CN211835838U

CN211835838U - Wearable hand function electrical stimulation therapeutic apparatus

Info

Publication number: CN211835838U
Application number: CN202020125187.9U
Authority: CN
Inventors: 李飞
Original assignee: Shenzhen Xft Medical Ltd
Current assignee: Shenzhen Xft Medical Ltd
Priority date: 2020-01-20
Filing date: 2020-01-20
Publication date: 2020-11-03
Anticipated expiration: 2030-01-20

Abstract

The utility model provides a wearable hand function electrical stimulation therapeutic apparatus, which comprises a shell and a circuit board, wherein the shell comprises an upper cover and a lower cover, the lower cover is formed integrally with the lower cover by a lower cover shell, a metal electrode, a magnetic suction charging interface and a binding band through in-mold injection molding, a FPC connector, a first connector and a second connector are welded on the circuit board, a touch key circuit is manufactured on a flexible circuit board and is directly pasted on the inner side of the upper cover, and the flexible circuit board is connected with a main control circuit on the circuit board through the FPC connector; first terminal line one end links to each other with the metal electrode, and the other end passes through first connector and links to each other with the circuit board, and second terminal line one end is inhaled with magnetism and is inhaled the interface that charges and link to each other, and the other end passes through the second connector and links to each other with the circuit board, and the circuit board passes through the fix with screw and at the lower cover casing inboard, and the complete machine adopts waterproof design, and waterproof grade is up to IPX6, has solved equipment because the problem of intaking and damage, has improved the fail safe nature of equipment.

Description

Wearable hand function electrical stimulation therapeutic apparatus

Technical Field

The utility model belongs to the technical field of wearable medical rehabilitation instrument, concretely relates to wearable hand function electrical stimulation therapeutic instrument.

Background

At present, the wearable therapeutic apparatus is widely applied to medical equipment at present due to the fact that the wearable therapeutic apparatus is portable and rapid, has partial calculation function, and can be connected with a Russian mobile phone or various terminals, however, the wearable hand function electrical stimulation therapeutic apparatus at present has many problems, such as the structure does not have a waterproof function; the keys are mechanical keys, so that the service life of the keys is limited; most charging interfaces use USB interfaces, one-hand operation cannot be achieved, and the service life of the interfaces is limited by plugging and unplugging.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a purpose aims at the above deficiency, the utility model provides a wearable hand function electric stimulation therapeutic instrument, the complete machine adopts waterproof design, the waterproof grade is up to IPX6, the problem that the equipment damages because of intaking is solved, the safe reliability of equipment has been improved; all keys adopt touch keys, so that the service life of the keys is greatly prolonged; the formula interface that charges is inhaled to the interface that charges adopts magnetism, can realize that the one hand pulls out and inserts the charging wire, does not divide positive and negative random insertion.

The utility model is realized by the following technical scheme, a wearable hand function electric stimulation therapeutic apparatus, which comprises a shell and a circuit board, wherein the shell comprises an upper cover and a lower cover, the lower cover is formed integrally with the lower cover by a lower cover shell, a metal electrode, a magnetic suction charging interface and a binding band through in-mold injection molding, a FPC connector, a first connector and a second connector are welded on the circuit board, a touch key circuit is manufactured on a flexible circuit board and is directly pasted on the inner side of the upper cover, and the flexible circuit board is connected with a main control circuit on the circuit board through the FPC connector; first terminal line one end links to each other with the metal electrode, and the other end passes through first connector and links to each other with the circuit board, and second terminal line one end is inhaled with magnetism and is inhaled the interface that charges and link to each other, and the other end passes through the second connector and links to each other with the circuit board, and the circuit board passes through the screw fixation and is inboard at the lower cover casing.

Furthermore, the upper cover and the lower cover are assembled together through inner side buckling positions and are glued and fixed on the inner sides of the edges.

Furthermore, the circuit board comprises a charging circuit, a switching circuit, a power supply circuit, an MCU master control circuit, a myoelectricity detection circuit, an electrical stimulation circuit and a display screen circuit, wherein the charging circuit, the switching circuit and the power supply circuit are sequentially connected, the myoelectricity detection circuit, the electrical stimulation circuit and the display screen circuit are respectively connected with the MCU master control circuit, and the power supply circuit respectively supplies power to the display screen circuit, the MCU master control circuit, the myoelectricity detection circuit and the electrical stimulation circuit.

Furthermore, the interface that charges is inhaled to magnetism links to each other through the second connector on second terminal line and the circuit board, and the second connector links to each other with charging circuit on the circuit board, and charging circuit links to each other with the battery, and equipment charges for the battery through the external charger of the interface that charges that magnetism is inhaled.

Further, the circuit board further comprises an electromyographic input/electrical stimulation output switching circuit, wherein the metal electrode is connected with a first connector through a first terminal wire, and the first connector is connected with the electromyographic input/electrical stimulation output switching circuit.

Compared with the prior art, the wearable hand function electrical stimulation therapeutic apparatus provided by the utility model adopts a waterproof design, the waterproof grade is up to IPX6, the safety and reliability of the apparatus are improved, and the problem that the apparatus is damaged due to water inflow is solved; all keys adopt touch keys, so that the service life of the keys is greatly prolonged; the formula interface that charges is inhaled to the interface that charges adopts magnetism, can realize that the one hand pulls out and inserts the charging wire, does not divide positive and negative random to insert, charges more convenient safety.

Drawings

Fig. 1 is a schematic view of the whole wearable hand-function electrical stimulation treatment instrument of the present invention;

fig. 2 is a schematic view of the wearable hand-function electrical stimulation treatment apparatus after the whole apparatus is assembled;

fig. 3 is a schematic diagram of a circuit board of the wearable hand-function electrical stimulation treatment instrument.

The reference numbers are as follows:

1, covering the cover; 2, covering the lower cover; 3, a circuit board; 4 a flexible circuit board; 5, touching the key circuit; 6, magnetically attracting the charging interface; 7 a metal electrode; 8, binding a belt; 9 an FPC connector; 10 a first connector; 11 a first terminal line; 12 a second connector; 13 second terminal line

Detailed Description

The overall schematic diagram of the whole machine of the utility model is shown in fig. 1, and the whole machine comprises a shell and a circuit board. The shell comprises an upper cover 1 and a lower cover, wherein the lower cover is formed by a lower cover shell body 2, a metal electrode 7, a magnetic suction charging interface 6 and a binding belt 8 through in-mold injection molding and the lower cover in an integrated mode. The FPC connector 9, the first connector 10, and the second connector 12 are soldered on the circuit board 3; the touch key circuit 5 is manufactured on the flexible circuit board 4 and is directly pasted on the inner side of the upper cover 1, and the flexible circuit board 4 is connected with the circuit board 3 through the FPC connector 9; one end of a first terminal line 11 is connected with the metal electrode 7, and the other end is connected with the circuit board 3 through a first connector 10; one end of a second terminal wire 13 is connected with the magnetic charging interface 6, and the other end of the second terminal wire is connected with the circuit board 3 through a second connector 12; the circuit board 3 is fixed inside the lower cover case 2 by screws.

The upper cover and the lower cover are assembled together through the inner side buckling position, and the inner side of the edge is glued and fixed to realize the waterproof function, and the schematic diagram after the assembly is shown in figure 2.

The circuit board 3 comprises a charging circuit, a switching circuit, a power circuit, an MCU master control circuit, a myoelectricity detection circuit, an electrical stimulation circuit and a display screen circuit, wherein the charging circuit, the switching circuit and the power circuit are sequentially connected, and the myoelectricity detection circuit, the electrical stimulation circuit and the display screen circuit are respectively connected with the MCU master control circuit.

The interface 7 that charges is inhaled to magnetism links to each other through second terminal line 13 and second connector 12 on the circuit board 3, and second connector 12 links to each other with charging circuit on the circuit board 3, and charging circuit links to each other with the battery, and equipment charges for the battery through the external charger of interface 7 that charges that magnetism is inhaled to magnetism.

The battery supplies power to the power circuit through the on-off circuit, and the power circuit supplies power to the display screen circuit, the MCU main control circuit, the myoelectricity detection circuit and the electrical stimulation circuit respectively.

The MCU main control circuit controls the display screen circuit to display a working interface, processes the myoelectric signals transmitted by the myoelectric detection circuit, controls the myoelectric detection circuit to work, controls the electric stimulation circuit to output electric stimulation signals and processes touch key signals.

The therapeutic instrument collects the autonomous myoelectric signals of a human body through a metal electrode 7, the metal electrode 7 is connected with a first connector 10 through a first terminal line 11, the first connector 10 is connected with a myoelectric input/electric stimulation output switching circuit, the collected myoelectric signals are transmitted to a myoelectric detection circuit to be amplified, filtered and the like, and the processed signals are transmitted to an MCU main control circuit.

The MCU main control circuit controls the electrical stimulation circuit to generate an electrical stimulation signal, and the electrical stimulation signal is transmitted to the myoelectricity input/electrical stimulation output switching circuit and then transmitted to a human body treatment part through the first connector 10, the first terminal line 11 and the metal electrode 7.

The touch key circuit 5 is manufactured on the flexible circuit board 4 and directly adhered to the inner side of the upper cover of the therapeutic instrument, the flexible circuit board 4 is connected with the MCU main control circuit through the FPC connector 9, and the FPC connector 9 is welded on the circuit board 3. The touch key circuit 5 transmits the detected key signals to the FPC connector 9 through the flexible circuit board 4, and then transmits the detected key signals to the MCU main control circuit to analyze and process the key signals.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims

1. A wearable hand function electrical stimulation therapeutic apparatus is characterized by comprising a shell and a circuit board, wherein the shell comprises an upper cover and a lower cover, the lower cover is formed by a lower cover shell, a metal electrode, a magnetic suction charging interface and a binding band through in-mold injection molding and is integrally formed with the lower cover, an FPC connector, a first connector and a second connector are welded on the circuit board, a touch key circuit is manufactured on a flexible circuit board and is directly adhered to the inner side of the upper cover, and the flexible circuit board is connected with a main control circuit on the circuit board through the FPC connector; first terminal line one end links to each other with the metal electrode, and the other end passes through first connector and links to each other with the circuit board, and second terminal line one end is inhaled with magnetism and is inhaled the interface that charges and link to each other, and the other end passes through the second connector and links to each other with the circuit board, and the circuit board passes through the screw fixation and is inboard at the lower cover casing.

2. The wearable hand-function electrical stimulation treatment instrument of claim 1, wherein the upper cover and the lower cover are assembled together through inner buckling positions and are fixed by gluing on the inner sides of the edges.

3. The wearable hand function electrical stimulation treatment instrument according to claim 1, wherein the circuit board comprises a charging circuit, a switching circuit, a power supply circuit, an MCU master control circuit, a myoelectricity detection circuit, an electrical stimulation circuit and a display screen circuit, wherein the charging circuit, the switching circuit and the power supply circuit are sequentially connected, the myoelectricity detection circuit, the electrical stimulation circuit and the display screen circuit are respectively connected with the MCU master control circuit, and the power supply circuit respectively supplies power to the display screen circuit, the MCU master control circuit, the myoelectricity detection circuit and the electrical stimulation circuit.

4. The wearable hand-function electrical stimulation treatment instrument as claimed in claim 3, wherein the magnetic charging interface is connected to a second connector on the circuit board through a second terminal wire, the second connector is connected to a charging circuit on the circuit board, the charging circuit is connected to the battery, and the device charges the battery through a charger externally connected to the magnetic charging interface.

5. The wearable hand-function electrical stimulation treatment instrument as claimed in claim 3, wherein the circuit board further comprises a myoelectric input/electrical stimulation output switching circuit, wherein the metal electrode is connected to the first connector through a first terminal line, and the first connector is connected to the myoelectric input/electrical stimulation output switching circuit.