CN210009033U - Split type developments blood glucose monitor structure and developments blood glucose monitor - Google Patents

Abstract

Compared with the prior art, the split type dynamic blood sugar monitor structure disclosed by the application comprises: a signal transmitter; an implant tool body for implanting the sensor in human skin; wherein the signal transmitter includes: a blood glucose data transmission part connected with the sensor; a blood sugar data transmitting part for transmitting the blood sugar data to the terminal; the blood sugar data transmission part is detachably connected with the blood sugar data transmitting part; the blood sugar data transmitting part is detachably connected with the implantation tool main body. The application provides a split type developments blood glucose monitor structure compares in prior art, and it can avoid the damage that the inside electronic components caused at the in-process of disinfection processing of developments blood glucose monitor, improves the durability of developments blood glucose monitor. The application also relates to a dynamic blood glucose monitor, which has the beneficial effects.

Description

Split type developments blood glucose monitor structure and developments blood glucose monitor

Technical Field

The application relates to the technical field of medical instruments, more specifically says, especially relates to a split type developments blood glucose monitor structure, and this application still relates to a developments blood glucose monitor.

Background

With the improvement of living standard of people, people pay more attention to the health condition, and pay attention to health preservation and detection of various parameters of the body. For example, it is necessary to periodically measure the glycemic index and to pay attention to the amount of sugar in blood. We generally focus on the physical condition from the side by regular glycemic index monitoring, monitoring the physical health index, etc.

At present, current blood sugar test mode mainly has two kinds, one kind is for pricking finger collection fingertip blood, uses the blood sugar examination strip and the blood glucose meter cooperation of test usefulness, can gather discrete blood sugar value, and another kind is dynamic blood sugar monitoring system CGM, through implanting blood glucose sensor in the skin, enzyme on the sensor and subcutaneous tissue liquid reaction detection blood sugar value to cooperate the transmitter with blood sugar value transmission to the terminal, can gather continuous blood sugar value. Blood glucose monitor is as a medical instrument device, and disinfection is its essential link in production, use, and in prior art, the signal transmitter part among the blood glucose monitor is disinfected, causes the damage of inside electronic components easily, influences dynamic blood glucose monitor's normal use.

Therefore, how to provide a split type dynamic blood glucose monitor structure, which can avoid the damage of the dynamic blood glucose monitor to the internal electronic components in the process of disinfection treatment, and improve the durability of the dynamic blood glucose monitor has become a technical problem to be solved urgently by those skilled in the art.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the application provides a split type developments blood sugar monitor structure, and it can avoid the damage that developments blood sugar monitor caused inside electronic components at the in-process of disinfection, improves the durability of developments blood sugar monitor. The application also relates to a dynamic blood glucose monitor, which has the beneficial effects.

The technical scheme provided by the application is as follows:

the application provides a split type developments blood glucose monitor structure includes: a signal transmitter; an implant tool body for implanting the sensor in human skin; wherein, signal transmitter includes: a blood glucose data transmission part connected with the sensor; a blood sugar data transmitting part for transmitting the blood sugar data to the terminal; the blood sugar data transmission part is detachably connected with the blood sugar data transmitting part; the blood sugar data transmitting part is detachably connected with the implantation tool main body.

Further, in a preferred mode of the present invention, the signal transmitter further includes: an emitter housing; the blood sugar data transmitting part is arranged on the inner side of the transmitter shell; the blood sugar data transmission part is arranged outside the emitter shell; the blood sugar data transmission part is detachably connected with the emitter shell.

Further, in a preferred mode of the present invention, the transmitter housing includes: a lower cover of the emitter; the emitter upper cover is arranged on the emitter lower cover; the installation base is arranged on the lower cover of the emitter and used for installing the blood sugar data emitting part; the first waterproof glue is arranged at the joint of the upper cover and the lower cover of the emitter.

Further, in an preferred embodiment of the present invention, the blood sugar data transmission unit is disposed outside the transmitter housing and specifically includes: the emitter upper cover is provided with a concave part, and the concave part is used for placing the blood sugar data transmission part.

Further, in a preferred embodiment of the present invention, the blood glucose data transmission unit includes: the conductive electrode is communicated with the flexible circuit board and used for controlling the opening or closing of the blood glucose data transmitting part; the silica gel protective cover is arranged at the opening of the depressed part and is detachably connected with the upper cover of the emitter; the sensor needle is used for penetrating through the needle hole to deeply detect the blood sugar under the skin, and is connected with the conductive electrode; and the second waterproof glue is filled in the concave part.

Further, in a preferred embodiment of the present invention, the blood glucose data transmitting unit includes: a printed circuit board disposed on the mounting base; the button battery is arranged on the mounting base and used for supplying power to the printed circuit board; and the flexible circuit board is arranged on the mounting base and is used for being connected with the blood glucose data transmission part.

Further, in a preferred mode of the present invention, a first waterproof adhesive is filled between the flexible circuit board and the upper and lower transmitter covers; the second waterproof glue is specifically waterproof silica gel.

Further, in an preferred mode of the present invention, the split type dynamic blood glucose monitor structure further comprises: sterilizing the storage box; the disinfection storage box is provided with a transmitter storage part for placing a signal transmitter; the disinfection storage box is provided with an implantation tool storage part for placing an implantation tool.

Further, in a preferred embodiment of the present invention, the two sides of the storage portion for the implantation tool are provided with finger placement positions for picking up the implantation tool.

Further, in a preferred embodiment of the present invention, the implanting tool storage portion is provided with a seal sticker tearing position.

The application still provides a developments blood glucose monitor, has as above split type developments blood glucose monitor structure, has above-mentioned beneficial effect equally.

The utility model provides a pair of split type developments blood glucose monitor structure compares with prior art, include: the method comprises the following steps: a signal transmitter; an implant tool body for implanting the sensor in human skin; wherein, signal transmitter includes: a blood glucose data transmission part connected with the sensor; a blood sugar data transmitting part for transmitting the blood sugar data to the terminal; the blood sugar data transmission part is detachably connected with the blood sugar data transmitting part; the blood sugar data transmitting part is detachably connected with the implantation tool main body. When the developments blood sugar monitor disinfected, blood sugar data transmission portion can disinfect with implant instrument main part jointly, and blood sugar data transmission portion can dismantle out and avoid disinfecting, and its inside electronic component can avoid carrying out the damage that the disinfection process appears because of following the developments blood sugar monitor, compare in prior art, can avoid the damage that the inside electronic components caused at the in-process of disinfection processing to the developments blood sugar monitor, improve the durability of developments blood sugar monitor.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic diagram of a split-type dynamic blood glucose monitor structure applied to a dynamic blood glucose monitor according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a needle retracting mechanism of a dynamic blood glucose monitor according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a trigger portion of a dynamic blood glucose monitor according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of a signal emitter in a dynamic blood glucose monitor according to an embodiment of the present invention;

FIG. 5 is a schematic view of a dynamic blood glucose monitor according to an embodiment of the present invention in a needle feeding state;

FIG. 6 is a schematic view of a dynamic blood glucose monitor according to an embodiment of the present invention in a needle withdrawn state;

FIG. 7 is a schematic diagram of the components of a dynamic blood glucose monitor according to an embodiment of the present invention;

FIG. 8 is an exploded view of a dynamic blood glucose monitor according to an embodiment of the present invention;

FIG. 9 is a schematic view of a sterilization case provided in accordance with an embodiment of the present invention;

FIG. 10 is a schematic view of a dynamic blood glucose monitor according to an embodiment of the present invention disposed in a sterile storage case;

fig. 11 is a schematic perspective view of a dynamic blood glucose monitor according to an embodiment of the present invention.

Detailed Description

In order to make those skilled in the art better understand the technical solutions in the present application, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

Wherein, when an element is referred to as being "fixed" or "disposed" on another element, it can be directly on the other element or be indirectly disposed on the other element; when an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It will be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like, refer to an orientation or positional relationship illustrated in the drawings for convenience in describing the present application and to simplify description, and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present application.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, the meaning of a plurality of or a plurality of is two or more unless specifically limited otherwise.

It should be understood that the structures, ratios, sizes, and the like shown in the drawings are only used for matching the disclosure of the specification, so as to be understood and read by those skilled in the art, and are not used to limit the practical limit conditions of the present application, so that the modifications of the structures, the changes of the ratio relationships, or the adjustment of the sizes, do not have the technical essence, and the modifications, the changes of the ratio relationships, or the adjustment of the sizes, are all within the scope of the technical contents disclosed in the present application without affecting the efficacy and the achievable purpose of the present application.

As shown in fig. 1 to 11, the split type dynamic blood glucose monitor structure provided in the embodiment of the present application includes: a signal transmitter 8; an implant tool body for implanting the sensor 10 in the skin of a human body; wherein, the signal transmitter 8 includes: a blood glucose data transmission unit connected to the sensor 10; a blood sugar data transmitting part for transmitting the blood sugar data to the terminal; the blood sugar data transmission part is detachably connected with the blood sugar data transmitting part; the blood sugar data transmitting part is detachably connected with the implantation tool main body.

The embodiment of the utility model provides a split type developments blood glucose monitor structure, include: a signal transmitter 8; an implant tool body for implanting the sensor 10 in the skin of a human body; wherein, the signal transmitter 8 includes: a blood glucose data transmission unit connected to the sensor 10; a blood sugar data transmitting part for transmitting the blood sugar data to the terminal; the blood sugar data transmission part is detachably connected with the blood sugar data transmitting part; the blood sugar data transmitting part is detachably connected with the implantation tool main body. When the developments blood sugar monitor disinfected, blood sugar data transmission portion can disinfect with implant instrument main part jointly, and blood sugar data transmission portion can dismantle out and avoid disinfecting, and its inside electronic component can avoid carrying out the damage that the disinfection process appears because of following the developments blood sugar monitor, compare in prior art, can avoid the damage that the inside electronic components caused at the in-process of disinfection processing to the developments blood sugar monitor, improve the durability of developments blood sugar monitor.

Specifically, in the embodiment of the present invention, the signal transmitter 8 further includes: an emitter housing; the blood sugar data transmitting part is arranged on the inner side of the transmitter shell; the blood sugar data transmission part is arranged outside the emitter shell; the blood sugar data transmission part is detachably connected with the emitter shell. Since the blood glucose data transmitting part is provided outside the transmitter housing, the blood glucose data transmitting part can be detached from the signal transmitter 8.

Specifically, in the embodiment of the present invention, the transmitter housing includes: an emitter lower cover 802; an emitter upper cover 801 disposed on the emitter lower cover 802; a mounting base arranged on the lower cover 802 of the transmitter and used for mounting the blood sugar data transmitting part; and the first waterproof glue is arranged at the joint of the emitter upper cover 801 and the emitter lower cover 802.

The first waterproof glue is arranged at the joint of the upper transmitter cover 801 and the lower transmitter cover 802, so that water cannot invade the blood sugar data transmitting part from the joint.

Specifically, in the embodiment of the present invention, the blood sugar data transmission portion is disposed outside the transmitter housing and specifically includes: the emitter upper cover 801 is provided with a recess for placing the blood glucose data transmission part.

Specifically, in the embodiment of the present invention, the blood glucose data transmission unit includes: a conductive electrode 806 in communication with the flexible circuit board 804 for controlling the opening or closing of the blood glucose data transmitting part; a silica gel protective cover 807 arranged at the opening of the depressed part and detachably connected with the emitter upper cover 801; a sensor 10 needle for detecting blood glucose passing through the needle hole deep subcutaneously, the sensor 10 needle being connected to the conductive electrode 806; and the second waterproof glue is filled in the concave part.

The data detected by the sensor 10 is transmitted to the conductive electrode 806, the conductive electrode 806 is connected with the flexible circuit board 804, and when the blood glucose data transmitting part is turned on, the data is transmitted to the blood glucose data transmitting part through the flexible circuit board 804.

Specifically, in the embodiment of the present invention, the blood glucose data transmitting part includes: a printed circuit board 803 provided on the mounting base; a button cell 805 arranged on the mounting base and used for supplying power to the printed circuit board 803; and the flexible circuit board 804 is arranged on the mounting base and is used for being connected with the blood glucose data transmission part.

Specifically, in the embodiment of the present invention, a first waterproof adhesive is filled between the flexible circuit board 804 and the upper cover 801 and between the flexible circuit board and the lower cover 802; the second waterproof glue is specifically waterproof silica gel.

Specifically, in the embodiment of the utility model provides an in, split type developments blood glucose monitor structure still includes: a sterilizing storage box 11; the disinfection storage box 11 is provided with a transmitter storage part 110 for placing the signal transmitter 8; the sterilizing storage box 11 is provided with an implantation tool storage portion 111 for storing an implantation tool.

Specifically, in the embodiment of the present invention, finger placing positions 112 for picking up the implantation tool are provided on both sides of the implantation tool storage portion 111.

Specifically, in the embodiment of the present invention, the seal paper tearing position 113 is provided on the implantation tool storage portion 111.

The embodiment of the application also provides a dynamic blood sugar monitor, which has the split type dynamic blood sugar monitor structure and also has the beneficial effects.

More specifically, the dynamic blood glucose monitor applying the split type dynamic blood glucose monitor structure related to the embodiment is specifically as follows:

the dynamic blood glucose monitor comprises: the ejection device comprises a support body 1, wherein an ejection base 2 is arranged in the support body 1, and the ejection base 2 has a positioning state of contacting with the support body 1 and a separation state of separating from the support body 1; an ejection spring 3 is arranged between the supporting body 1 and the ejection base 2, the ejection spring 3 is used for pushing the ejection base 2 downwards, an ejection body 5 is arranged on the ejection base 2, and a sensing implantation needle 6 is arranged on the ejection body 5 and used for carrying a sensor 10 and sending the sensor 10 into the skin of a human body; furthermore, a triggering part 4 is involved for triggering the support body 1 to disengage the ejection base 2 from the support body 1; and a signal transmitter 8 for transmitting data sensed by the sensor 10 to the terminal. In the dynamic blood glucose monitor that this application relates to, press down the line and will touch ejection base 2 and break away from in supporting main part 1 when trigger part 4, ejection base 2 slides down under the spring effort, and drive ejection main part 5 and slide down, thereby drive sensing implantation needle 6 gliding and pierce human skin, adopt the elasticity of ejecting spring 3 to carry out the propelling movement, the operation is steady, the dynamics of propelling movement is invariable, the painful discomfort that the too big or undersize of exerting oneself that someone leads to as the factor brings, trigger part 4 one key triggers can not terminate because of being afraid of the pain at the in-process of implanting because of the human factor. Compared with the prior art, the sensor implantation needle can avoid pain and discomfort caused by too much or too little force due to human factors, and remarkably reduces discomfort of a user in the implantation process of the sensor implantation needle 6.

Wherein, developments blood glucose monitor still includes: a needle withdrawing structure 9 for receiving the skin penetrating sensing implant needle 6 in the support body 1.

Wherein, withdraw of needle structure 9 includes: a needle withdrawing spring 901 arranged on the ejection base 2; a needle seat 902 arranged on the top of the needle withdrawing spring 901; a needle body fixing seat 903 connected with the needle head seat 902 and used for fixing the sensing implantation needle 6; a first constraint arm 904 provided inside the support body 1; a second restraint arm 905 arranged on the ejection base 2, wherein the second restraint arm 905 has a contracted state restrained inside the first restraint arm 904 and a disengaged state disengaged from the restraint of the first restraint arm 904; the second constraint arm 905 is provided with a limit bump 906 for pressing down the needle head seat 902, and the second constraint arm 905 is in a contraction state, and the limit bump 906 presses down the limit needle head seat 902.

Wherein, a supporting contact 907 is arranged at one side of the upper end of the second constraint arm 905 close to the first constraint arm 904.

Wherein, the upper part of needle seat 902 is provided with a matching contact surface 908 which is matched with the limit bump 906.

Wherein, the periphery of the upper end of the needle seat 902 is provided with a first inclined plane end, and the lower end of the limit bump 906 is provided with a second inclined plane end matched with the first inclined plane end.

Wherein, an elastic hook arm 101 is arranged inside the supporting body 1; the ejection base 2 is provided with a positioning structure 201 matched with the elastic hook arm 101; the positioning structure 201 has a positioning state placed on the elastic hook arm 101 and a disengaged state disengaged from the elastic hook arm 101.

Wherein the elastic hook arm 101 comprises: a hook arm main body 102; a trigger protrusion 103 disposed on the hook arm main body 102 and engaged with the trigger part 4; the limiting hook body 104 is arranged on the hook arm main body 102 and positioned at the lower part of the trigger bump 103, and the limiting hook body 104 is used for limiting the positioning structure 201.

The supporting body 1 is further provided with a triggering portion 4, and the triggering portion 4 is used for triggering the elastic hook arm 101 to move outwards so that the positioning structure 201 is in a disengaged state.

Wherein, trigger part 4 includes: a launch button 401 provided on the upper portion of the support body 1 for pressing the elastic hook arm 101 downward and pushing the elastic hook arm 101 to move outward; a key compression spring 402 between the support body 1 and the launch key 401; the middle part of the launching key 401 is provided with a key positioning hook 403, and the key positioning hook 403 is abutted against the inner wall of the upper end of the supporting main body 1.

Wherein, the emission button 401 is further provided with an anti-trigger cover 7.

The triggering part of the emission key 401 is enveloped with the triggering part of the supporting upper cover in the supporting main body 1, the four bone positions of the emission key 401 are sleeved with the supporting upper cover, the two components are mutually constrained and mutually limited to ensure the stable triggering direction, the stable tripping in four directions can be ensured only by pressing the emission key 401 during triggering, and the problem of easy dislocation in the triggering process is solved.

In the dynamic blood glucose monitor according to the present embodiment, the trigger portion is located on the supporting body 1, and when the dynamic blood glucose monitor is used, the supporting body 1 can be triggered by pressing the trigger portion 4 to push the elastic hook arm 101 on the supporting body 1 to expand outward, so that the ejection base 2 loses the upward supporting force provided by the elastic hook arm 101, the ejection base 2 is disengaged from the position constraint of the hook arm, and is pushed downward under the action of the ejection spring 3 in a compressed state, the ejection body 5 moves downward along with the ejection base 2, and the sensing implantation needle 6 on the ejection body 5 pierces the skin of the human body.

Then, pierce human skin at sensing implantation needle 6, the sensor 10 that carries on the sensing implantation needle 6 persists in the human body, and sensing implantation needle 6 is retrieved in supporting main part 1 under the effect of withdrawing needle structure 9, and concrete process is:

the upper supporting cover is provided with a first constraint arm 904, the ejection base 2 is provided with a second constraint arm 905, the first constraint arm 904 can constrain the second constraint arm 905 on the ejection base 2 to prevent the second constraint arm 905 from expanding outwards, and as shown in fig. 5 and 6, the second constraint arm 905 does not bear the enveloping force of the first constraint arm 904 after moving downwards for a certain distance. Because the second constraint arm 905 is provided with the limit bump 906 for constraining the needle seat 902 to move upwards, when the second constraint arm 905 is under the enveloping force of the first constraint arm 904, the limit bump 906 limits the needle seat 902 to move upwards, and at this time, the needle withdrawing spring 901 is in a compressed state; however, as the ejection base 2 is separated from the elastic hook arm 101, the ejection spring 3 pushes the ejection base 2 downwards, after the implanted needle carrying sensor 10 penetrates the skin of the human body, the second constraint arm 905 moves downwards along with the ejection base 2 and is no longer subjected to the enveloping force of the first constraint arm 904, the needle withdrawing spring 901 which is in the compressed state provides an upward acting force for the needle base 902, the second constraint arm 905 which loses the constraint force provided by the first constraint arm 904 is moved outwards after being subjected to the upward acting force of the needle base 902, and the implanted needle is withdrawn into the support body 1 under the acting force of the needle withdrawing spring 901 to complete the needle withdrawing action.

It should be noted that the blood glucose emitting device according to the embodiment of the present application mainly includes an implantation tool portion and a signal emitter 8, and in order to prevent secondary infection, the implantation tool cannot be reused after implantation is completed, that is, the implantation tool is a disposable product. When the sensor 10 is implanted, the signal emitter 8 is attached to the skin, and the bottom of the signal emitter 8 is provided with a sticker 808.

After withdrawing the needle, the implanted needle is completely recovered into the support body 1 and is not exposed outside the device, so that accidental injury of the user by the needle body can be avoided; in addition, withdraw from behind the needle second restraint arm 905 can't return to first restraint arm 904 inboard again, press this moment trigger part 4 can't pierce human skin with sensing implantation needle 6 secondary, therefore the developments blood glucose monitor that this embodiment relates to can't carry out the secondary usage, so have the advantage that prevents sensing implantation needle 6 reutilization, help improving the standardization of medical equipment use, more sanitary.

Wherein, the support body 1 includes: supporting the upper cover 105; a support lower cover 106 fitted with the support upper cover 105; the support lower cover 106 includes: a mounting butt joint part which is used for matching and connecting with the supporting upper cover and is covered on the outer side of the ejection main body 5; a position restraining part connected with the lower end of the butt joint part and used for restraining the position of the signal emitter 8; and the base ejection part is connected with the lower end of the position restriction part and can be attached to the surface of the skin.

Wherein, the signal transmitter 8 includes: a blood glucose data transmission unit connectable to the blood glucose test sensor 10; a blood sugar data transmitting part for transmitting the blood sugar data to the terminal; the blood sugar data transmission part is detachably connected with the blood sugar data emission part, and the blood sugar data emission part is assembled in the support main body 1.

In this embodiment, the developments blood glucose monitor that relates to is split type structure, and it should be explained that the disinfection environment of developments blood glucose monitor is in aseptic workshop, and the disinfection mode mainly adopts laser ray disinfection, and the sealed sticker that just opens the product when the user used is sealed the processing to the product to the disinfection completion. Because the electronic component part can appear damaging the components and parts after disinfecting, so do the disconnect-type design with electronic components, what the separation adopted is that implant instrument and transmitter separation assemble subassembly such as the waterproof silica gel visor of sensor sensing implantation needle 6 in implanting the instrument and carry out whole disinfection processing, so the design can realize comprehensive disinfection, can not produce any influence to the electron component ware again, ensures that the product uses safelyr and relieved.

As shown in fig. 9 and 10, the dynamic blood glucose monitor according to the present embodiment may further include a sterilization storage case 11; the disinfection storage box 11 is provided with a transmitter storage part 110 for placing the signal transmitter 8; the sterilizing storage box 11 is provided with an implantation tool storage portion 111 for storing the implantation tool. More specifically, both sides of the implant tool storage part 111 are provided with finger placement positions 112 for picking up the implant tool. In addition, a seal sticker tearing position 113 is provided on the implantation tool storage portion 111. This kind of mode of putting can guide the user to use fast, and the user only needs to tear the seal membrane and just can pack the transmitter into the implantation instrument facing to the draw-in groove, and it is convenient, labour saving and time saving to install.

Wherein, the signal transmitter 8 includes: an emitter housing composed of an emitter upper cover 801 and an emitter lower cover 802; the mounting base is arranged in the emitter shell; a printed circuit board 803, a flexible circuit board 804, a button cell 805 and a conductive electrode 806 which are arranged on the mounting base; a silica gel protective cover 807 clamped with the emitter upper cover 801; waterproof glue materials are filled in the joint of the upper transmitter cover 801 and the lower transmitter cover 802; waterproof glue materials are filled between the flexible circuit board 804 and the emitter upper cover 801 and between the flexible circuit board and the emitter lower cover 802; waterproof silicone is filled between the silicone protective cover 807 and the conductive electrode 806.

The transmitter upper cover FPC board adopts waterproof glue to realize the sealing and waterproof functions by dropping the waterproof glue into the glue seams; the waterproofing of the FPC board and the lower cover of the emitter is realized by coating a layer of waterproof glue on the bottoms of the emitter and the FPC board to prevent the FPC board and the lower cover of the emitter from sealing and waterproofing. The emitter upper cover 801 and the emitter lower cover 802 are waterproof by means of penetrating waterproof glue into the connecting seams to meet the waterproof requirement.

The silica gel protective cover, the waterproof silica gel and the conductive electrode are an assembly part, the conductive electrode is arranged in the waterproof silica gel, the waterproof silica gel is arranged in the silica gel protective cover 807, the silica gel protective cover 807 is provided with a buckle which is connected with the emitter upper cover 801 in a clamping mode, a concave point is arranged at the joint part of the emitting edge to position the direction, and the silica gel is deformed by the pulling force of the buckle position to achieve the waterproof effect. Specifically, the number of buckles is 3, and the number of pits is 3.

When 3 buckling positions of the silica gel protective cover 807 are buckled into the upper cover 801 of the emitter, the waterproof silica gel is deformed by the pulling force of the buckling positions, and when the conductive electrodes are communicated with the circuit of the FPC board in the deformation process, the waterproof silica gel and the FPC board can achieve the waterproof effect due to the compression force.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. A split type developments blood glucose monitor structure which characterized in that includes: a signal transmitter; an implant tool body for implanting the sensor in human skin; wherein the signal transmitter includes: a blood glucose data transmission part connected with the sensor; a blood sugar data transmitting part for transmitting the blood sugar data to the terminal; the blood sugar data transmission part is detachably connected with the blood sugar data transmitting part; the blood sugar data transmitting part is detachably connected with the implantation tool main body.

2. The split-type ambulatory blood glucose monitor structure as set forth in claim 1, wherein the signal transmitter further comprises: an emitter housing; the blood glucose data transmitting part is arranged on the inner side of the transmitter shell; the blood glucose data transmission part is arranged outside the emitter shell; the blood sugar data transmission part is detachably connected with the emitter shell.

3. The split-type ambulatory blood glucose monitor structure of claim 2, wherein the emitter housing comprises: a lower cover of the emitter; the emitter upper cover is arranged on the emitter lower cover; the installation base is arranged on the lower cover of the emitter and used for installing the blood sugar data emitting part; and the first waterproof glue is arranged at the joint of the upper transmitter cover and the lower transmitter cover.

4. The split type dynamic blood glucose monitor structure of claim 3, wherein the blood glucose data transmission part is disposed outside the transmitter housing and specifically comprises: the emitter upper cover is provided with a concave part, and the concave part is used for placing the blood sugar data transmission part.

5. The split-type ambulatory blood glucose monitor structure as set forth in claim 4, wherein the blood glucose data transmission portion comprises: the conductive electrode is communicated with the flexible circuit board and used for controlling the opening or closing of the blood glucose data transmitting part; the silica gel protective cover is arranged at the opening of the depressed part and is detachably connected with the upper cover of the emitter; the sensor needle is used for penetrating through the needle hole to deeply detect the blood sugar subcutaneously and is connected with the conductive electrode; and the second waterproof glue is filled in the concave part.

6. The split-type ambulatory blood glucose monitor structure as set forth in claim 5, wherein the blood glucose data transmitting portion comprises: the printed circuit board is arranged on the mounting base; the button battery is arranged on the mounting base and used for supplying power to the printed circuit board; the flexible circuit board is arranged on the mounting base and is used for being connected with the blood glucose data transmission part; first waterproof glue is filled between the flexible circuit board and the upper cover and between the flexible circuit board and the lower cover of the emitter; the second waterproof glue is specifically waterproof silica gel.

7. The split-type ambulatory blood glucose monitor structure of claim 1, wherein the split-type ambulatory blood glucose monitor structure further comprises: sterilizing the storage box; the disinfection storage box is provided with a transmitter storage part for placing the signal transmitter; the disinfection storage box is provided with an implantation tool storage part for storing the implantation tool.

8. The split type structure of dynamic blood glucose monitor according to claim 7, wherein finger placement positions for picking up the implantation tool are provided on both sides of the implantation tool storage part.

9. The split type structure of dynamic blood glucose monitor according to claim 8, wherein the implanting tool storage portion is provided with a seal sticker tearing position.

10. A dynamic blood glucose monitor, comprising: the split-type ambulatory blood glucose monitor structure of any one of claims 1-9.

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