CN222234920U - A multifunctional portable medical video acquisition and transmission device - Google Patents

Abstract

A multifunctional portable medical video acquisition and transmission device, the utility model relates to the technical field of medical auxiliary vision systems. The utility model is to solve the problem that in the video acquisition and transmission device of the auxiliary vision system in the prior art, the antenna is installed on the outside of the device, and the video signal transmission device is large in size and inconvenient to carry during surgery. The utility model includes a housing assembly, a circuit assembly, an inverter and a battery; the circuit assembly is installed in the housing assembly, the inverter and the battery are arranged at the rear of the housing assembly, and the inverter and the circuit assembly are electrically connected to the battery. The utility model is used for medical auxiliary vision systems.

Description

Multifunctional portable medical video acquisition and transmission device

Technical Field

The utility model relates to the technical field of medical auxiliary vision systems, in particular to a multifunctional portable medical video acquisition and transmission device.

Background

The wearable medical instrument is an electronic medical instrument with the characteristics of wearable performance and portability, and can sense, record, analyze, regulate and control, intervene and even treat diseases or maintain health states under the support of software. With the advent, application and development of various innovative technologies, the wearable medical instrument is greatly promoted in clinical technology application services, and with the continuous perfection of the medical industry chain in China, the development of the medical instrument tends to diversify, and the module for realizing the visualization of the intraoperative scene in surgery and the later development can realize the three-dimensional display of the patient information by means of MR glasses. The MR glasses need to be transmitted with power by a receiver, the MR glasses are connected with the receiver by a signal transmission line, the receiver receives the wireless video signal transmitted by the video acquisition and transmission device, and then the wireless video signal is converted into a wired video signal to be transmitted to the MR glasses through the signal transmission line.

In the prior art, an irreplaceable built-in lithium battery is generally adopted for power supply, when the performance of the built-in lithium battery is reduced after long-time use, a common user is difficult to replace the built-in lithium battery, an antenna is arranged outside the device, the volume of the video signal transmission device is large, and the video signal transmission device is inconvenient to carry in the operation process.

Disclosure of utility model

The utility model aims to solve the problems that in the prior art, an antenna is arranged outside a device, the volume of a video signal transmission device is large, and the video signal transmission device is inconvenient to carry in the operation process, and further provides a multifunctional portable medical video acquisition and transmission device.

The technical scheme adopted for solving the problems is that the multifunctional portable medical video acquisition and transmission device comprises a shell component, a circuit component, an inverter and a battery, wherein the circuit component is arranged in the shell component, the inverter and the battery are arranged at the rear part of the shell component, and the inverter and the circuit component are electrically connected with the battery.

Preferably, the housing assembly includes a front case and a rear case fitted to each other, the circuit assembly is disposed between the front case and the rear case, and the inverter and the battery are mounted in the rear case.

Preferably, the circuit assembly is provided with a power supply output head, and the power supply output head penetrates out of the front shell.

Preferably, the circuit assembly is further provided with a display module, the front shell is provided with a semi-transparent window, and the display module corresponds to the semi-transparent window on the front shell.

Preferably, the circuit assembly is further provided with a charging module, the charging module is electrically connected with the battery, and the charging module penetrates out of the front shell.

Preferably, the circuit assembly is further provided with a controller module and an antenna module, and the antenna module receives wireless video signals and transmits the wireless video signals to the controller module.

Preferably, the circuit assembly is further provided with a micro switch, and the front shell is provided with keys matched with the micro switch.

Preferably, the inverter controls the bidirectional direct current/direct current converter to work forward through the controller, converts the low-voltage direct current voltage of the battery into high-voltage direct current voltage, and simultaneously controls the bidirectional direct current/direct current converter to work forward, and converts the high-voltage direct current voltage output by the bidirectional direct current/direct current converter into alternating current voltage.

The utility model has the following beneficial technical effects:

The utility model is used for a wearable medical auxiliary vision system, a wireless video signal is transmitted through a portable video acquisition and transmission device, a receiver receives the wireless video signal transmitted by the video acquisition and transmission device, the MR glasses are connected with the receiver by adopting a signal transmission line, and a doctor wears the MR glasses, so that three-dimensional display of patient information can be realized in the operation process.

The portable video acquisition and transmission device is provided with the inverter to convert the direct current voltage output by the battery into alternating current voltage, and the portable video acquisition and transmission device converts the direct current voltage output by the battery into alternating current through the inverter to supply power for portable medical equipment such as an ultrasonic host machine and the like in medical scenes where external alternating current cannot be used. The antenna is arranged in the shell, and can supply power for portable medical equipment such as a display terminal of the wearable medical auxiliary vision system, a host of the ultrasonic diagnostic device and the like.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is an isometric view of the present utility model;

FIG. 3 is one of the exploded schematic views of the present utility model;

FIG. 4 is a second exploded view of the present utility model;

FIG. 5 is a schematic view of the utility model as applied to a wearable medical assisted vision system;

in the figure, 1, a front shell, 2, a rear shell, 3, a circuit assembly, 31, a power supply output head, 32, a display module, 33, a charging module, 34, an antenna module, 35, a micro switch, 36, a controller module, 4, an inverter, 5, a battery, 6, a back clamp, 7, a video acquisition and transmission device, 8, a power supply transmission line and 9, an ultrasonic host.

Detailed Description

The present utility model will be further described in detail with reference to the drawings and examples, which are provided to illustrate the present utility model and not to limit the present utility model.

The first embodiment is described with reference to fig. 1 to 5, and the multifunctional portable medical video acquisition and transmission device of the first embodiment includes a housing assembly, a circuit assembly 3, an inverter 4 and a battery 5, wherein the circuit assembly 3 is installed in the housing assembly, the inverter 4 and the battery 5 are disposed at the rear portion of the housing assembly, and the inverter 4 and the circuit assembly 3 are electrically connected with the battery 5.

The wearable medical instrument is an electronic medical instrument with the characteristics of being wearable and portable, and can realize visualization of an intraoperative scene in an operation by means of MR (magnetic resonance) glasses and simultaneously realize three-dimensional display of patient information by a later developed module. The utility model is used for medical portable wearable equipment, the video acquisition and transmission device transmits wireless video signals, the MR glasses are connected with the receiver by adopting a signal transmission line, and the receiver receives the wireless video signals transmitted by the video acquisition and transmission device.

In the second embodiment, referring to fig. 1 to 5, the housing assembly includes a front case 1 and a rear case 2 that are matched with each other, the circuit assembly 3 is disposed between the front case 1 and the rear case 2, the rear case 2 is provided with an inverter 4 and a battery 5, and the battery 5 is mounted on the rear case 2 by hook insertion.

In this embodiment, the inverter 4 controls the bidirectional dc/dc converter to operate in the forward direction by the controller, converts the low-voltage dc voltage of the battery 5 into the high-voltage dc voltage, and simultaneously controls the bidirectional dc/ac converter to operate in the forward direction, and converts the high-voltage dc voltage output by the bidirectional dc/dc converter into the ac voltage. The construction of the inverter 4 is preferably known from the prior art, using common standard parts or components known to the person skilled in the art, the construction and principle of which are known to the person skilled in the art from the technical manual.

The ultrasound mainframe 9 is typically smaller in size and lighter in weight, such as in a form-factor that may resemble a notebook computer. The ultrasound mainframe 9 may be placed on a cart when it is desired to push the ultrasound mainframe 9 to the place where it is desired to use. In a medical scenario that external alternating current cannot be used, an external power supply is needed to supply power to the ultrasonic host 9, the video acquisition and transmission device 7 is connected with the ultrasonic host 9 through the power supply transmission line 8, and the video acquisition and transmission device 7 converts direct current output by the battery 5 into alternating current through the inverter 4 to supply power to the ultrasonic host 9.

Other components and connection relationships are the same as those of the first embodiment.

In the third embodiment, the present embodiment is described with reference to fig. 1 to 5, in which the circuit assembly 3 is provided with a power supply output head 31, and the power supply output head 31 penetrates the front case 1. The circuit assembly 3 is further provided with a display module 32, the front shell 1 is provided with a semi-transparent window, and the display module 32 corresponds to the semi-transparent window on the front shell 1. The circuit assembly 3 is further provided with a charging module 33, the charging module 33 is electrically connected with the battery 5, and the charging module 33 penetrates out of the front shell 1.

The display module 32 used in this embodiment is one of an LED nixie tube display module or a liquid crystal display module with backlight, and at least a part of the front case 1 forms a semi-transparent window, and the display module 32 on the circuit assembly 3 and the semi-transparent window on the front case 1 are aligned with each other. The collecting and transmitting device of the present embodiment charges the battery 5 through the charging module 33, and temporarily supplies power to portable medical equipment such as a main unit of the ultrasonic diagnostic apparatus through the power supply output head 31.

Other components and connection relationships are the same as those of the first embodiment.

In the fourth embodiment, referring to fig. 1 to 5, the circuit assembly 3 is further provided with a controller module 36 and an antenna module 34, and the antenna module 34 receives a wireless video signal and transmits the wireless video signal to the controller module 36. The circuit assembly 3 is also provided with a micro switch 35, and the front shell 1 is provided with keys matched with the micro switch 35.

The front shell 1 adopted in this embodiment is embedded with a key matched with the micro switch 35, and the key is a rubber or plastic key, and when the key is pressed, the micro switch 35 can be triggered, so that the functions of on-off, channel switching and mode switching are realized. The antenna of the wireless video receiver of the embodiment is arranged in the shell component, and the wireless video receiver is small in size, light in weight and convenient to carry.

The circuit assembly 3 of this embodiment is further provided with a controller module 36, where the controller module 36 is electrically connected with the power supply output head 31, the display module 32, the charging module 33, the antenna module 34 and the micro switch 35, and the above electrical components are all existing electrical components, and all the components, structures and principles of which are known by the general standard components or those skilled in the art are known by the technical manual.

Other components and connection relationships are the same as those of the first embodiment.

In the fifth embodiment, referring to fig. 1 to 5, a back clip 6 is preferably disposed on the back of the rear case 2, the back clip 6 is composed of a surface clip and a bottom clip, the surface clip and the bottom clip are rotatably connected through a pin, and a spring is disposed between the surface clip and the bottom clip, or the back clip 6 is a clip.

The back clamp 6 adopted in the embodiment is a spring clamp or a clamp, and the video acquisition and transmission device can be hung on a trolley of the ultrasonic diagnostic device in the operation process of a doctor to continuously supply power to the ultrasonic diagnostic device.

Other components and connection relationships are the same as those of the first embodiment.

The working principle of the utility model is as follows:

The utility model is used for a wearable medical auxiliary vision system, a portable video acquisition and transmission device is used for transmitting wireless video signals, the MR glasses are connected with a receiver by adopting a signal transmission line, the receiver receives the wireless video signals transmitted by the video acquisition and transmission device, and a doctor wears the MR glasses to perform an operation. The portable video acquisition and transmission device is provided with the inverter 4 for converting the direct current voltage output by the battery 5 into alternating current voltage, and the portable video acquisition and transmission device converts the direct current output by the battery 5 into alternating current through the inverter 4 to supply power for portable medical equipment such as an ultrasonic diagnostic device host computer and the like in medical scenes where external alternating current cannot be used.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the present utility model, but various modifications and variations can be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (5)

1. A multifunctional portable medical video acquisition and transmission device, characterized in that it comprises a housing assembly, a circuit assembly (3), an inverter (4) and a battery (5); the circuit assembly (3) is installed in the housing assembly, the inverter (4) and the battery (5) are arranged at the rear of the housing assembly, and the inverter (4) and the circuit assembly (3) are electrically connected to the battery (5); The housing assembly comprises a front housing (1) and a rear housing (2) which cooperate with each other, the circuit assembly (3) is arranged between the front housing (1) and the rear housing (2), and an inverter (4) and a battery (5) are installed in the rear housing (2); The circuit assembly (3) is also provided with a charging module (33), the charging module (33) is electrically connected to the battery (5), and the charging module (33) passes through the front shell (1); The circuit assembly (3) is also provided with a controller module (36) and an antenna module (34); the antenna module (34) receives a wireless video signal and transmits it to the controller module (36). 2. The multifunctional portable medical video acquisition and transmission device according to claim 1, characterized in that: a power output head (31) is provided on the circuit component (3), and the power output head (31) passes through the front shell (1). 3. The multifunctional portable medical video acquisition and transmission device according to claim 1 is characterized in that: a display module (32) is also provided on the circuit component (3), a semi-transparent window is provided on the front shell (1), and the display module (32) corresponds to the semi-transparent window on the front shell (1). 4. The multifunctional portable medical video acquisition and transmission device according to claim 1, characterized in that: a micro switch (35) is also provided on the circuit component (3), and a button matching the micro switch (35) is provided on the front shell (1). 5. The multifunctional portable medical video acquisition and transmission device according to claim 1 is characterized in that: the inverter (4) controls the bidirectional DC/DC converter to work in the forward direction through the controller, converting the low-voltage DC voltage of the battery (5) into a high-voltage DC voltage, and at the same time controls the bidirectional DC/AC converter to work in the forward direction, converting the high-voltage DC voltage output by the bidirectional DC/DC converter into an AC voltage.