CN210843480U9 - Robot external vision mirror with 3D function - Google Patents
Robot external vision mirror with 3D function Download PDFInfo
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- CN210843480U9 CN210843480U9 CN201920215002.0U CN201920215002U CN210843480U9 CN 210843480 U9 CN210843480 U9 CN 210843480U9 CN 201920215002 U CN201920215002 U CN 201920215002U CN 210843480 U9 CN210843480 U9 CN 210843480U9
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- 230000036285 pathological change Effects 0.000 abstract description 3
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Abstract
The utility model discloses a robot external view mirror with a 3D function, which is characterized in that: the device comprises a machine main body, a camera system arranged on the machine main body and a display device for displaying images acquired by the camera system; the imaging system comprises a 3D imaging system, wherein the 3D imaging system comprises 3D operation field imaging equipment and a 3D host; the display device includes a 3D display having a 3D image display mode; and the images acquired by the 3D surgical field camera equipment are processed by the 3D host and then are transmitted to the 3D display for display. The robot external vision lens can conveniently acquire three-dimensional images of the operation field, the focus and the cells in the operation process, provides three-dimensional feeling for doctors in operation diagnosis, helps the doctors to clearly observe pathological changes at the operation place, accurately judges the nature of the focus and further helps the doctors to make accurate treatment operation schemes on site in real time.
Description
Technical Field
The utility model belongs to the technical field of medical instruments, and particularly relates to a robot external view mirror with a 3D function.
Background
At present, in various clinical open operations, the symptoms of a patient are usually required to be diagnosed by virtue of the experience of doctors or by using various invasive medical diagnosis modes, on one hand, the invasive diagnosis method often brings pain and discomfort to the patient in the diagnosis process; on the other hand, the conventional diagnosis method has the defects of low detection precision, low diagnosis efficiency and the like.
Moreover, most of the current diagnostic devices use two-dimensional imaging, compared with three-dimensional imaging, because the vision is single, the observed tissue lacks a stereoscopic impression, so that the stereoscopic overall view of the whole operation area cannot be reflected stereoscopically, and the judgment of the nature of the focus and the development of subsequent operation treatment by a doctor are limited to a certain extent.
Moreover, most of the current diagnostic devices can only be used for pre-operation/post-operation examination and diagnosis, but there is no matched diagnostic device in the operation process. The operation visual field is not accurate and visual enough, the operation is not convenient, and when the pathological change condition or suspected disease appears in the operation process, the operation process is often required to be suspended to wait for the analysis result again, so that the nature of the focus cannot be rapidly and accurately judged. Not only increases the pain of the patient, but also increases the risk of the operation.
Therefore, in order to improve the diagnosis efficiency and the diagnosis precision and reduce the pain of the patient, it is necessary for the doctor to easily obtain visual and three-dimensional high-definition scanning images of the tissues at the operation field or the focus, so as to help the doctor accurately judge the nature of the focus and make an accurate treatment surgery scheme on site in real time.
Disclosure of Invention
Aiming at the defects of the prior art, the utility model provides the robot endoscope with the 3D function, which can conveniently acquire three-dimensional images of the operation field, the focus and the cells in the operation process, provides stereo feeling for doctors in operation diagnosis, helps the doctors to clearly observe the pathological changes of the operation place, accurately judges the nature of the focus and further helps the doctors to make an accurate treatment operation scheme on site in real time.
In order to solve the technical problems, the utility model adopts the following technical scheme:
the robot external view mirror with the 3D function comprises a machine main body, a camera system arranged on the machine main body and a display device for displaying images acquired by the camera system;
the imaging system comprises a 3D imaging system, the 3D imaging system comprises 3D operation field imaging equipment and a 3D host, and the display device comprises a 3D display with a 3D image display mode; and the images acquired by the 3D surgical field camera equipment are processed by the 3D host and then are transmitted to the 3D display for display.
Further, the 3D surgical field photographing device comprises two mutually independent high-definition optical lenses, the two high-definition optical lenses can respectively simulate CCD imaging systems of left and right eyes of a person, and two sets of images of the same surgical field are collected at the same time; and after the three-dimensional image synthesis processing is carried out on the two sets of images acquired by the two high-definition optical lenses through the 3D host, outputting the two sets of images to the 3D display.
Further, the two high-definition optical lenses are respectively arranged on two mutually independent image pickup devices or integrally arranged on the same image pickup device.
Further, the resolution ratio of the high-definition optical lens is at least 1280×720, the pixels are at least 200 ten thousand, and the optical zoom of at least 10 times is satisfied.
Further, the 3D host is connected with the 3D surgical field camera device through a data line connection, and the output mode of the 3D host comprises
A 3D eyeglass mode and a naked eye 3D mode; wherein,
3D glasses mode: an observer needs to be provided with 3D glasses to observe the three-dimensional image on the 3D display;
naked eye 3D mode: the observer can observe the three-dimensional image on the 3D display without wearing 3D glasses.
Further, the 3D glasses include active glasses or polarizers, and the 3D glasses modes are divided into an active 3D glasses mode and a passive 3D glasses mode.
Further, the camera system further comprises a scene camera system, the scene camera system comprises a scene camera and a scene image processing host, the display device comprises a scene display for displaying images of the scene camera system, and the images acquired by the scene camera are transmitted to the scene display after passing through the scene image processing host;
the scene camera adopts a high-definition CCD optical system for imaging, and can carry out 360-degree panoramic shooting;
the scene camera comprises a single optical lens or a scene camera array formed by a plurality of optical lenses.
Further, the mechanical main body comprises a carrier main body and a mechanical arm which is arranged on the carrier main body and has a plurality of rotational degrees of freedom, and the 3D surgical field imaging equipment is arranged on the mechanical arm;
the 3D host can be simultaneously connected with a plurality of 3D displays, and the 3D displays comprise a first 3D display arranged on the carrier main body and a plurality of second 3D displays for remote display;
the scene image processing host can be simultaneously connected with a plurality of scene displays, and the scene displays comprise a first scene display arranged on the carrier main body and a plurality of second scene displays for remote display.
Further, the carrier main part is mobilizable workstation car, the workstation car includes box, universal castor, locates little gas cylinder support and power in the box, the box is equipped with back chamber door and push-pull handle, still be equipped with drawer and 3 layer at least baffles in the box, the baffle between high position can be adjusted.
Further, the carrier main body is a hanging table which is horizontally hung on the ceiling of the operating room, and the hanging table comprises a storage rack, a vertical rod, a rotating arm and a hanging part;
the shelf is provided with at least 3 layers of partition boards, the height position between the partition boards can be adjusted, and the upper end of the shelf passes through one end of the vertical rod and one end of the rotating arm;
the other end of the rotating arm is hinged with a rotating part and can horizontally rotate relative to the hoisting part.
Compared with the prior art, the utility model has the beneficial effects that:
the robot external vision lens disclosed by the utility model can conveniently operate the 3D surgical field camera equipment to scan tissues at a surgical site by the aid of the mechanical main body, so that two high-definition images under the same surgical field are obtained; and then, two high-definition images transmitted by the camera equipment through the 3D host are subjected to three-dimensional image synthesis processing, and then are transmitted to a 3D display for display. The 3D imaging system clearly presents the high-cleaning tracing image of the three-dimensional depth structure of the surgical field or the focus in front of the eyes of the doctor, and the doctor accurately judges the nature of the focus in the surgical process, so that an accurate surgical treatment scheme can be quickly made in real time. Not only reduces the pain of patients, but also greatly reduces the operation risk.
According to the robot external view mirror, the scene camera device is arranged, 360-degree panoramic shooting can be carried out on the surgical environment according to the requirement, and the surgical scene is displayed on the display by the display, so that the command and the allocation of an operator are facilitated; by arranging a plurality of 3D displays and scene displays, the scene shot by the scene shooting device can be transmitted or the operation image can be sent to the outside of an operating room, so that remote real-time operation guidance and teaching can be performed, and a direction is opened for realizing remote operation. In addition, the scene camera device can be used for shooting the manipulations, actions and the like of doctors in the operation process, so that subsequent academic communication and teaching are facilitated.
Drawings
The technology of the present utility model will be described in further detail below with reference to the attached drawings and detailed description:
fig. 1 is a schematic view of the structure of an external view mirror of a robot according to embodiment 1 of the present utility model;
fig. 2 is a schematic view showing a partial structure of an external view mirror of a robot according to embodiment 2 of the present utility model;
FIG. 3 is a schematic view of a robot arm according to the present utility model;
FIG. 4 is a top view of a robotic endoscope according to embodiment 1 of the present utility model;
fig. 5 is a schematic view of the structure of the external view mirror of the robot according to embodiment 3 of the present utility model.
Reference numerals
1. A carrier body; 11. a work trolley; 12. a hanging platform; 121. a commodity shelf; 122. a vertical rod; 123. a rotating arm; 124. a hoisting part; 2. a robotic arm; 21. a fixing seat; 22. a mechanical arm; 23. A developing manipulator; 24. a lens holder; 26. Developing a split arm; 3. a display device; 31. a first 3D display; 32. a first scene display; 4. a scene camera system; 41. a scene camera; 42. a scene host; 5. a 3D imaging system; 51. 3D operation field camera equipment; 511. high definition optical lens; 52. a 3D host; 6. 3D glasses; 61. active glasses; 62. a polarizer;
Detailed Description
The preferred embodiments of the present utility model will be described below with reference to the accompanying drawings, it being understood that the preferred embodiments described herein are for illustration and explanation of the present utility model only, and are not intended to limit the present utility model.
Example 1
The utility model discloses a robot external view mirror with a 3D function, which comprises a machine body, an image pickup system arranged on the machine body and a display device 3 for displaying images acquired by the image pickup system, as shown in figures 1-5.
The camera system comprises a 3D imaging system 5 and a scene camera system 4.
The 3D imaging system 5 of (2) includes a 3D surgical field imaging apparatus 51, a 3D host 52.
The display device 3 includes a 3D display having a 3D image display mode; the image collected by the 3D field imaging device 51 is processed by the 3D host 52 and then transmitted to the 3D display for display.
Specifically, the 3D host is connected to the 3D surgical field imaging apparatus 51 through a data line (not shown in the figure) connection. The 3D host 52 is connected to a control device (not shown), where the control device can control the 3D host 52 to perform mode control and on-off operation, and the mode control of the control device includes a scan mode and a normal mode; the manipulation device may be an operation panel, an operation keyboard or a hand-held operation device.
The output modes of the 3D host 52 include a 3D glasses mode, a naked eye 3D mode.
As shown in fig. 1-2, the 3D glasses 6 include active glasses 61 and polarizers 62. The 3D glasses mode may be classified into an active 3D glasses mode and a passive 3D glasses mode according to the difference of the 3D glasses 6.
Wherein, active 3D glasses mode: the viewer is equipped with active glasses 61 to view the image of the 3D display, which will display the image at twice the normal frequency. While the 3D display is displaying an image, the active glasses 61 will cover the left or right eye: such as when the screen presents a left eye image, conceals the right eye and vice versa.
Passive 3D glasses 6 mode: the observer is equipped with a polarizer 62 to observe, and at this time, the 3D display simultaneously displays two images with different polarized light, so that the left eye can only see the left eye image and the right eye can only see the right eye image according to the different polarized light of the left and right lens filters of the polarizer 62.
Naked eye 3D mode: the observer can observe the three-dimensional image on the 3D display without wearing the 3D glasses 6.
As shown in fig. 1-2, the 3D surgical field imaging device 51 includes two mutually independent high-definition optical lenses 511, where the two high-definition optical lenses 511 can respectively correspond to CCD imaging systems simulating left and right eyes of a person, and simultaneously acquire two sets of images of the same surgical field; the two sets of images acquired by the two high-definition optical lenses 511 are subjected to three-dimensional image synthesis processing by the 3D host 52 and then output to the 3D display.
The resolution of the high-definition optical lens 511 is at least 1280×720, the pixels are at least 200 ten thousand, and at least 10 times of optical zooming is satisfied.
In this embodiment, as shown in fig. 1, two high-definition optical lenses 511 may be provided on two mutually independent image pickup apparatuses, respectively.
The 3D host 52 may be electrically connected to a plurality of 3D displays at the same time, and the 3D displays include a first 3D display 31 disposed on the carrier body and a plurality of second 3D displays (not shown) for remote display.
The three-dimensional image processed by the 3D host 52 may be transmitted to the second 3D display for display by a wired or wireless method.
The robot external vision lens disclosed by the utility model can conveniently operate the 3D surgical field camera equipment to scan tissues at a surgical site by the aid of the mechanical main body, so that two high-definition images under the same surgical field are obtained; and then the two high-definition images transmitted by the image capturing device through the 3D host 52 are subjected to three-dimensional image synthesis processing, and then transmitted to a 3D display for display. The 3D imaging system 5 clearly presents the high-cleaning tracing image of the three-dimensional depth structure of the surgical field or the focus in front of the eyes of the doctor, and the doctor accurately judges the nature of the focus in the surgical process, so that an accurate treatment surgical scheme can be rapidly made in real time. Not only reduces the pain of patients, but also greatly reduces the operation risk.
In the above embodiment, as shown in fig. 1 to 5, the scene camera system 4 includes a scene camera 41 and a scene image processing host 42, the display device 3 includes a scene display 32 for displaying images of the scene camera system 4, and images collected by the scene camera 41 are transmitted to the scene display 32 after passing through the scene image processing host 42.
Specifically, the image processing host processes 1 or more images, and has functions of image integration, image switching, image segmentation, and image output.
The scene camera 41 uses a high-definition CCD optical system for imaging, and a multi-lens panoramic camera system for 360 ° panoramic imaging.
The scene camera 41 includes a single optical lens or a scene camera array composed of a plurality of optical lenses.
The scene image processing host 42 may be connected to a plurality of scene displays simultaneously, including a first scene display 32 provided on the carrier body and a plurality of second scene displays (not shown) for remote display.
The images processed by the scene image processing host 42 may be transmitted to a second scene display for display by wired or wireless means.
According to the embodiment, the plurality of 3D displays and the scene display are arranged, so that a scene or an operation image shot by the scene shooting device can be transmitted to an operating room for remote real-time operation guidance and teaching, and a direction is opened for realizing remote operation.
In the above embodiment, as shown in fig. 1 to 5, the machine body includes a carrier body, and a robot arm disposed on the carrier body and having a plurality of rotational degrees of freedom.
The robot arm 2 comprises a fixed seat 21, a robot arm 21 and a developing robot arm 23; the scene camera 41 is disposed at a connection position between the machine fixing base 21 and the mechanical arm 21.
The rear end of the imaging manipulator 23 is fixedly arranged on the fixing seat 21, and the front end is provided with the display device 3.
The rear end of the mechanical arm 21 is rotationally connected with the fixed seat 21, the front end is provided with a lens bracket 24, and the ground clearance of the lens bracket 24 is 850-2400 mm. The 3D surgical field imaging apparatus is disposed on the lens holder 24.
Specifically, the mechanical arm 21 is formed by sequentially hinging a plurality of connecting rods 221, the mechanical arm 21 can simultaneously realize rotation in the horizontal direction and the vertical direction, and the maximum rotation angle between the connecting rods 221 in the horizontal direction is not less than 300 degrees; the arm extension length of the mechanical arm 21 is not more than 1800mm. The mechanical arm 21 at least comprises 3 joints and 5 degrees of freedom, wherein each joint of the mechanical arm 21 rotates at least 300 degrees in the horizontal direction, the arm extension length of the mechanical arm 21 does not exceed 1800mm, and the up-and-down swinging height of the mechanical arm 21 is between 850 and 2400mm (taking the horizontal ground of an operating room as a reference surface).
As shown in fig. 1-2, the carrier body 1 is a movable workbench 11, the workbench 11 comprises a box body, universal casters, a small gas cylinder bracket and a power supply, the small gas cylinder bracket and the power supply are arranged in the box body, a rear box door and a push-pull handle are arranged in the box body, a drawer and at least 3 layers of partition plates are further arranged in the box body, and the height position between the partition plates can be adjusted. In this embodiment, the fixing base 21 of the robot arm is fixed on the workbench 11.
Example 2:
the present embodiment differs from embodiment 1 in the structure as follows:
as shown in fig. 2, two high-definition optical lenses 511 may be integrally provided on the same image pickup apparatus.
Example 3
The present embodiment differs from embodiment 1 or embodiment 2 in the following structure:
as shown in fig. 5, the carrier body 1 is a hanging table 12 which is horizontally hung on the ceiling of an operating room, and the hanging table 12 includes a shelf 121, a vertical rod 122, a rotating arm 123, and a hanging part 124.
The shelf 121 is provided with at least 3 layers of partition boards, the height position between the partition boards can be adjusted, and the upper end of the shelf 121 is connected with one end of the rotating arm 123 through the vertical rod 122.
The other end of the rotating arm 123 is hinged with a rotating part and can horizontally rotate relative to the lifting part 124.
Wherein the fixed base 21 of the robot arm is translatably suspended on the ceiling in the same or similar manner as the suspending part 124. The developing manipulator 23 is fixed on the fixed seat 21 through the developing sub-arm 26, and the developing sub-arm 26 has 5 degrees of freedom but is not limited to 5 degrees of freedom, so that the display is driven to display in a proper angle direction.
Other contents of the robot endoscope with 3D function described in the present utility model refer to the prior art, and are not described herein.
The present utility model is not limited to the preferred embodiments, and any modifications, equivalent variations and modifications made to the above embodiments according to the technical principles of the present utility model are within the scope of the technical proposal of the present utility model.
Claims (10)
1. The utility model provides a robot endoscope with 3D function which characterized in that: the device comprises a machine main body, a camera system arranged on the machine main body and a display device for displaying images acquired by the camera system;
the imaging system comprises a 3D imaging system, wherein the 3D imaging system comprises 3D operation field imaging equipment and a 3D host;
the display device includes a 3D display having a 3D image display mode; and the images acquired by the 3D surgical field camera equipment are processed by the 3D host and then are transmitted to the 3D display for display.
2. The 3D capable robotic endoscope according to claim 1, wherein: the 3D surgical field shooting equipment comprises two mutually independent high-definition optical lenses, the two high-definition optical lenses can respectively correspond to CCD imaging systems simulating left and right eyes of a person, and two sets of images of the same surgical field are acquired at the same time; and after the three-dimensional image synthesis processing is carried out on the two sets of images acquired by the two high-definition optical lenses through the 3D host, outputting the two sets of images to the 3D display.
3. The 3D capable robotic endoscope according to claim 2, wherein: the two high-definition optical lenses are respectively arranged on two mutually independent image pickup devices or are integrally arranged on the same image pickup device.
4. The 3D capable robotic endoscope according to claim 2, wherein:
the resolution ratio of the high-definition optical lens is at least 1280 multiplied by 720, the pixels are at least 200 ten thousand, and the optical zoom of at least 10 times is satisfied.
5. The 3D capable robotic endoscope according to claim 1, wherein: the 3D host is connected with the 3D surgical field camera equipment through a data line, and the output mode of the 3D host comprises a 3D glasses mode and a naked eye 3D mode; wherein,
3D glasses mode: an observer needs to be provided with 3D glasses to observe the three-dimensional image on the 3D display;
naked eye 3D mode: the observer can observe the three-dimensional image on the 3D display without wearing 3D glasses.
6. The 3D capable robotic endoscope according to claim 5, wherein: the 3D glasses include active glasses or polarizers, and the 3D glasses modes are divided into an active 3D glasses mode and a passive 3D glasses mode.
7. The 3D capable robotic endoscope according to claim 1, wherein:
the camera system also comprises a scene camera system, the scene camera system comprises a scene camera and a scene image processing host, the display device comprises a scene display for displaying images of the scene camera system, and the images acquired by the scene camera are transmitted to the scene display after passing through the scene image processing host;
the scene camera adopts a high-definition CCD optical system for imaging, and can carry out 360-degree panoramic shooting;
the scene camera comprises a single optical lens or a scene camera array formed by a plurality of optical lenses.
8. The 3D capable robotic endoscope according to claim 7, wherein: the mechanical main body comprises a carrier main body and a mechanical arm which is arranged on the carrier main body and has a plurality of rotational degrees of freedom, and the 3D surgical field imaging equipment is arranged on the mechanical arm;
the 3D host can be simultaneously connected with a plurality of 3D displays, and the 3D displays comprise a first 3D display arranged on the carrier main body and a plurality of second 3D displays for remote display;
the scene image processing host can be simultaneously connected with a plurality of scene displays, and the scene displays comprise a first scene display arranged on the carrier main body and a plurality of second scene displays for remote display.
9. The 3D capable robotic endoscope according to claim 8, wherein: the carrier main part is mobilizable workstation car, the workstation car includes box, universal castor, locates little gas cylinder support and power in the box, the box is equipped with back chamber door and push-pull handle, still be equipped with drawer and 3 layer at least baffles in the box, the high position between the baffle can be adjusted.
10. The 3D capable robotic endoscope according to claim 8, wherein: the carrier main body is a hanging table which is horizontally hung on the ceiling of the operating room, and the hanging table comprises a storage rack, a vertical rod, a rotating arm and a hanging part;
the shelf is provided with at least 3 layers of partition boards, the height position between the partition boards can be adjusted, and the upper end of the shelf passes through one end of the vertical rod and one end of the rotating arm;
the other end of the rotating arm is hinged with a rotating part and can horizontally rotate relative to the hoisting part.
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Correction item: Claims|Description Correct: Claims and specification submitted on November 27, 2023 False: Claims and specification submitted on March 6, 2020 Number: 26-02 Page: ?? Volume: 36 |