CN210931290U - Dual-system endoscope controller structure - Google Patents
Dual-system endoscope controller structure Download PDFInfo
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- CN210931290U CN210931290U CN201921298094.XU CN201921298094U CN210931290U CN 210931290 U CN210931290 U CN 210931290U CN 201921298094 U CN201921298094 U CN 201921298094U CN 210931290 U CN210931290 U CN 210931290U
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- 230000009977 dual effect Effects 0.000 claims abstract description 7
- 230000017525 heat dissipation Effects 0.000 description 4
- 238000005286 illumination Methods 0.000 description 3
- 230000000694 effects Effects 0.000 description 2
- 238000009434 installation Methods 0.000 description 2
- 238000000034 method Methods 0.000 description 2
- 238000005516 engineering process Methods 0.000 description 1
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Abstract
The utility model relates to an endoscope control structure. The utility model provides a dual system endoscope controller structure, includes the quick-witted case, and the machine incasement is installed the image and is handled the board, and the image is handled the board and is handled the board including last image and lower image that arrange from top to bottom, goes up the image and handles board and all connect on the power with lower image, installs the light source in one side of the image of the incasement board, and the light source includes upper light source and lower light source that arrange from top to bottom, and the fan of the tip of upper light source and lower light source is connected on the wind channel cover. The utility model provides a double-system endoscope controller structure which has small occupied space, convenient use, simple operation and compact structure and integrates the control systems of a soft lens and a hard lens together; the technical problems that when a soft lens and a hard lens are needed to be used simultaneously, an operation control system occupies a large space, is large in structure, complex to operate and inconvenient to control and adjust in the prior art are solved.
Description
Technical Field
The utility model relates to an endoscope control structure especially relates to an endoscope controller structure of dual system.
Background
With the development of science and technology, instruments in modern surgical operations are more and more, and the surgical instruments can well help doctors to complete the operations, so that the convenience and the safety are improved. Therefore, in operation, an endoscope is often used and then an instrument is matched to perform the operation. Endoscopes are widely used in current operations, and often used together with a display device and instruments. The existing endoscope is generally divided into a soft endoscope control system and a hard endoscope control system in the using process, if the existing endoscope is used at the same time, two sets of control system subsections are needed for control, the space for control is large, the operation is complex, the number of devices is large, and the installation is difficult.
Disclosure of Invention
The utility model provides a double-system endoscope controller structure which has small occupied space, convenient use, simple operation and compact structure and integrates the control systems of a soft lens and a hard lens together; the technical problems that when a soft lens and a hard lens are needed to be used simultaneously, an operation control system occupies a large space, is large in structure, complex to operate and inconvenient to control and adjust in the prior art are solved.
The utility model also provides a dual-system endoscope controller structure which has good heat dissipation effect and ensures that the light source, the power supply and the like work at normal temperature; the technical problems of complicated system and poor heat dissipation effect in the prior art are solved.
The above technical problem of the present invention is solved by the following technical solutions: the utility model provides a dual system endoscope controller structure, includes the quick-witted case, quick-witted incasement install the image processing board, the image processing board including last image processing board and the lower image processing board of arranging from top to bottom, go up the image processing board and all connect on the power with lower image processing board, install the light source in one side of quick-witted incasement image processing board, the light source including last light source and the lower light source of arranging from top to bottom, the fan of the tip of going up light source and lower light source is connected on the wind channel cover, installs the last storage interface and the lower storage interface of arranging from top to bottom on the casing of quick-witted case, install the mirror body interface on the casing simultaneously. The image processing board, the light source and the storage interface which are arranged up and down respectively correspond to the soft lens image processing board, the hard lens image processing board, the soft lens light source and the hard lens light source, and the soft lens storage interface and the hard lens storage interface. Whether the soft lens portion is on top or the hard lens portion is on top can be adjusted according to the use requirements. The control system of the soft lens and the control system of the hard lens are integrated in the case shell to be arranged up and down, and the two image processing boards share one power supply, so that the space is saved, different use requirements are met, the weight is reduced, and the multifunction of one machine is realized. The hard lens light source and the soft lens light source can emit high-brightness light rays with different parameters, and the high-brightness light rays are output to the soft lens and the hard lens through the soft lens light interface and the hard lens light interface respectively to provide illumination for the soft lens and the hard lens. The soft lens and the hard lens can emit light rays with different parameters at the same time so as to adapt to the illumination requirements of different endoscopes. The image of the soft lens is transmitted to the image processing board of the soft lens through the soft lens interface to be processed, and then is displayed on the external display through the output port of the soft lens, and the image is stored in the mobile storage medium accessed from the storage interface. The image of the hard mirror is transmitted to the hard mirror image processing board through the hard mirror interface to be displayed on the external display through the hard mirror output port after being processed, and the image is stored in the mobile storage medium accessed from the storage interface.
Preferably, one end of the air channel cover is connected with the fan of the light source, the other end of the air channel cover is provided with the output fan, and the machine box is provided with an air outlet hole which is positioned on an output wind channel of the output fan. The output fan blows outwards to form a negative pressure case, and heat in the case is sucked outwards through the air outlet hole to dissipate heat.
Preferably, the image processing board and the power supply are positioned on the same straight line, the light source and the air duct cover are positioned on the same straight line, the rear side of the shell is provided with an air inlet hole and an air outlet hole, the air inlet hole is positioned on one side of the image processing board, and the air outlet hole is positioned on one side of the air duct cover. The output fan blows outwards to form a negative pressure case, cold air is pressed in by atmospheric pressure, air is fed from the inside and the outside separated by the air channel cover on the shell, and heat generated by the power supply, the soft mirror image processing board, the hard mirror image processing board, the soft mirror light source and the hard mirror light source is absorbed from the hard mirror light source fan (the soft mirror light source fan) to form a U-shaped air channel for heat dissipation.
Preferably, the front side surface of the casing of the case is provided with an upper control board and a lower control board, the upper control board is provided with an upper lens button, and the lower control board is provided with a lower lens button. Different image processing boards, light sources and the like are controlled by buttons and control boards on the panel, so that the operation is convenient.
Preferably, the air duct cover is a rectangular parallelepiped, the upper end of the air duct cover abuts against the upper end face of the chassis, the lower end of the air duct cover abuts against the lower end face of the chassis, the right side face of the air duct cover is provided with the output fan, the output fan is mounted on the rear shell of the chassis, and the front side face of the air duct cover is connected with the light source.
Therefore, the utility model discloses a dual system endoscope controller structure possesses following advantage:
(1) the system has a soft lens and a hard lens double system, can be operated and controlled simultaneously, shares a trolley and adopts a cantilever type double-display structure, and the occupied operation space is reduced by one time. The existing single system mode needs to be matched with two sets of independent operation systems if a soft lens and a hard lens are used simultaneously, and has the disadvantages of large volume, more equipment, difficult installation and complex operation. The controller is integrated, so that the controller is small in size, compact in structure, simpler to mount, more convenient to use and more space-saving.
(2) The soft and hard mirror light source can emit light rays with different parameters at the same time. The current single system method only has one kind of parameter light source. The combined light source of the controller can adapt to the illumination requirements of different endoscopes.
(4) The high-efficiency power supply and the air duct design can lead the structure to be compact and the volume to be small. In the existing single-system mode, if the soft lens and the hard lens are used simultaneously, two sets of equipment are needed, and the controller only has one power supply and one air duct, so that the space is greatly saved, and the weight is reduced.
Drawings
Fig. 1 is a perspective view of a dual-system endoscope controller structure according to the present invention.
Fig. 2 is an internal perspective view of the housing of fig. 1 after opening.
Fig. 3 is a top view of fig. 1.
Detailed Description
The technical solution of the present invention is further specifically described below by way of examples and with reference to the accompanying drawings.
Example (b):
as shown in fig. 1, 2 and 3, a dual-system endoscope controller structure comprises a case 1, wherein a soft lens storage interface 2 and a hard lens storage interface 3 which are arranged up and down are arranged on the front end surface of the case. Below the storage interface a power switch 6 is arranged. A soft mirror button 4 and a hard mirror button 5 are arranged on one side of the storage interface, and the soft mirror button 4 and the hard mirror button 5 are connected with a software control board 24 and a hard mirror control board 25 on the casing of the cabinet. The front end face of the case shell is also provided with a soft lens interface 7 and a hard lens interface 8 for externally connecting a soft lens and a hard lens, the other ends of the soft lens interface 7 and the hard lens interface 8 are connected to a soft lens image processing board 11 and a hard lens image processing board 12 in the case, the soft lens image processing board 11 and the hard lens image processing board 12 are both connected to a power supply 13, and the power supply 13 is connected with a power supply switch 6 of the case shell. The soft mirror image processing board 11 and the hard mirror image processing board 12 in the case 1 are arranged up and down, and the soft mirror image processing board 11 is located above the hard mirror image processing board 12. The front end surface of the chassis shell is also provided with a hard lens light source interface 10 and a soft lens light source interface 9, the hard lens light source interface 10 is connected with a hard lens light source 17, the soft lens light source interface 9 is connected with a soft lens light source 16, the soft lens light source 16 is positioned above the hard lens light source 17, and the soft lens light source 16 and the hard lens light source 17 are arranged in the chassis shell. The soft mirror fan 22 and the hard mirror fan 23 are arranged behind the soft mirror light source 16 and the hard mirror light source 17, the air duct cover 15 is cuboid, and the height of the air duct cover 15 is equal to the height of the case. An output fan 21 is mounted behind the duct cover 15. An air outlet is arranged on the case 1 and is positioned on an output wind power channel of the output fan 21. The image processing board and the power supply are positioned on the same straight line, the light source and the air duct cover are positioned on the same straight line, the rear side of the shell is provided with an air inlet hole 14 and an air outlet hole, the air inlet hole is positioned on one side of the image processing board, the air outlet hole is positioned on one side of the air duct cover, and the output fan 21 blows outwards to form a negative air pressure case to form a U-shaped three-dimensional heat dissipation air duct. The rear side of the machine case shell is provided with a soft lens output port 19 and a hard lens output port 20, and a power supply input port 18. The image of the soft lens is transmitted to the image processing board of the soft lens through the soft lens interface to be processed, and then is displayed on the external display through the output port of the soft lens, and the image is stored in the mobile storage medium accessed on the storage interface of the soft lens. The image of the hard mirror is transmitted to the hard mirror image processing board through the hard mirror interface to be displayed on the external display through the hard mirror output port after being processed, and the image is stored in the mobile storage medium accessed from the hard mirror storage interface.
Claims (5)
1. A dual-system endoscope controller structure comprises a case, and is characterized in that: the quick-witted incasement install the image processing board, the image processing board including last image processing board and the lower image processing board of arranging from top to bottom, go up the image processing board and all connect on the power with lower image processing board, install the light source in one side of the image processing board of quick-witted incasement, the light source including last light source and the lower light source of arranging from top to bottom, the fan of the tip of going up light source and lower light source is connected on the wind channel cover, install last storage interface and the lower storage interface of arranging from top to bottom on the casing of quick-witted case, install the mirror body interface on the casing simultaneously.
2. The dual-system endoscope controller structure according to claim 1, characterized in that: one end of the air channel cover is connected with the fan of the light source, the other end of the air channel cover is provided with an output fan, and an air outlet hole is arranged on the case and is positioned on an output wind power channel of the output fan.
3. A dual system endoscope controller structure according to claim 1 or 2, characterized in that: the image processing board and the power supply are positioned on the same straight line, the light source and the air duct cover are positioned on the same straight line, the rear side of the shell is provided with an air inlet hole and an air outlet hole, the air inlet hole is positioned on one side of the image processing board, and the air outlet hole is positioned on one side of the air duct cover.
4. A dual system endoscope controller structure according to claim 1 or 2, characterized in that: the front side surface of the shell of the case is provided with an upper control panel and a lower control panel, the upper control panel is provided with an upper lens button, and the lower control panel is provided with a lower lens button.
5. A dual system endoscope controller structure according to claim 1 or 2, characterized in that: the air duct cover is a cuboid, the upper end of the air duct cover abuts against the upper end face of the case, the lower end of the air duct cover abuts against the lower end face of the case, an output fan is arranged on the right side face of the air duct cover and mounted on the rear shell of the case, and the front side face of the air duct cover is connected with the light source.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201921298094.XU CN210931290U (en) | 2019-08-12 | 2019-08-12 | Dual-system endoscope controller structure |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201921298094.XU CN210931290U (en) | 2019-08-12 | 2019-08-12 | Dual-system endoscope controller structure |
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Publication Number | Publication Date |
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CN210931290U true CN210931290U (en) | 2020-07-07 |
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CN201921298094.XU Active CN210931290U (en) | 2019-08-12 | 2019-08-12 | Dual-system endoscope controller structure |
Country Status (1)
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CN (1) | CN210931290U (en) |
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2019
- 2019-08-12 CN CN201921298094.XU patent/CN210931290U/en active Active
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