CN215959995U - Robot and system for medical operation of sampling new coronavirus - Google Patents

Abstract

The utility model discloses a robot and a system for sampling medical operation of new coronavirus, wherein the robot for sampling medical operation of new coronavirus comprises an elastic connecting piece, a plurality of connecting plates, a plurality of telescopic assemblies, a driving assembly and a flexible sampling assembly. A plurality of connecting plates all are connected with elastic connection spare, and along elastic connection spare's length direction interval distribution. The both ends of every flexible subassembly are connected with two adjacent connecting plates respectively, and flexible subassembly includes a plurality of extensible members that encircle the elastic connection spare setting, and a plurality of extensible members divide into two sets of at least flexible groups, and every flexible group of group includes two extensible members that relative elastic connection spare set up. The drive assembly can drive the telescopic piece to stretch and retract. Flexible sampling subassembly wears to establish in a plurality of connecting plates and a plurality of flexible subassembly, and flexible sampling subassembly is used for gathering the new coronavirus specimen of respiratory track. The robot can freely bend and move in the special-shaped respiratory tract of a human body, so that the sampling of the respiratory tract secretion of the human body is realized, the pain of examination is relieved, and the difficulty of the examination is reduced.

Description

Robot and system for medical operation of sampling new coronavirus

Technical Field

The utility model relates to the technical field of medical instruments, in particular to a robot and a system for sampling new coronavirus for medical operation.

Background

The examination of human body cavity is one of the common means for doctors to diagnose diseases, such as examination of narrow cavities such as nasal cavity, oral cavity, trachea, etc. and collection of mucosal secretion, but there are many blind areas due to the bending and narrow space of the narrow cavities such as nasal cavity, oral cavity, trachea, etc. The mechanical arm of the existing robot for cavity medical operation is generally linear or has less bending freedom, which brings inconvenience to the examination of doctors and also brings pain to patients.

SUMMERY OF THE UTILITY MODEL

One object of the present invention is to provide a novel robot for sampling coronavirus for medical operation, which can have a plurality of combinations of translational and bending degrees of freedom.

The utility model also aims to provide a system for sampling medical operation of the novel coronavirus, which can reduce the pain of a patient and reduce the examination and sampling difficulty of a doctor.

In order to achieve the technical effects, the technical scheme of the utility model is as follows:

a robot for medical operation of sampling a new coronavirus, comprising: an elastic connecting member; the connecting plates are connected with the elastic connecting pieces and are distributed at intervals along the length direction of the elastic connecting pieces; the two ends of each telescopic assembly are respectively connected with two adjacent connecting plates, each telescopic assembly comprises a plurality of telescopic pieces arranged around the elastic connecting piece, the plurality of telescopic pieces are divided into at least two groups of telescopic groups, and each group of telescopic groups comprises two telescopic pieces arranged on two opposite sides of the elastic connecting piece; the driving assembly can drive the telescopic piece to stretch and retract; the flexible sampling assembly is arranged in a plurality of penetrating and penetrating modes in the connecting plate and the telescopic assembly, and the flexible sampling assembly is used for collecting human respiratory tract secretions.

Further, the telescoping member includes a flexible bladder and the drive assembly includes a deflation and inflation structure.

Further, the inflation and deflation structure comprises a plurality of air pipes, the air pipes extend along the length direction of the elastic connecting piece, and each air pipe is communicated with one or more flexible air bags.

Furthermore, the elastic connecting piece comprises a plurality of elastic tubes which are sequentially sleeved, and one end of each elastic tube is connected with one connecting plate.

Furthermore, the end of the elastic tube is provided with a connecting bulge, and the connecting plate is provided with a connecting groove matched with the connecting bulge.

Furthermore, flexible group is two sets ofly, a set of two of flexible group the extensible member distributes along the X axle direction, another group two of flexible group the extensible member distributes along the Y axle direction, elastic connection's length direction extends the setting along the Z axle direction.

Further, the cross section of the telescopic piece is in a fan shape, so that the outer peripheral surface of the telescopic assembly is formed into a circumferential surface; the peripheral surface of the connecting plate is a circumferential surface.

Further, flexible sampling subassembly includes flexible sampling tube and vision perception structure, flexible sampling tube with the vision perception structure all stretches out elastic connecting piece's tip, flexible sampling tube is used for gathering the elastic connecting piece tip human respiratory tract secretion, the vision perception structure is used for acquireing human tissue's image information in order to guide the drive assembly drive is a plurality of flexible subassembly removes in the chamber is said.

Further, the robot for the new coronavirus sampling medical operation further comprises a flexible protective film, and the flexible protective film is wrapped on the outer peripheral surfaces of the plurality of connecting plates and the plurality of telescopic assemblies.

A system for sampling a new coronavirus for medical procedures, comprising: the robot for medical operation of sampling new coronavirus is arranged in the negative pressure operating room; the intelligent terminal is arranged outside the negative pressure operating room, the intelligent terminal is in communication connection with the robot for the new coronavirus sampling medical operation, the intelligent terminal is configured to control the driving assembly to drive the expansion piece to expand and contract and receive the information collected by the robot for the new coronavirus sampling medical operation, and the intelligent terminal can also acquire real-time image information in the negative pressure operating room.

The utility model has the following beneficial effects: according to the robot for sampling the new coronavirus for medical operation, disclosed by the utility model, the robot can freely bend and move in the special-shaped respiratory tract of a human body and realize sampling of respiratory tract secretion of the human body, so that the inspection pain of a patient is relieved, and the inspection difficulty of a doctor is reduced.

The utility model has the following beneficial effects: due to the fact that the robot for the new coronavirus sampling medical operation is arranged, the robot for the new coronavirus sampling medical operation can be intelligently controlled through the intelligent terminal, a plurality of telescopic assemblies of the robot for the new coronavirus sampling medical operation can better adapt to narrow special-shaped channels of a human body and can freely bend and stretch in the channels, pain of a patient is relieved, and difficulty in checking and operating of a doctor is reduced.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the utility model.

Drawings

FIG. 1 is a schematic structural diagram of a robot for sampling and medical operation of a new coronavirus according to an embodiment of the present invention;

FIG. 2 is a schematic partial exploded view of a robot for sampling a new coronavirus for medical operation according to an embodiment of the present invention;

FIG. 3 is an exploded view of a connection plate and telescoping assembly according to an embodiment of the present invention;

FIG. 4 is a schematic view of a portion of an elastic connector according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of the application of the system for sampling and medical operation of new coronavirus according to the embodiment of the utility model.

Reference numerals

1. An elastic connecting member; 11. an elastic tube; 12. a connecting projection;

2. a connecting plate; 21. connecting grooves; 22. a first communication hole; 23. a second communication hole;

3. a telescoping assembly; 31. a telescoping member; 4. an air tube;

5. a flexible sampling assembly; 51. a flexible sampling tube; 52. a visual perception structure; 6. a housing;

100. a robot for medical operation for sampling new coronavirus; 110. a display mechanism; 120. a moving mechanism; 130. a lifting mechanism.

Detailed Description

In order to make the technical problems solved, the technical solutions adopted and the technical effects achieved by the present invention clearer, the technical solutions of the present invention are further described below by way of specific embodiments with reference to the accompanying drawings.

In the description of the present invention, unless expressly stated or limited otherwise, the terms "connected," "connected," and "fixed" are to be construed broadly, e.g., as meaning permanently connected, removably connected, or integral to one another; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In the present invention, unless otherwise expressly stated or limited, "above" or "below" a first feature means that the first and second features are in direct contact, or that the first and second features are not in direct contact but are in contact with each other via another feature therebetween. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

It will be understood that the terms "central," "longitudinal," "transverse," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in an orientation or positional relationship indicated in the drawings for convenience and simplicity of description only and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be considered as limiting the utility model. In the description of the present invention, "a plurality" means two or more unless otherwise specified. Furthermore, the terms "first" and "second" are used only for descriptive purposes and are not intended to have a special meaning.

The specific structure of the robot for sampling medical operation of new coronavirus according to the embodiment of the present invention is described below with reference to fig. 1 to 5.

As shown in fig. 1-5, fig. 1 discloses a new robot for sampling medical operation of coronavirus, which comprises an elastic connecting piece 1, a plurality of connecting plates 2, a plurality of telescopic assemblies 3, a driving assembly and a flexible sampling assembly 5. A plurality of connecting plates 2 all are connected with elastic connection spare 1, and along elastic connection spare 1's length direction interval distribution. The both ends of every flexible subassembly 3 are connected with two adjacent connecting plates 2 respectively, and flexible subassembly 3 includes a plurality of extensible members 31 that set up around elastic connection spare 1, and a plurality of extensible members 31 divide into at least two sets of flexible groups, and every flexible group of group is including establishing two extensible members 31 in the relative both sides that set up of elastic connection spare 1. The drive assembly can drive the telescopic member 31 to extend and retract. Flexible sampling subassembly 5 wears to establish in a plurality of connecting plates 2 and a plurality of flexible subassembly 3, and flexible sampling subassembly 5 is used for gathering human respiratory secretion.

It can be understood that, when the driving assembly drives one expansion element 31 to expand, the expansion element 31 will drive the elastic connection element 1 to expand and drive one connection plate 2 connected thereto to move in the length direction of the elastic connection element 1, meanwhile, other expansion elements 31 adjacent to the expansion element 31 and belonging to the same expansion element 3 are still at the original length, and the other expansion elements 31 are also connected to the connection plate 2, so that the expansion element 3 where the expansion element 31 is located bends, and in addition, when the driving assembly simultaneously drives all expansion elements 31 in one expansion element 3 to expand or shorten, the expansion element 3 can be extended or shortened in the length direction of the elastic connection element 1, that is, the displacement of the connection plate 2 connected to the expansion element 3 in the length direction of the elastic connection element 1 is realized. Therefore, different telescopic pieces 31 in the telescopic assemblies 3 are driven by the driving assembly to extend or shorten, the telescopic assemblies 3 can stretch out and draw back and bend, the telescopic assemblies 3 can make different posture changes under the action of the driving assembly, the telescopic assemblies 3 can have multiple freedom degree combinations of direct movement and bending, the various control of the form of the robot is effectively realized, and the robot can stretch in, withdraw from and freely bend in the cavity channels with irregular shapes and different widths in the human body and reach the sampling position in the human body. Because flexible sampling subassembly 5 has the flexibility, make it produce same bending and displacement under the drive of a plurality of flexible subassemblies 3 to finally can reach sample department, thereby make the robot can accomplish the tissue sample in the human body chamber way, for example mucosa, mucosa secretion etc. with the sample of acquireing human respiratory tract secretion, thereby be convenient for carry out new crown virus to the sample and detect, make the sample of human respiratory tract secretion show the misery that alleviates the patient produced, and greatly reduced doctor's inspection operation degree of difficulty.

According to the robot for medical operation for sampling the new coronavirus, the robot can freely bend and move in the special-shaped respiratory tract of the human body and realize sampling of internal tissues of the human body, so that the inspection pain of a patient is relieved, and the inspection difficulty of a doctor is reduced.

Illustratively, the robot for medical operation of sampling new coronavirus of the embodiment is particularly suitable for examination of narrow cavities such as nasal cavity, oral cavity, and trachea 4 and collection of mucosal secretions in the nasal cavity, the oral cavity, and the respiratory tract trachea 4, thereby facilitating the collection and testing of new coronavirus samples.

In some embodiments, the telescoping member 31 comprises a flexible balloon and the drive assembly comprises a deflation and inflation configuration.

It can be understood that the flexible airbag is simple and convenient to stretch, and the flexible airbag has extremely small change in radial dimension in the stretching process, so that the telescopic part 31 cannot interfere with the special-shaped breathing cavity in the stretching process, and the medical accident problem that the telescopic part 31 is clamped in the cavity of a human body in the stretching process is definitely prevented. At the same time, the inflation and deflation structure is also beneficial to extend in all the telescopic assemblies 3 so as to realize the telescopic driving of the telescopic member 31 which is positioned at the extending part of the human body.

In some embodiments, as shown in fig. 1, the inflation and deflation structure comprises a plurality of air tubes 4, the air tubes 4 extend along the length direction of the elastic connecting piece 1, and each air tube 4 is communicated with one or more flexible air bags.

It can be understood that, a plurality of trachea 4 can realize respectively filling and discharging function to all flexible gasbags to realized drive assembly to every extensible member 31 independent flexible control, be favorable to improving the flexible accuracy of flexible subassembly 3, thereby improve the bending precision of whole robot, thereby make the robot can remove in the human dysmorphism breathing cavity of complicacy say, reduced the robot and removed the collision phenomenon that process and human tissue appear, further alleviateed patient's inspection misery.

In some embodiments, as shown in fig. 4, the elastic connecting member 1 includes a plurality of elastic tubes 11 sequentially sleeved, and one end of each elastic tube 11 is connected to one connecting plate 2.

It can be understood that, because every connecting plate 2 is only connected with an elastic tube 11, when the connecting plate 2 is displaced along the length direction of the elastic connecting piece 1 under the action of the telescopic piece 31, the connecting plate will drive the elastic tube 11 connected with the connecting plate to axially displace relative to other elastic tubes 11, thereby only realizing the bending and the stretching of a single telescopic assembly 3, and effectively preventing the telescopic assembly 3 from interfering with other telescopic assemblies 3 in the bending and stretching processes.

For example, when the robot is located comparatively constrictive chamber space, drive assembly can drive 3 bending and displacements of the flexible subassembly that are located the most end, and then drive the next 3 bending and displacements of flexible subassembly, thereby be convenient for the robot through narrow chamber space, and simultaneously, when the robot is located comparatively expanse chamber space, drive assembly can drive 3 bending of the flexible subassembly that are close to drive assembly, thereby drive other bent subassemblies and swing in chamber space, the flexibility that has showing and improving the robot, and be favorable to flexible sampling subassembly 5 to gather the human respiratory tract secretion in the chamber. In addition, each elastic tube 11 is only connected with one connecting plate 2, so that the elastic tube 11 can be driven to move in the axial direction in the actual operation process of the robot, the whole telescopic assembly 3 can be stretched, and the operation convenience of the robot is improved.

Of course, in this embodiment, the elastic tubes 11 sleeved in sequence have a small amount of expansion and contraction in the axial direction, and in other embodiments of the present invention, the elastic connection member 1 may also be formed as an elastic structure capable of achieving both bending and segmented expansion and contraction in the axial direction, and also capable of enabling the driving assembly to achieve bending and expansion and contraction of a single expansion and contraction assembly 3, so that the actual structure of the elastic connection member 1 may be determined according to actual requirements without specific limitations.

In some embodiments, as shown in fig. 2-4, the end of the elastic tube 11 is provided with a connection protrusion 12, and the connection plate 2 is provided with a connection groove 21 matching with the connection protrusion 12.

It can be understood that the arrangement of the connecting protrusion 12 and the connecting groove 21 can better realize the stable connection between the elastic tube 11 and the connecting plate 2, so that the telescopic assembly 3 can drive the elastic tube 11 to simultaneously complete the telescopic or bending posture change through the movement of the connecting plate 2 when being telescopic and bent, thereby ensuring the reliability of the robot shape change and improving the change flexibility of the robot.

In some embodiments, as shown in fig. 2, the connection plate 2 has a first communication hole 22 and a second communication hole 23, the first communication hole 22 is engaged with the air tube 4, and the second communication hole 23 is engaged with the flexible sampling assembly 5. In addition, as shown in fig. 3, according to the specific distribution position of each connecting plate 2 in the axial direction of the elastic connecting member 1, the number of the first through holes 22 formed in the connecting plate 2 is also different, specifically, the number of the first through holes 22 is gradually reduced in the direction close to the flexible sampling assembly 5, and each telescopic assembly 3 can realize telescopic control through an independent driving assembly, so that the bending and movement accuracy of the robot can be better improved.

In some embodiments, the telescopic groups are two groups, two telescopic members 31 of one group are distributed along the X-axis direction, two telescopic members 31 of the other group are distributed along the Y-axis direction, and the length direction of the elastic connecting member 1 is extended along the Z-axis direction.

It will be appreciated that when one of the two telescopic members 31 extending in the X-axis direction is extended and the other is shortened, the telescopic group will bend towards the shortened telescopic member 31, thereby bending the telescopic assembly 3 in the X-axis direction, and similarly, by driving the extension and retraction of the two telescopic members 31 extending in the Y-axis direction, the bending of the telescopic assembly 3 in the Y-axis direction can also be achieved. In addition, through the flexible of two extensible member 31 of adjusting two flexible groups simultaneously, can realize that flexible subassembly 3 is crooked in the contained angle direction department between X axle direction and Y axle direction, can realize the universal bending motion of flexible subassembly 3 according to the flexible length of difference, if make the flexible same displacement volume of four extensible member 31 simultaneously, can realize the displacement of flexible subassembly 3 in Z axle direction. Therefore, the telescopic assembly 3 comprises the four telescopic pieces 31, so that the robot can be bent well, and the robot can adapt to the special-shaped breathing cavity of a human body, and the control difficulty and the production cost of the robot are reduced on the premise of ensuring the bending reliability of the robot. Of course, in other embodiments of the present invention, in order to further improve the bending precision of the robot, the telescopic assembly 3 may also include multiple telescopic groups, the more the telescopic groups are distributed, the more accurate the bending direction of the robot can be adjusted, and the specific number of the telescopic groups may be determined according to actual requirements without specific limitations.

In some embodiments, as shown in FIGS. 1-4, telescoping piece 31 is fan-shaped in cross-section such that the outer peripheral surface of telescoping assembly 3 is formed as a circumferential surface; the outer peripheral surface of the connecting plate 2 is a circumferential surface.

It can be understood that the outer circumferential surface of the telescopic assembly 3 and the outer circumferential surface of the connecting plate 2 are both formed into circumferential surfaces, so that the interference and collision phenomenon between the robot and the body cavity channel can be reduced, and the examination pain of a patient can be further relieved. The cross section of the telescopic member 31 is fan-shaped, so that the connection with the elastic connecting piece 1 is facilitated, the telescopic assembly 3 with a round outer peripheral surface is formed, and the assembly difficulty of the telescopic member 31 is reduced. Of course, in other embodiments of the present invention, the outer peripheral surfaces of the connecting plate 2 and the telescopic assembly 3 may be provided with an arc-shaped structure of an ellipse, which need not be limited specifically.

In some embodiments, the flexible sampling assembly 5 includes a flexible sampling tube 51 and a visual perception structure 52, the flexible sampling tube 51 and the visual perception structure 52 both extend out of the end of the elastic connection member 1, the flexible sampling tube 51 is used for collecting human respiratory secretions at the end of the elastic connection member 1, and the visual perception structure 52 is used for acquiring image information of human tissues to guide the driving assembly to drive the plurality of telescopic assemblies 3 to move in the cavity.

It can be understood that the visual perception structure 52 can facilitate obtaining image information of human tissues, so that a doctor can complete sampling operation by using the flexible sampling tube 51 according to the image information, and can obtain health conditions of the human tissues according to the image information, and in addition, the visual perception structure 52 can also achieve a visual navigation function, so that the doctor can conveniently operate and control the motion of the robot, and the interference between the robot and the human tissues can be reduced.

Illustratively, in the present embodiment, the visual perception structure 52 includes a flexible endoscope disposed near the front end of the visual perception structure 52, but of course, in other embodiments of the present invention, the visual perception structure 52 may be of other types as long as the function of acquiring image information of human tissue is achieved, and need not be limited specifically.

In some embodiments, as shown in fig. 1, the robot for sampling new coronavirus for medical operation further includes a housing 6, the housing 6 is disposed at an end of the plurality of telescopic assemblies 3 away from the flexible sampling assembly 5, and the housing 6 can cover the driving assembly, the elastic connecting member 1, and the like, so as to facilitate fixing the robot on a medical instrument to complete sampling operation.

In some embodiments, the robot for sampling and medical operation of neocoronavirus further includes a flexible protective film (not shown) which is wrapped around the outer circumferential surfaces of the plurality of connection plates 2 and the plurality of expansion assemblies 3.

It can be understood that the flexible protective film has a smooth surface, so that the friction between the telescopic assemblies 3 and the connecting plate 2 and a human body during the motion in the cavity of the human body can be obviously reduced, the discomfort of the patient can be relieved, and the displacement and bending smoothness of the telescopic assemblies 3 can be improved. In addition, the flexible protective film can also prevent internal environment media of a human body from entering the telescopic assembly 3 so as to prevent the media from interfering with the movement of the telescopic assembly 3 or damaging the telescopic assembly 3, thereby ensuring the use safety of the robot.

In some embodiments, the robot for medical operation of sampling new coronavirus further comprises a force sensing mechanism, and the force sensing mechanism is arranged on the outer peripheral surfaces of the connecting plates 2, so that the interaction force between the telescopic assemblies 3 and human tissues in the motion process can be conveniently acquired, the safety interaction function in the special-shaped breathing cavity channel can be further realized, and the robot can be prevented from causing discomfort or even injury to the patient due to the fact that the robot exerts too much force on the human tissues.

As shown in fig. 5, the present invention further discloses a system for medical operation of sampling new coronavirus, which comprises the robot 100 for medical operation of sampling new coronavirus and the intelligent terminal. The robot 100 for sampling a new coronavirus for medical operation is installed in a negative pressure operating room. The intelligent terminal is arranged outside the negative pressure operating room, the intelligent terminal is in communication connection with the robot 100 for new coronavirus sampling medical operation, the intelligent terminal is configured to control the driving assembly to drive the plurality of telescopic pieces 31 to stretch and receive information collected by the robot 100 for new coronavirus sampling medical operation, and the intelligent terminal can also acquire real-time image information in the negative pressure operating room.

According to the system for sampling medical operation of new coronavirus in the embodiment of the utility model, as the robot 100 for sampling medical operation of new coronavirus is arranged, the robot 100 for sampling medical operation of new coronavirus can be intelligently controlled through an intelligent terminal, so that a plurality of telescopic components 3 of the robot 100 for sampling medical operation of new coronavirus can better adapt to narrow and special-shaped channels of a human body and can freely bend and stretch in the channels, the pain of a patient is reduced, and the difficulty in examination and operation of a doctor is reduced. In addition, set up intelligent terminal and new coronavirus sampling medical operation with robot 100 respectively outside the negative pressure operating room, under the prerequisite of guaranteeing that the doctor reliably operates new coronavirus sampling medical operation with robot 100 and observation patient's state, can be convenient for inspect the sample operation to the patient better.

Specifically, the intelligent terminal can control the driving assembly to work according to the information fed back by the force sensing mechanism so as to control the extension and the bending of the plurality of telescopic assemblies 3: after the force sensing mechanism collects the interaction forces of the plurality of telescopic assemblies 3, the connecting plate 2 and the human tissue, the intelligent terminal judges whether the interaction forces are in a safety setting range through a preset algorithm, if the interaction forces exceed the safety setting range, the intelligent terminal automatically controls the working state of the driving assembly, the telescopic assemblies 3 are driven to retreat along the vertical direction of the contact force, the contact positions of the telescopic assemblies 3 and the human tissue move in the direction of reducing the contact force, and the robot 100 for sampling the new coronavirus for medical operation is ensured to be safely interacted with the human tissue.

In some embodiments, as shown in fig. 5, the narrow lumen medical operation system further includes a display mechanism 110, a moving mechanism 120 and an elevating mechanism 130, the elevating mechanism 130 is disposed on the moving mechanism 120, the new coronavirus sampling medical operation robot 100 is mounted on the elevating mechanism 130, and the elevating mechanism 130 can be elevated to adjust the height of the new coronavirus sampling medical operation robot 100 to adapt to the heights of different patients; the bottom of the moving mechanism 120 is provided with a roller, so that the moving is convenient; the display mechanism 110 is used for displaying the human tissue image obtained by the visual perception structure 52, so that both the doctor and the patient can observe the examination process at the same time, and the doctor and the patient can communicate effectively.

Example (b):

a system for sampling medical procedures for corona virus according to one embodiment of the utility model is described below with reference to fig. 1-5.

The system for medical operation of sampling new coronavirus in the embodiment comprises a robot for medical operation of sampling new coronavirus and an intelligent terminal. The robot for the new coronavirus sampling medical operation is arranged in a negative pressure operating room. The intelligent terminal is arranged outside the negative pressure operating room, the intelligent terminal is in communication connection with the robot for the new coronavirus sampling medical operation, the intelligent terminal is configured to control the driving assembly to drive the plurality of telescopic pieces 31 to stretch and receive information collected by the robot for the new coronavirus sampling medical operation, and the intelligent terminal can also acquire real-time image information in the negative pressure operating room.

The robot for the new coronavirus sampling medical operation comprises an elastic connecting piece 1, a plurality of connecting plates 2, a plurality of telescopic assemblies 3, a driving assembly, a flexible sampling assembly 5 and a shell 6.

The elastic connecting piece 1 comprises a plurality of elastic tubes 11 which are sequentially sleeved, and one end of each elastic tube 11 is connected with one connecting plate 2. The end of the elastic tube 11 is provided with a coupling protrusion 12.

A plurality of connecting plates 2 all are connected with elastic connection spare 1, and along elastic connection spare 1's length direction interval distribution. The connecting plate 2 is provided with a connecting groove 21 matched with the connecting bulge 12. The outer peripheral surface of the connecting plate 2 is a circumferential surface.

The both ends of every flexible subassembly 3 are connected with two adjacent connecting plates 2 respectively, and flexible subassembly 3 includes a plurality of extensible members 31 that encircle the setting of elastic connecting piece 1, and a plurality of extensible members 31 divide into two sets of flexible groups, and two extensible members 31 of a set of flexible group distribute along the X axle direction, and two extensible members 31 of another set of flexible group distribute along the Y axle direction, and elastic connecting piece 1's length direction extends the setting along the Z axle direction. The cross-section of the telescopic member 31 is fan-shaped so that the outer circumferential surface of the telescopic assembly 3 is formed as a circumferential surface.

Drive assembly can drive extensible member 31 and stretch out and draw back, and drive assembly is including filling the gassing structure, fills the gassing structure and includes a plurality of trachea 4, and a plurality of trachea 4 all extend the setting along the length direction of elastic connection spare 1, and every trachea 4 communicates with one or more flexible gasbag.

Flexible sampling subassembly 5 wears to establish in a plurality of connecting plates 2 and a plurality of flexible subassembly 3, and flexible sampling subassembly 5 is used for gathering human respiratory secretion. The flexible sampling assembly 5 comprises a flexible sampling tube 51 and a visual perception structure 52, the flexible sampling tube 51 and the visual perception structure 52 both extend out of the end part of the elastic connecting piece 1, the flexible sampling tube 51 is used for collecting human respiratory tract secretions at the end part of the elastic connecting piece 1, and the visual perception structure 52 is used for acquiring image information of human tissues so as to guide the driving assembly to drive the plurality of telescopic assemblies 3 to move in the cavity channel.

The shell 6 is arranged at one end of the telescopic assemblies 3 far away from the flexible sampling assembly 5, and the shell 6 covers the driving assembly, the elastic connecting piece 1 and other structures.

In the description herein, references to the description of "some embodiments," "other embodiments," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The above description is only a preferred embodiment of the present invention, and for those skilled in the art, the present invention should not be limited by the description of the present invention, which should be interpreted as a limitation.

Claims (10)

1. A robot for medical operation for sampling a new coronavirus, comprising:

an elastic connecting piece (1);

the connecting plates (2) are connected with the elastic connecting piece (1) and are distributed at intervals along the length direction of the elastic connecting piece (1);

the two ends of each telescopic assembly (3) are respectively connected with two adjacent connecting plates (2), each telescopic assembly (3) comprises a plurality of telescopic pieces (31) arranged around the elastic connecting piece (1), the plurality of telescopic pieces (31) are divided into at least two groups of telescopic groups, and each group of telescopic groups comprises two telescopic pieces (31) arranged on two opposite sides of the elastic connecting piece (1);

a driving assembly capable of driving the telescopic member (31) to extend and retract;

flexible sampling subassembly (5), flexible sampling subassembly (5) wear to establish a plurality ofly connecting plate (2) and a plurality of in flexible subassembly (3), flexible sampling subassembly (5) are used for gathering human respiratory tract secretion.

2. The robot for sampling medical procedures of new coronavirus according to claim 1, wherein the telescopic member (31) comprises a flexible balloon and the driving assembly comprises an inflation and deflation structure.

3. The robot for sampling medical operation of new coronavirus according to claim 2, wherein the inflation/deflation structure comprises a plurality of air tubes (4), the plurality of air tubes (4) are arranged in an extending manner along the length direction of the elastic connecting piece (1), and each air tube (4) is communicated with one or more flexible air bags.

4. The robot for sampling medical operation of new coronavirus according to claim 1, wherein the elastic connector (1) comprises a plurality of elastic tubes (11) sleeved in sequence, and one end of each elastic tube (11) is connected with one of the connecting plates (2).

5. The robot for sampling medical operation of new coronavirus according to claim 4, wherein the end of the elastic tube (11) is provided with a connecting protrusion (12), and the connecting plate (2) is provided with a connecting groove (21) matched with the connecting protrusion (12).

6. The robot for sampling medical corona virus according to any one of claims 1 to 5, wherein the telescopic groups are two groups, two telescopic members (31) of one group are distributed along X-axis direction, two telescopic members (31) of the other group are distributed along Y-axis direction, and the length direction of the elastic connecting member (1) is extended along Z-axis direction.

7. The robot for sampling medical corona virus according to any one of claims 1 to 5, wherein the cross section of the telescopic member (31) is fan-shaped so that the outer peripheral surface of the telescopic member (3) is formed as a circumferential surface; the peripheral surface of the connecting plate (2) is a circumferential surface.

8. The robot for sampling medical operation of new coronavirus according to any one of claims 1-5, wherein the flexible sampling assembly (5) comprises a flexible sampling tube (51) and a visual perception structure (52), the flexible sampling tube (51) and the visual perception structure (52) both extend out of the end of the elastic connecting piece (1), the flexible sampling tube (51) is used for collecting the human respiratory tract secretion at the end of the elastic connecting piece (1), and the visual perception structure (52) is used for acquiring the image information of human tissue to guide the driving assembly to drive the telescopic assemblies (3) to move in the lumen.

9. The robot for sampling medical treatment of neocoronaviruses according to any one of claims 1 to 5, further comprising a flexible protective film covering outer peripheral surfaces of the plurality of connection plates (2) and the plurality of expansion members (3).

10. A system for sampling a new coronavirus for medical procedures, comprising:

the robot for new coronavirus sampling medical procedures of any one of claims 1-9, which is disposed in a negative pressure operating room;

the intelligent terminal is arranged outside the negative pressure operating room, the intelligent terminal is in communication connection with the robot for the new coronavirus sampling medical operation, the intelligent terminal is configured to control the driving assembly to drive the expansion piece (31) to expand and contract and receive information collected by the robot for the new coronavirus sampling medical operation, and the intelligent terminal can also acquire real-time image information in the negative pressure operating room.

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