KR20240098959A - Continuous Anaylyte Measurement Device - Google Patents

Abstract

The continuous analyte meter of the present invention includes a sheath member; an operation button member provided on an upper portion of the sheath member; a down unit provided inside the sheath member and lowered by the operation of the operation button member; a spring that lowers the down unit; an up unit that is unlocked by the down unit and rises; a clutch unit included in the down unit and lowering the needle assembly; may include.

Description

Continuous Anaylyte Measurement Device}

The present invention relates to a continuous analyte measuring device, and more specifically, to a device having a common spring inside a sheath member and a mechanism capable of safely and automatically inserting and removing a needle through an operation button member. will be.

Immediate detection of hypoglycemia is very important for diabetic patients, but blood glucose meters that measure blood sugar intermittently have limitations in accurately detecting this condition.

Recently, to overcome these limitations, a continuous glucose monitoring system (CGMS) is being developed that is inserted into the human body and measures blood sugar levels at intervals of several minutes.

This continuous blood sugar measuring device includes a sensor for sensing that is inserted into the body's skin to measure blood sugar, and a needle to guide the sensor when inserted. When the sensor is inserted into the body's skin, the needle is inserted into the body's skin and the sensor must be able to be inserted simultaneously, and once the sensor is inserted into the skin, the needle must be separated to the outside of the skin.

The structure for implementing this series of operations must be simple yet clearly implement the operations, and the user must be able to use it easily.

The present invention provides a mechanism that includes a common spring inside the sheath member and safely and automatically inserts and removes the needle through an operation button member.

The continuous analyte meter of the present invention includes a sheath member; an operation button member provided on an upper portion of the sheath member; a down unit provided inside the sheath member and lowered by the operation of the operation button member; a spring that lowers the down unit; an up unit that is unlocked by the down unit and rises; a clutch unit included in the down unit and lowering the needle assembly; may include.

When the up unit rises, the clutch unit simultaneously rises and the needle assembly can be raised.

The driving means of the present invention can provide driving force to raise or lower a needle or transmitter. The instrument member moves within the sheath member and can raise or lower the needle or transmitter. The driving means may be a single spring, a common spring. The common spring may be a compression spring in which both ends are compressed or restored.

In the present invention, when the operation button member provided on the upper part of the sheath member is rotated and pressed, the down unit provided inside the sheath member is switched from the locked state to the unlocked state and is lowered by the repulsion force of the common spring, thereby injecting needles and electricity into the user's skin. Chemical sensors can be inserted automatically. That is, the first automatic firing can be performed by rotating and pressing the operation button member.

In the first state in which the common spring is compressed in both the upward direction and the downward direction, the down unit is fixed in the first down position and the up unit is also fixed in the first up position with respect to the anchor unit fixed to the inside of the sheath member. It can be.

By pressing or moving the operation button member, the locking of the down unit with respect to the anchor unit may be released. The down unit may be lowered from the first down position to the second down position. In the second down position, the transmitter and needle are in a lowered position and the needle can be inserted into the skin and the transmitter attached to the skin.

In the first down position or the second down position, the upper end of the compressed common spring is supported in a stationary state by the up unit, and the lower end of the common spring can be lowered by pushing the down unit. The support point that supports the upper part of the up unit and the common spring in a stationary state may be an anchor unit.

Just before the down unit reaches the second down position or the second down position, the locking of the up unit relative to the anchor unit may be released. Unlocking of the up unit can be achieved by an elastic protrusion or an elastic recess on the down unit. The unlocked up unit can be raised from the first up position to the second up position. As the up unit rises toward the second up position, the needle is released from the skin and the needle can be raised to the top of the transmitter. The sensor housed inside the needle is mounted on the transmitter, the transmitter remains attached to the skin, the sensor remains inserted into the skin, and only the needle can be separated from the sensor or transmitter.

In the first up position or the second up position, the compressed lower end of the common spring is supported in a stationary state or just before stopping by the down unit, and the upper end of the common spring can be raised by pushing the up unit. The support point that supports the lower end of the down unit and the common spring in a stationary state may be an anchor unit.

As another example, just before the down unit reaches the second down position, the locking of the up unit relative to the anchor unit may be released. The lower end of the common spring may move the down unit to the second down position from a position immediately before reaching the second down position. At the same time, the upper end of the common spring can move the up unit from the first up position toward the second up position. Although it is only for a moment, there may be a moment when the down movement of the down unit and the up movement of the up unit are performed together by the common spring. This may be to eliminate time delays that may occur due to mechanical tolerances or assembly errors after the down unit reaches the second down position.

If the up unit does not rise immediately due to time delay or other reasons the moment the down unit reaches the second down position, the needle may move and cause pain to the skin. Therefore, it may not be desirable for the up unit to be unlocked at the moment the down unit is completely lowered to the second down position, and even if tolerances, etc. occur, the upward movement of the up unit must be done simultaneously with the completion of the down unit's descent or slightly later. The mechanism is designed so that it can be done beforehand.

Meanwhile, the means for resisting the restoring force of the compressed common spring may be an anchor unit. The down unit or up unit can be kept stationary by hanging the down unit or up unit on the anchor unit or sheath using a hook, etc.

First, if the hook lock of the down unit is released, the transmitter and needle begin to lower, and after insertion is completed, if the hook lock of the up unit is released, the up unit starts to rise and the needle can be raised.

A needle is coupled to the clutch unit, and the clutch unit can initially be lowered together with the down unit by engaging it with a hook, etc. The lower part of the common spring pushes the down unit, and the upper part of the common spring hangs on the up unit and is stopped. When the down unit is lowered, the clutch unit may be in a fastened state with respect to the down unit and in a free state with respect to the up unit.

After insertion is completed, the clutch unit and down unit are disengaged and the clutch unit can be connected to the up unit. When the up unit rises, the clutch unit can rise together with the needle. The upper part of the common spring pushes the up unit, and the lower part of the common spring hangs on the down unit and is stopped. When the up unit rises, the clutch unit may be in a fastened state with respect to the up unit and in a free state with respect to the down unit.

In the present invention, the common spring can be compressed or expanded in both directions, including the upper and lower ends. The common spring, which is compressed or restored in both directions, can have a larger stroke than Abbott's rising spring, which is inserted by hand and used only when rising. Even if the same coil wire diameter is wound, the stroke is larger, so it can exert a lot of movement displacement and a lot of restoring force. A groundbreaking inserter capable of automatic insertion and return can be provided. A larger stroke reduces the risk of the spring getting caught somewhere and malfunctioning.

On the other hand, compared to Dexcom's inserter that uses two insertion springs and two return springs, the number of springs is reduced from two to one, the mechanism structure for compressing or expanding the spring is reduced by half, and the spring is installed in multiple numbers in the radial direction of the inserter. The complexity of assembly and the possibility of malfunction due to placement can be reduced by half.

Meanwhile, the common spring may be provided outside the down unit and the up unit. Compared to the case where a common spring is provided inside these springs, the overall diameter of the spring can be increased even if the spring has the same wire diameter, so there is an advantage of increasing the elastic force, and the case of malfunction due to being caught somewhere can be eliminated.

Assuming that the common spring is stored inside the down unit and the up unit, the length of the common spring that expands in both directions may be too long compared to the diameter, so the common spring may buckle (toggle) in the storage space. In addition, since the common spring must be stored inside the unit located more internally among the down unit and the up unit, assembly may be very complicated and the diameter of the spring may be small.

Despite these theoretical advantages, it is very difficult to actually mechanically implement the common spring, and the clutch unit of the present invention is the most difficult to create. The clutch structure of the present invention, which couples only to the down unit at a specific position and then only to the up unit at another specific position by simply mechanical hook coupling, is not seen anywhere in the prior art.

Meanwhile, the present invention also has novelty in the hook structure for releasing the lock. The hook can bite into at least one of the down unit, up unit, clutch unit, and anchor unit to keep their movement in a stationary state. The protrusion of the hook and the groove engaging therewith may be disposed on one of the down unit, up unit, clutch unit, and anchor unit, respectively.

The down unit, up unit, and clutch unit can be raised or lowered in the height direction of the sheath with respect to the anchor unit. When the protrusion of the hook protruding on one side along the width direction of the sheath is engaged with any one of the down unit, up unit, and clutch unit, the opposite side of the protrusion of the hook along the width direction of the sheath is engaged with the down unit, up unit, and clutch unit. It may be in contact with a block wall formed in one of the units and anchor units. The block wall prevents the hook from moving, so the hook's engagement state can be maintained firmly. In other words, the protrusion of the hook provides a direct cause of jamming, and the opposite side of the protrusion of the hook is blocked by the block wall, which can serve as a double locking function to block release of the jam once again.

After the needle and electrochemical sensor are inserted into the skin, the locking state of the up unit can be released from the anchor unit fixed to the inside of the sheath member by the lowered down unit. At this time, the up unit together with the anchor unit provided in the center of the down unit can rise upward from the anchor unit due to the repulsive force of the common spring.

As the clutch unit rises due to the upward motion of the up unit, the needle assembly coupled with the clutch unit rises simultaneously with the up unit, so that the electrochemical sensor is inserted into the skin, and only the needle assembly comes out and moves away from the transmitter. can be moved to

Therefore, the present invention can automatically perform the insertion of the needle and the electrochemical sensor and the separation of the needle with one common spring, and after the needle assembly is separated, when the sheath member is separated from the skin, the transmitter remains attached to the skin. can be maintained.

In addition, in the present invention, the operation button member provided on the upper part of the sheath member is not pressed even if pressed before use, so the phenomenon of the needle assembly lowering due to malfunction does not occur, and it must be rotated in one direction and pressed manually to move the down unit to the lower part. It is fired automatically and the needle and electrochemical sensor of the needle assembly are inserted into the skin, making it safe to use.

The present invention uses an anchor unit provided inside the sheath member as a fixing means when implementing the primary operation of inserting the needle and the electrochemical sensor into the skin by a common spring and the secondary operation of separating the needle, and the up unit and down unit You can perform independent movements in the opposite direction without shaking. The means for connecting the needle assembly to the up unit to raise it or connecting the needle assembly to the down unit to lower it may be a clutch unit.

The clutch unit remains coupled to the needle assembly and may be connected to the up unit when ascending and to the down unit when descending. The advantage of the clutch unit's connection switching operation is that it does not use an electric switch or motor, but rather uses elastic coupling of the protruding and concave parts.

Conventionally, Abbott of the United States had a structure in which the needle was inserted by manually lowering the sheath, and the needle was raised by the lifting force of the return common spring. In this case, complex cam and slide cam shapes must be created inside the sheath to obtain the force and timing required for needle insertion when pressed by hand, so maintaining mold precision when manufactured with a plastic mold is a problem that determines the defect in cam operation timing. There was.

Also, when inserting a needle by hand, there was a problem that the patient had no choice but to feel fear because he was inserting the needle himself. If you lose your grip out of fear, the needle may not be inserted properly. It may not be advisable to have a diabetic patient use the device while feeling fear every time.

Meanwhile, Dexcom of the United States and iSense of Korea have conventionally adopted inserters that use a first common spring when the needle is lowered and a second common spring when the needle is raised. In this case, automatic insertion and automatic return are advantages, but there is a problem that many internal structures are required to operate the two common springs, and assembly of the inserter is difficult.

There is a question as to whether using two common springs for automatic insertion and automatic return is the optimal design from an engineering perspective. While the goal of the invention is to obtain the same function while minimizing the number of members as much as possible, the present invention has made a groundbreaking change in idea by performing all these operations using one common spring.

Figure 1 is a perspective view of a continuous analyte measuring device according to an embodiment of the present invention.
Figure 2 is a plan perspective view of the sheath member of the present invention.
Figure 3 is a bottom perspective view of an outer operation button member of a continuous analyte measuring device according to an embodiment of the present invention.
Figure 4 is a plan view of the inner operation button member of the continuous analyte measuring device according to an embodiment of the present invention.
Figure 5 is a bottom perspective view of the inner operation button member of the present invention.
Figure 6 is a perspective view of an assembly provided inside the sheath member of the present invention.
Figure 7 is a plan perspective view of the down unit of the present invention.
Figure 8 is a perspective view of the up unit moving inside the sheath member of the invention.
Figure 9 is a perspective view of an anchor unit fixed to the inside of the sheath member of the present invention.
Figure 10 is a combined cross-sectional view of a continuous analyte measuring device according to an embodiment of the present invention.
FIG. 11 is a color-coded view of the cross-sectional view of FIG. 10.
FIG. 12 is a cross-sectional view with the sealing member in FIG. 10 removed.
FIG. 13 is a color-coded view of the cross-sectional view of FIG. 12.
FIG. 14 is a cross-sectional view of the outer operation button member in FIG. 12 in a state in which the outer operation button member is rotated and pressed.
FIG. 15 is a color-coded view of the cross-sectional view of FIG. 14.
FIG. 16 is a cross-sectional view of the assembly in FIG. 14 in which the locking state is released, the assembly is lowered, and the needle is inserted into the skin.
FIG. 17 is a color-coded view of the cross-sectional view of FIG. 16.
FIG. 18 is a cross-sectional view of the anchor unit in FIG. 16 in a state in which the anchor unit is unlocked from the up unit and the up unit, transmitter housing, and needle assembly are raised by a common spring.
Figure 19 is a color-coded cross-sectional view of Figure 18.

Hereinafter, the case where the electrochemical sensor 400 of the present invention is used in a continuous glucose monitoring system (CGMS) that measures interstitial fluid or blood glucose concentration will be described as an example. However, the continuous blood glucose meter of the present invention is not limited to measuring glucose concentration in the body and can be expanded to a continuous analyte meter that measures other biomarkers.

Referring to Figure 1, the continuous analyte measuring device 1 according to an embodiment of the present invention includes a sheath member 100, an operation button member 200 provided on the upper part of the sheath member 100, and a sheath member 100. ) may include a sealing member 300 that is detachably provided at the lower portion.

The sheath member 100 may be formed in a cylindrical shape with a predetermined storage space.

The sheath member 100 may include a body portion 110 that forms an exterior, and a fixing plate 120 formed on an upper portion of the body portion 110.

The fixing plate 120 may be formed at a position recessed from the top of the body 110 to the bottom. Accordingly, the fixing plate 120 may be arranged with a height difference from the top of the body portion 110.

An operation button member 200 may be provided in the space formed by this height difference.

The fixing plate 120 may include a first through hole 121 formed in the center and a plurality of second through holes 122 formed at intervals along the circumferential direction around the first through hole 121. .

Insertion grooves 121a may be formed in the first through hole 121 at intervals along the circumferential direction.

Additionally, a support hole 123 into which the locking member 540 of the up unit 500 is inserted and supported may be formed between the second through holes 122.

Additionally, a plurality of third through holes 124 may be formed in the fixing plate 120 radially outside the second through holes 122 at intervals along the circumferential direction.

Additionally, a plurality of locking protrusions 125 may be formed on the bottom of the fixing plate 120 at intervals along the circumferential direction. The locking protrusion 125 can lock the assembly, which will be described later, and the locking state is released by the operation of the operation button member 200, and the down unit 400 and the clutch unit 800 are connected by the repulsive force of the common spring 560. It can be lowered inside the sheath member 100.

Additionally, a hook member 126 may protrude from the bottom of the fixing plate 120. The hook member 126 can be locked after the up unit 500 is raised to prevent the up unit 500 from shaking within the sheath member 100.

Here, the assembly may include a down unit 400, an up unit 500, a common spring 560, and a clutch unit 800.

The operation button member 200 may include two separately provided members. One member may be an outer operation button member 210 disposed on the outside, and the remaining member may be an inner operation button member 220 provided below the outer operation button member 210.

A handle 211 may be formed on the outer surface of the outer operation button member 210 to easily rotate the outer operation button 210. At this time, the periphery of the handle 211 may be formed in the form of a recessed groove to facilitate the user's grip and rotation.

Additionally, the bottom of the outer operation button member 210 may include a hook protrusion 212 formed at an inner position close to the center and a guide protrusion 213 formed radially outward from the hook protrusion 212. The hook protrusion 212 and the guide protrusion 213 may be formed to protrude in plural numbers at intervals along the circumferential direction.

Additionally, the inner operation button member 220 may have a plurality of guide grooves 221 formed at intervals along the circumferential direction, and a through hole 222 may be formed in the center.

A plurality of locking grooves 221a may be formed in the guide groove 221 at intervals such that the locking protrusion 213a of the guide protrusion 213 is inserted.

In addition, referring to FIG. 4, a plurality of through holes 223 are formed at intervals radially outward from the through hole 222, and a plurality of openings 224 are formed at intervals radially outward from the through hole 223. ) can be formed.

As shown in FIG. 5, the passing hole 223 may be a hole through which the hook protrusion 225 is bent, and the opening 224 allows the guide protrusion 213 of the outer operation button member 210 to rotate. When this occurs, elastic deformation may occur to facilitate rotational movement of the guide protrusion 213.

The locking protrusion 213a formed on the guide protrusion 213 of the outer operation button member 210 is one of the plurality of locking grooves 221a formed on the guide groove 221 of the inner operation button member 220. ) can be moved to the next position of the locking groove (221a) and caught.

Therefore, when the outer operation button member 210 rotates, it is locked in the locking groove 221a at the first position, and then rotates and moves to the locking groove 221a at the second position and is locked, so the rotating action is performed at the first position. The second position can be reliably achieved.

In addition, a hook protrusion 225 may be formed on the bottom of the inner operation button member 220 at a position close to the through hole 222, and an unlocking protrusion 226 may be formed radially outward from the hook protrusion 225. there is.

The hook protrusion 225 and the unlocking protrusion 224 may be formed to protrude in plurality at intervals along the circumferential direction.

The hook protrusion 225 may be inserted into the insertion groove 121a formed around the first through hole 121 formed in the fixing plate 120 of the sheath member 110.

The unlocking protrusion 226 may become narrower from the bottom to the end of the inner operation button member 220 and may be formed into a sharp wedge shape.

The unlocking protrusion 226 may be inserted through the second through hole 122 formed in the fixing plate 120 of the sheath member 100.

The sealing member 300 may be detachably screwed to the lower end of the sheath member 100, and a support member 310 may be formed therein to surround and support a needle, which will be described later.

Additionally, a down unit 400 holding the transmitter may be provided inside the sheath member 100.

The down unit 400 may be equipped with a transmitter and a needle assembly.

The down unit 400 includes a base member 410, and a through hole 411 through which the needle assembly penetrates is formed at the center of the base member 410, and a through hole 411 is formed around the through hole 411 along the circumferential direction. A plurality of hook members 420 may protrude at intervals. Additionally, a guide wall 430 may be formed around the hook member 420, and a plurality of locking members 440 may be formed on the guide wall 430 at intervals. The locking member 440 may protrude to a predetermined height, and a locking hole 441 having a long hole structure may be formed along the height direction.

The hook member 420 may be provided with a predetermined elastic force. Additionally, a guide member 450 may protrude from the radial outer side of the locking member 440.

The guide member 450 may be formed in plural numbers at intervals along the circumferential direction and may be provided at a position facing the locking member 440.

Additionally, an up unit 500 that is raised and lowered within the sheath member 100 may be provided inside the sheath member 100. The up unit 500 includes a curved side wall 510 and an upper surface 520 formed on the upper part of the side wall 510, and a guide tube 530 may protrude from the center of the upper surface 520. , a plurality of insertion holes 521 may be formed around the guide tube 530 at intervals along the circumferential direction.

The insertion hole 521 may include a first insertion hole 521a and a second insertion hole 521b. The first insertion hole 521a may be formed to be longer in the circumferential direction than the second insertion hole 521b.

The locking member 440 of the down unit 400 can be inserted into the first insertion hole 521a, and the up unit 500 can be inserted into the second insertion hole 521b to be raised and then attached to the fixing plate of the sheath member 100. (120) A locking protrusion 125 protruding from the bottom may be inserted.

A plurality of concave portions 511 may be formed on the side wall 510 at intervals along the circumferential direction. The guide member 450 of the down unit 400 may face the concave portion 511, and when the up unit 500 rises, the concave portion 511 rises while maintaining the state facing the guide member 450. Therefore, the upward motion can be performed more stably without shaking.

In addition, on the side wall 510, inclined surfaces 512 may be formed at intervals along the circumferential direction to protrude inward, and on the outer peripheral surface of the side wall 510, a guide groove ( 513) can be formed in plural form at intervals.

A through hole 531 may be formed in the guide tube 530, and locking grooves 532 may be formed at a predetermined depth on both sides of the through hole 531.

A locking member 540 may protrude between the plurality of insertion holes 521. A locking hole 541 is formed in the locking member 540, so that after the up unit 500 is raised, it is caught by the hook member 126 formed on the bottom of the fixing plate 120 of the sheath member 100 and is locked without shaking. can be maintained.

A support pipe 550 may be formed inside the up unit 500, and a common spring 560 may be provided on the outer peripheral surface of the support pipe 550.

Additionally, a clutch unit 800 may be provided inside the support pipe 550, which is coupled to the needle assembly 700 and is provided to penetrate the guide pipe 530 of the up unit 500. At this time, the hook member 420 of the down unit 400 facing the inside of the support pipe 550 may be pressed in the center direction, and when the up unit 500 rises, the support pipe 550 is pressed against the hook member. Since it deviates from (420), the pressurized state can be released.

A transmitter 460 may be provided at the lower part of the base member 410 of the down unit 400. Inside the transmitter 460, an electrochemical sensor 461 that penetrates the user's skin, a communication unit, a battery, etc. may be provided.

The transmitter 460 can control the signal measured by the electrochemical sensor 461 and transmit continuously measured blood sugar levels to an external terminal, including a mobile phone.

The external terminal is provided separately from the transmitter 460 attached to the skin, and can continuously receive measurement data of the electrochemical sensor 461 wirelessly from the transmitter 460. The user can continuously monitor and diagnose measurement data from the electrochemical sensor 461 for biomarkers including glucose, lactate, etc.

The transmitter 460 may include a first housing and a second housing corresponding to a lower lid and an upper lid, and an internal space may be provided between the first housing and the second housing. A main board may be seated in the internal space of the transmitter 460.

The main board includes a power supply such as a battery required to measure the glucose concentration in the distal part corresponding to the end of the electrochemical sensor, a control unit including an electric circuit, and a control unit that controls the data measured by the electrochemical sensor 461 and wirelessly transmits it to the outside. At least one of a wireless communication unit for transmission and an operational amplifier may be installed.

The power supply may supply a bias voltage that can cause an electrochemical reaction of the working electrode.

The analyte signal measured distal to the electrochemical sensor may be amplified by an operational amplifier.

Additionally, the needle assembly 700 may be coupled to penetrate the transmitter 460. The needle assembly 700 may include a needle 710 that guides the sensor 461 to be inserted into the skin, and a needle holder 720 coupled to the upper part of the needle 710.

The clutch unit 800 includes a support pipe 810 that protrudes through the guide pipe 530 of the up unit 500, a locking pipe 820 formed in the lower part of the support pipe 810, and a locking pipe 820. It may include a clamping member 830 provided inside and clamping the needle holder 720.

A locking protrusion 811 may be formed at the end of the support pipe 810 to be caught in the locking groove 532 of the up unit 500 when the clutch unit 800 is lowered.

An inclined surface 821 of the down unit 400 may be formed on the upper side of the catching pipe 820.

The clamping member 830 may have elasticity so that the upper end of the needle holder 720 is inserted and pressed.

The locking pipe 820 can be maintained in the hooked state by the hook member 420 of the down unit 400, and can be released by overcoming the catching force of the hook member 420 by the repulsive force of the common spring 560. .

Additionally, an anchor unit 600 may be provided to be fixed inside the sheath member 100.

The anchor unit 600 may include a support plate 610, an insertion hole 611 formed in the support plate 610, and a pressing member 620 formed along the circumferential direction around the edge of the insertion hole 611. . The support plate 610 may be formed in a circular shape, for example.

The support plate 610 may be inserted between the down unit 400 and the up unit 500.

A plurality of pressing members 620 may be provided at intervals along the circumferential direction of the insertion hole 611, and a first locking protrusion 621 may be formed on each inner surface to protrude inward in the radial direction.

Additionally, each of the plurality of pressing members 620 may be formed with a pressing surface 622, and a second locking protrusion 623 may be formed to protrude outside the pressing surface 622.

Additionally, a plurality of support protrusions 630 may protrude from the bottom of the support plate 610.

In addition, the guide member 450 of the down unit 400 is inserted into the support plate 610, and a plurality of coupling holes 612 are formed at intervals along the circumferential direction to guide the down unit 400 when moving. It can be, and a coupling groove 613 for coupling to the inner surface of the body portion 110 of the sheath member 100 may be formed on the radial outer side of the coupling hole 612. Accordingly, the anchor unit 600 can remain fixed inside the sheath member 100.

In Figure 10, the technical key points of the present invention are indicated by dotted circles. That is, the unlocking operation by the operation button member 200, the release operation of the down unit by lowering the inner operation button member 220, the locking of the up unit 500 and the anchor unit 600, and the down unit 400. It may be a release state due to a lowering operation, a locking state between the clutch unit 800 and the hook member 420 of the down unit 400, and a release operation position.

[First operation mode due to absence of operation button] (unlocking operation)

10 to 19, the continuous analyte measuring device 1 according to the present invention is sealed by the sealing member 300, and the transmitter is used while the user inserts an electrochemical sensor into the skin to check blood sugar level. (460) can be worn.

At this time, when the sealing member 300 is separated from the lower end of the sheath member 100, the needle 710 of the needle assembly 700 can be changed from a sealed state to an open state.

The needle 710 may be previously inserted into the sheath member 100 and may not protrude outside the body portion 110 of the sheath member 100.

In this state, the operation button member 200 can be manipulated to lower the needle assembly 700 to insert the needle 710 and the electrochemical sensor 461 into the user's skin.

The operation button member 200 is composed of an outer operation button member 210 provided on the top of the sheath member 100 and an inner operation button member 220 therein. In the initial state, the outer operation button member 210 Even if you press , it may not be pressed.

When the outer operation button member 210 is pressed, the inner operation button member 220 disposed below must be lowered, but the guide protrusion 213 protruding from the bottom of the outer operation button member 210 is not connected to the inner operation button member 210. Since one side of the guide groove 221 of 220 is penetrated and faces the fixing plate 120 of the sheath member 100, the outer operation button member 210 may not be able to descend. Accordingly, the inner operation button member 220 provided below the outer operation button member 210 can maintain its arranged state without any influence.

At this time, when the handle 211 of the outer operation button member 210 is held and rotated in one direction, the guide protrusion 213 formed on the bottom of the outer operation button member 210 is the guide groove of the inner operation button member 220 ( 221) can be rotated at a predetermined angle (for example, 30 degrees), and the hook protrusion 212 can also be rotated along the inner surface of the through hole 222 of the inner operation button member 220.

Then, the guide protrusion 213 of the outer operation button member 210 rotates and meets the third through hole 124 formed on the outermost side of the fixing plate 120, and at this moment, the outer operation button member 210 When pressed, the guide protrusion 213 may descend while being inserted into the interior of the sheath member 100 through the third through hole 124.

Accordingly, as the outer operation button member 210 descends, the inner operation button member 220 disposed below it may also be pressed and descend at the same time.

A plurality of unlocking protrusions 226 protrude at intervals from the outermost portion of the bottom of the inner operation button member 220, and as the inner operation button member 220 descends, the unlocking protrusions 226 are sheath members ( The locking protrusion 125 formed on the bottom of the fixing plate 120 of the down unit 400 and the upper end of the locking hole 441 of the locking member 440 of the down unit 400 can be released.

In other words, the locking protrusion 124 is caught on the upper end of the locking hole 441 of the locking member 440, and the unlocking protrusion 226 penetrates between the locking protrusions 125 and locks the locking protrusion 125 into the locking member 440. It can be spread in a direction away from. Accordingly, the locking protrusion 125 may be separated from the engaging hole 441 of the engaging member 440 and the locked state may be released.

Since the unlocking protrusion 226 has a wedge shape whose width becomes narrower toward the lower end, when the inner button member 220 descends, the unlocking protrusion 226 descends and the locking protrusion 125 and the locking member 440 ) The locking state can be released by pushing the locking protrusion 125 outward in the radial direction while entering the space.

The operation to release this locking state can be referred to as a primary unlocking operation, and through the primary unlocking operation, the needle and electrochemical sensor can be inserted into the user's skin.

[Second operation mode for inserting the needle and electrochemical sensor by releasing the first lock] (lowering operation)

By manipulating the operation button member 200, the assembly enters a primary unlocked state inside the sheath member 100 and can descend.

When the primary locking state is released, the assembly may descend inside the sheath member 100 and reach the lower end of the sheath member 100 due to the repulsive force of the common spring 560 connected to the down unit 400.

The common spring 560 is compressed and provided between the down unit 400 and the up unit 500, and when the primary lock is released, the down unit ( 400) can act as a force to move downward.

Since the common spring 560 is provided in a compressed state, it can act as a force pushing the down unit 400 in the downward direction due to the repulsion force, and can simultaneously act as a force pushing the up unit 500 in the upward direction. .

At this time, the down unit 400 may be unable to descend because the locking hole 441 of the locking member 440 is caught by the locking protrusion 125 formed on the bottom of the fixing plate 120 of the sheath member 100.

Even if a force to raise the up unit 500 is applied, the second locking protrusion 623 formed on the anchor unit 600 in a fixed state is attached to the inclined surface 512 protruding inside the side wall 510 of the up unit 500. Because it is in a locked state, it cannot be raised and remains fixed.

Moreover, since the guide wall 430 of the down unit 400 is inserted inside the second locking protrusion 623 of the anchor unit 600 and is pressed radially outward, the second locking protrusion 623 can be pushed and maintained in close contact with the inclined surface 512 of the up unit 500.

The second locking protrusion 623 of the anchor unit 600 protrudes outside the pressing surface 622 of the pressing member 620, and the pressing surface 622 is formed as a free end from the pressing member 620 and is elastic. It can be moved in the radial direction.

Therefore, when the guide wall 430 of the down unit 4000 is inserted into the insertion hole 611 of the pressing member 620, the pressing surface 622 of the free end can be pushed outward in the radial direction, and thus the down unit (Without the guide wall 430 of 4000, the pressing surface 622 can be returned to its original position.

In this way, when the primary locking state is released for the down unit 400 and the up unit 500 in a fixed state, the down unit 400 is lowered by the repulsive force of the common spring 560, and the down unit 400 ), the clutch unit 800 clamped in the center of the down unit 400 may also descend at the same time.

The locking protrusion 811 formed on the upper end of the support pipe 810 formed on the descending clutch unit 800 contacts the locking groove 532 of the guide pipe 530 formed in the center of the up unit 500, thereby causing locking. The lowering operation of the ground down unit 400 may be stopped. The clutch unit 800 is in contact with the up unit 500 to raise the up unit 500.

However, it is not limited to this, and the connection between the clutch unit 800 and the up unit 500 can function as a stopper to stop the downward movement of the down unit 400, and the down unit 400 and the clutch unit 800 It can provide the force to disconnect.

In other words, when the down unit 400 is lowered by the repulsion force of the common spring 560 in the initially assembled state (raised state), the clutch unit 800 is also lowered at the same time, but during the lowering time of the down unit 400 The up unit 500 maintains a fixed state.

Since the up unit 500 is supported by the anchor unit 600, it cannot rise due to the repulsive force of the common spring 560 and can remain fixed. Accordingly, only the down unit 400 and the clutch unit 800 descend due to the repulsive force of the common spring 560, and the up unit 600 may remain fixed without falling.

When the down unit 400 and the clutch unit 800 are lowered and stopped, the transmitter 460 provided at the lower part of the down unit 400 faces the user's skin (S), and accordingly the needle assembly ( The needle 710 of 700 can guide the electrochemical sensor 461 and insert it into the skin (S).

The stopper function that limits the lowering position of the down unit 400 will be described. When the down unit 400 is lowered and stopped, the locking member 440 of the down unit 400 is lowered and the first locking protrusion 621 protrudes from the inner surface of the pressing member 620 of the anchor unit 600. ) and the top of the locking hole 441 may become caught and stop.

When the down unit 400 is lowered and stopped, the guide wall 430 may be released from the state facing the pressing surface 622 of the anchor unit 600. Accordingly, the pressing surface 622 can be returned to its original position because no outward pushing force is applied.

Referring to Figure 18 or Figure 19, the down unit 400 facing the user's skin may be facing the skin in a state that protrudes slightly more than the lower end of the body portion 110 of the sheath member 100.

[Third operation mode to remove inserted needle]

With the needle 710 and the electrochemical sensor 461 inserted into the skin, a separation operation may be performed to separate only the needle 710 from the inside to the outside of the skin.

After the needle 710 is inserted into the skin by lowering the down unit 400, when the needle 710 is separated from the skin leaving only the electrochemical sensor 461, the down unit 400 is inserted into the sheath member 100. ) The separation operation of the needle 710 may be performed at a time when it is completely lowered inside the needle and is not facing the skin.

In other words, the moment the second locking protrusion 623 of the anchor unit 600 is released from being caught on the inclined surface 512 of the up unit 500 by lowering the guide wall 430 of the down unit 400, A separation operation of the needle 710 may be performed.

The moment the second locking protrusion 623 of the anchor unit 600 is released from being caught on the inclined surface 512 of the up unit 500 by lowering the guide wall 430 of the down unit 400, the needle ( 710) may be inserted into the skin together with the electrochemical sensor 461, and the down unit 400 may be in a state just before it is completely lowered.

Since the separation of the needle 710 begins, the user can minimize the time the needle 710 is inserted, thereby minimizing pain caused by inserting the needle 710.

Referring to FIG. 16, as the first gap between the lower end of the body portion 110 of the sheath member 100 and the lower end of the down unit 400 is indicated by an arrow, when the down unit 400 is lowered, the arrow When the first interval is reached, the first locking protrusion 621 and the locking member 440 may be arranged at a second interval as indicated by an arrow, and in this state, they are inserted into the skin. The needle 710 may be at a point where it rises upward.

Accordingly, when the down unit 400 completes the lowering operation by the first interval, the needle 710 may already begin to separate from the skin.

Since the common spring 560 continues to exert a repulsive force, the down unit 400 can no longer be lowered. Therefore, in the down unit 400, in a lowered and stopped state, the clutch unit 800 ) and can act as a force to raise the up unit 500.

That is, while the down unit 400 is stopped, the up unit 500 is forced to move upward due to the repulsive force of the common spring 560, and then the inclined surface 512 of the up unit 500 Since the second locking protrusion 623 of the anchor unit 600, which was maintained in the locked state while facing the It can rise by releasing it.

When the up unit 500 rises, the catching protrusion 811 formed on the upper end of the support tube 810 of the clutch unit 800, which is inserted through the through hole 531 of the guide tube 530, is connected to the guide tube ( Since it is locked in the locking groove 532 of 530, when the up unit 500 moves from the lower part to the upper part, the clutch unit 800 can also be moved to the upper part in a locked state.

When the clutch unit 800 rises upward by the up unit 500, the engaging pipe 820 of the clutch unit 800 remains locked by the hook member 420 of the down unit 400. However, the clutch unit 800 can rise above this jammed state. That is, the clutch unit 800 can rise by spreading the elastic hook member 420 outward in the radial direction, and at this time, the clamping member 830 formed inside the engaging pipe 820 of the clutch unit 800 is attached to the clamping member 830. The needle holder 720 clamped by can rise simultaneously.

As the needle holder 720 rises, the needle 710 coupled to the needle holder 720 also rises simultaneously, and may be separated from the skin to the outside and further separated from the transmitter 400.

When the up unit 500 rises, the upper end of the guide tube 530 comes into contact with the bottom of the fixing plate 120 of the sheath member 100, and the upward movement may be stopped.

Meanwhile, in the lowered state of the operation button member 200, the unlocking protrusion 226 of the inner operation button member 220 is pushed upward by the return force of the unlocking protrusion 125, which rises back to its original position. It can be.

When the needle 710 is separated from the skin and then the sheath member 100 is separated from the skin, the transmitter 400 is attached to the skin, and the separated sheath member 100 has an assembly installed therein. It can be disposed of.

1... Continuous analyte meter
100... sheath member 110... body part
120... fixing plate 121... first through hole
121a... Insertion groove 122... Second through hole
123... support hole 124... third through hole
125… Locking protrusion 126... Hook member
200...absence of operation button 210...absence of outer operation button
211... handle 212... hook projection
213... guide projection 213a... catching projection
220... Absence of inner operation button 221... Guide home 2
221a...Hanging groove
222... through hole 223... first insertion hole
224… 2nd insertion hole
225... Hook projection 226... Locking release projection
300... sealing member 310... supporting member
400... down unit 410... base member
411... through hole
420... Hook member 430... Guide wall
440... Locking member 441... Locking hole
450... Guide member 460... Transmitter
461... Electrochemical sensors
500... up unit 510... side wall
511... recess 512... incline
513... Guide home
520... Upper surface ` 521... Insertion hole
521a... first insertion hole 521b... second insertion hole
530... guide tube 531... through hole
532... Locking groove 540... Locking member
541...Hanging ball
550...support pipe 560...common spring
600...anchor unit 610...support plate
611... insertion hole 612... joining hole
613...coupling groove 620...pressure member
621...First locking protrusion 622...Pressure surface
623...Second locking protrusion 630...Supporting protrusion
700... needle assembly 710... needle
720... Needle holder
800... anchor unit 810... support pipe
811...Hanging protrusion 820...Hanging pipe
821...slope 830...clamping member

Claims (6)

Absent sheath;
an operation button member provided on an upper portion of the sheath member;
a down unit provided inside the sheath member and lowered by the operation of the operation button member;
a spring that lowers the down unit;
an up unit that is unlocked by the down unit and rises;
a clutch unit included in the down unit and lowering the needle assembly; Including,
A continuous analyte measuring device in which when the up unit rises, the clutch unit simultaneously rises and the needle assembly rises.
According to claim 1,
The operation button member,
Absence of outer operation button placed on the outside,
It includes an inner operation button member provided below the outer operation button member,
A continuous analyte measuring device in which the inner operation button member descends by rotating and pressing the outer operation button member to release the locking state of the down unit.
According to clause 2,
The sheath member includes a body portion,
A fixing plate is formed on the upper part of the body part,
A plurality of third through holes are formed in the fixing plate at intervals along the circumferential direction,
A hook protrusion formed on the bottom of the outer operation button member at an inner position close to the center,
It includes a guide protrusion formed radially outward from the hook protrusion,
The inner operation button member has a plurality of guide grooves formed at intervals along the circumferential direction,
The guide protrusion passes through the guide groove and is supported on the fixing plate,
As the outer operation button member rotates, the guide protrusion moves along the guide groove and is inserted into the third through hole to press the inner operation button member.
According to clause 3,
A continuous analyte measuring device in which a plurality of locking grooves are formed in the guide groove at intervals such that the locking protrusion of the guide protrusion is inserted.
According to clause 2,
A plurality of hook protrusions are formed on the bottom of the inner operation button member,
A continuous analyte measuring device in which an unlocking protrusion is formed radially outward from the hook protrusion.
According to clause 5,
The unlocking protrusion becomes narrower as it goes from the bottom of the inner operation button member to the end, forming a sharp wedge shape,
The unlocking protrusion is inserted through a second through hole formed in the fixing plate formed on the upper part of the sheath member,
A locking member for locking the down unit is formed on the bottom of the fixing plate of the sheath member,
When the inner operation button member is lowered, the unlocking protrusion pushes the locking member radially outward to release the locking state with the down unit.