CN212326358U - Depth of field debugging device for image transmission assembly of electronic endoscope - Google Patents

Abstract

The utility model discloses a depth of field debugging device for an electronic endoscope image transmission assembly, wherein the depth of field debugging device for the electronic endoscope image transmission assembly comprises a large bottom plate, one side of the upper side of the large bottom plate is provided with a target moving mechanism, and the target moving mechanism is provided with a resolution target mechanism which can move along the Z-axis direction; the other side of the upper edge of the large bottom plate is provided with a moving platform, the moving platform is provided with a depth-of-field debugging mechanism which can move along the X-axis direction and the Y-axis direction, and the depth-of-field debugging mechanism is used for installing an objective lens module and a COMS image photosensitive chip which are positioned below the resolution test plate; the large bottom plate is further provided with a debugging control system, the debugging control system comprises an image processor electrically connected with the COMS image photosensitive chip, and the debugging control system is respectively electrically connected with the target moving mechanism and the depth-of-field debugging mechanism and is used for adjusting the distance between the objective lens module and the COMS image photosensitive chip in the Z-axis direction.

Description

Depth of field debugging device for image transmission assembly of electronic endoscope

Technical Field

The utility model relates to an electron endoscope debugging equipment field especially relates to an electron endoscope biography image subassembly depth of field debugging device.

Background

The micro high-resolution camera is arranged in the head end part of the electronic endoscope body, so that when a doctor uses the electronic endoscope to inspect a patient, whether the stomach tissue of the patient is diseased or not can be effectively observed through the micro high-resolution camera arranged in the head end part of the electronic endoscope, and the micro high-resolution camera is used for assisting electronic gastroscopy, electronic gastroscopy operation treatment and early cancer screening. Meanwhile, doctors can also check the condition of the stomach tissues of patients in real time through the electronic endoscope system in the operation process, and the electronic endoscope system is widely applied to digestive system professionals of all levels of medical institutions at present.

According to the standard requirement of 4.2.7 in YY1028-2008 'endoscope for upper digestive tract of fiber' on observing the depth of field range, in order to enable a doctor to acquire clear images in an effective depth of field range when using an electronic endoscope system, when an image transmission assembly in the electronic endoscope is produced and assembled, the depth of field distance between an objective lens module and a COMS image photosensitive chip needs to be adjusted.

When the depth of field is adjusted, the existing production process needs to manually fix the image transmission assembly on the tool fixing seat, then sequentially assemble the objective lens seat (the COMS image photosensitive chip is fixed on the objective lens seat) and the objective lens module, respectively fix the objective lens seat and the objective lens module through the tool, and then drive the objective lens module to move up and down through the manual adjusting sliding table, and meanwhile, the definition degree of the near-end resolution plate image is observed and determined through the mode of visual inspection of staff. If the detected image is not clear in the process of adjusting the depth of field and the standard target required on the depth of field near-end resolution board cannot be accurately identified, the objective lens module needs to be repeatedly adjusted to move up and down and then the standard of the resolution is visually observed to judge whether the standard of the resolution reaches the standard or not. And the debugging is repeated for a plurality of times until the near-end resolution debugging reaches the standard, and then the far-end resolution is debugged in the same way. And when the near-end resolution and the far-end resolution meet the resolution standard requirement, the qualified depth of field debugging of the image transmission assembly of the electronic endoscope can be judged.

The production process of debugging the depth of field of the image transmission assembly according to the method is too complicated, the resolution of the near end and the far end of the image transmission assembly needs to be repeatedly confirmed when a set of image transmission assembly is adjusted, and the method is low in production efficiency and time-consuming and labor-consuming. Meanwhile, in the process of debugging the near-end and far-end resolution of the depth of field and the definition degree of the image transmission assembly, whether the depth of field and the image quality are qualified or not needs to be judged depending on the subjective consciousness of staff. If the staff is in a passive idle state or the judgment standards of the depth of field and the image quality are not clear, the depth of field of the product is unqualified or the image definition is not good, and the produced product finally directly influences the use of a doctor and influences the accurate judgment of the doctor in the operation process.

Therefore, the technical personnel in the field are dedicated to develop an automatic depth of field debugging device of the electronic endoscope image transmission assembly.

SUMMERY OF THE UTILITY MODEL

In view of the above-mentioned defects in the prior art, the present invention aims to provide an automatic depth-of-field debugging device for an image transmission assembly of an electronic endoscope.

In order to achieve the above object, the utility model provides a depth of field debugging device for an image transmission assembly of an electronic endoscope, which comprises a large bottom plate, wherein a target moving mechanism is arranged on one side of the upper side of the large bottom plate, and a resolution target mechanism capable of moving along the Z-axis direction is arranged on the target moving mechanism and is used for installing a resolution test board;

a moving platform is arranged on the other side of the upper edge of the large bottom plate, and a depth-of-field debugging mechanism capable of moving along the X-axis direction and the Y-axis direction is arranged on the moving platform and used for installing an objective lens module and a COMS image photosensitive chip which are positioned below the resolution test plate;

the large bottom plate is further provided with a debugging control system, the debugging control system comprises an image processor electrically connected with the COMS image photosensitive chip, and the debugging control system is respectively electrically connected with the target moving mechanism and the depth-of-field debugging mechanism and is used for adjusting the distance between the objective lens module and the COMS image photosensitive chip in the Z-axis direction.

In order to drive the resolution target mechanism to move along the Z-axis direction, the target moving mechanism comprises a bottom plate fixed on the large bottom plate and a mounting fixed plate vertically arranged on the bottom plate, and a motor module is arranged on the mounting fixed plate;

the motor module comprises a first motor electrically connected with the debugging control system, a first lead screw fixedly connected with an output shaft of the first motor, and a first movable sliding table in threaded connection with the first lead screw;

the resolution target mechanism is fixed on the first movable sliding table.

In order to prevent the installation fixing plate from inclining due to stress, a first supporting plate for supporting the installation fixing plate is arranged on the bottom plate.

In order to ensure that the resolution test board can reach the near-end depth of field working position and the far-end depth of field working position, a near-end depth of field position photoelectric switch and a far-end depth of field position photoelectric switch are further arranged on the motor module, and the near-end depth of field position photoelectric switch and the far-end depth of field position photoelectric switch are respectively and electrically connected with the debugging control system and the first motor.

Survey test panel and make the resolution survey test panel portable for better installation resolution, resolution target mechanism is including fixing connecting bottom plate, setting on the first slip table that removes are in second on the connecting bottom plate removes the slip table, fixes fixed plate on the second removes the slip table, transversely fixes light source support plate on the fixed plate, the light source support plate is used for fixing the resolution survey test panel is fixed.

In order to ensure that the COMS image photosensitive chip can collect the patterns on the resolution test board, the light source supporting plate is provided with a light source module.

In order to prevent the light source supporting plate from inclining due to stress, a second supporting plate for supporting the light source supporting plate is arranged on the fixing plate.

In order to adjust the distance between the objective lens module and the COMS image photosensitive chip in the Z-axis direction, the depth-of-field debugging mechanism comprises a supporting block fixed on the moving platform, a debugging motor module fixed on the supporting block, and a combined sliding block fixedly connected with the debugging motor module, wherein a clamping mechanism used for clamping the objective lens module, an upper pressing block used for clamping an objective lens seat and a lower pressing block used for clamping the COMS image photosensitive chip are fixed on the combined sliding block;

the debugging motor module comprises a second motor electrically connected with the debugging control system, a second lead screw fixedly connected with an output shaft of the second motor, and a third movable sliding table in threaded connection with the second lead screw;

the third movable sliding table is fixedly connected with the combined sliding block through a connecting block.

In order to control the stroke of the debugging motor module moving up and down in the Z-axis direction, a farthest position detection photoelectric switch and a nearest position detection photoelectric switch are further arranged on the debugging motor module, and the farthest position detection photoelectric switch and the nearest position detection photoelectric switch are respectively and electrically connected with the debugging control system and the second motor.

In order to ensure that the objective lens module and the COMS image photosensitive chip can be centered, the combined slide block comprises a Z-axis slide rail and a Z-axis slide block in sliding fit with the Z-axis slide rail, an X-axis slide rail is fixed on the Z-axis slide block, an X-axis slide block is in sliding fit with the X-axis slide rail, a Y-axis slide rail is fixed on the X-axis slide block, and a Y-axis slide block is in sliding fit with the Y-axis slide rail;

the clamping mechanism is fixedly connected to the Y-axis sliding block.

In order to conveniently install the COMS image sensing chip on the objective lens seat, the lower pressing block is in sliding fit with the upper pressing block.

In order to drive the depth of field debugging mechanism to move along the X-axis and the Y-axis, the moving platform comprises a moving sliding table which can drive the depth of field debugging mechanism to move along the X-axis and the Y-axis.

The utility model also provides a depth of field debugging method of the image transmission assembly of the electronic endoscope, which comprises the following steps:

the method comprises the following steps that firstly, a resolution test board, an objective lens module and a COMS image photosensitive chip are arranged on the same central line from top to bottom;

secondly, placing the resolution test board at a near-end depth of field working position, collecting the graph on the resolution test board through a COMS image photosensitive chip and sending a signal to an image processor for comparison and analysis, and if the collected graph on the resolution test board does not accord with the standard, adjusting the distance between the objective lens module and the COMS image photosensitive chip through a debugging control system until the collected graph on the resolution test board accords with the standard;

and step three, placing the resolution test board at the far-end depth of field working position, and debugging according to the step two.

The utility model has the advantages that: the utility model discloses electronic endoscope biography image subassembly depth of field debugging device is through the debugging motor module of debugging control system automatic control depth of field debugging mechanism automatically regulated objective lens module and COMS image sensitization chip between the interval to some production technology that relies on staff's manual debugging that have now replaced, through debugging control system automatic debugging, very big improvement the maneuverability of depth of field debugging process, also improved the production efficiency of electronic endoscope biography image subassembly depth of field debugging process, reduced staff's operation intensity of labour;

and simultaneously, the utility model discloses electronic endoscope biography image subassembly depth of field debugging device is at the depth of field debugging in-process, debug control system automatic acquisition near-end and the target image on the distal end resolution survey board, debug control system carries out the automatic comparison analysis processes of image, debug control system automatic analysis judges whether near-end and distal end resolution satisfy biography image subassembly depth of field standard requirement, thereby the effectual mode of having avoided through staff naked eye range estimation and the judgement standard that leads to is not clear, avoided relying on staff's subjective consciousness to judge whether the depth of field leads to the unqualified or the image definition bad adverse circumstances such as good of product depth of field for anthropogenic factor such as reaching standard with image standard.

Drawings

Fig. 1 is a schematic perspective view of a depth-of-field debugging device for an image transmission assembly of an electronic endoscope according to an embodiment of the present invention.

Fig. 2 is a front view of fig. 1.

Fig. 3 is a schematic structural view of a target moving mechanism in a depth-of-field debugging device of an image transmission assembly of an electronic endoscope according to an embodiment of the present invention.

Fig. 4 is a schematic structural view of a resolution target mechanism in the depth-of-field debugging device of the image transmission assembly of the electronic endoscope according to an embodiment of the present invention.

Fig. 5 is a schematic structural view of a mobile platform in a depth-of-field debugging device of an image transmission assembly of an electronic endoscope according to an embodiment of the present invention.

Fig. 6 is a schematic structural view of a depth-of-field debugging mechanism in a depth-of-field debugging device of an image transmission assembly of an electronic endoscope according to an embodiment of the present invention.

Fig. 7 is a schematic structural view of a combined slider in a depth-of-field debugging device of an image transmission assembly of an electronic endoscope according to an embodiment of the present invention.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and examples, wherein it is noted that, in the description of the invention, the terms "upper", "lower", "left", "right", "inner", "outer", etc. indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular manner, and therefore should not be construed as limiting the present invention. The terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

A depth of field debugging method for an electronic endoscope image transmission assembly comprises the following steps:

the method comprises the following steps that firstly, a resolution test board, an objective lens module and a COMS image photosensitive chip are arranged on the same central line from top to bottom;

secondly, placing the resolution test board at a near-end depth of field working position, collecting the graph on the resolution test board through a COMS image photosensitive chip and sending a signal to an image processor for comparison and analysis, and if the collected graph on the resolution test board does not accord with the standard, adjusting the distance between the objective lens module and the COMS image photosensitive chip through a debugging control system until the collected graph on the resolution test board accords with the standard;

and step three, placing the resolution test board at the far-end depth of field working position, and debugging according to the step two.

The method can be realized by the following depth-of-field debugging device of the image transmission assembly of the electronic endoscope.

As shown in fig. 1-7, a depth of field debugging device for an electronic endoscope image transmission assembly comprises a large base plate 500; a target moving mechanism 100 is arranged on one side of the upper side of the large bottom plate 500; the target moving mechanism 100 is provided with a resolving target mechanism 200 capable of moving along the Z-axis direction for mounting a resolving test board 207.

The other side of the upper side of the large bottom plate 500 is provided with a movable platform 300; the moving platform 300 is provided with a depth-of-field debugging mechanism 400 capable of moving along the X-axis and Y-axis directions, and is used for installing an objective lens module 410 and a cmos image sensor chip 408 below the resolution test board 207.

The large bottom plate 500 is also provided with a debugging control system 600; the debug control system 600 includes an image processor for electrically connecting with the cmos image sensor chip 408; the debugging control system 600 is electrically connected with the target moving mechanism 100 and the depth-of-field debugging mechanism 400 respectively; for adjusting the distance between the objective lens module 410 and the cmos image sensor chip 408 in the Z-axis direction.

In this embodiment, the target moving mechanism 100 includes a base plate 101 fixed on the large base plate 500, and a mounting fixing plate 105 erected on the base plate 101; the mounting plate 105 is provided with a motor module 106.

The motor module 106 comprises a first motor 106a electrically connected with the debugging control system 600, a first screw rod 106b fixedly connected with an output shaft of the first motor 106a, and a first movable sliding table 106c in threaded connection with the first screw rod 106 b.

The resolution target mechanism 200 is fixed to the first moving stage 106 c.

The base plate 101 is provided with a first support plate 102 supporting the mounting fixing plate 105.

The motor module 106 is also provided with a near-end depth-of-field position photoelectric switch 103 and a far-end depth-of-field position photoelectric switch 104; the near-end depth-of-field position photoelectric switch 103 and the far-end depth-of-field position photoelectric switch 104 are electrically connected to the debug control system 600 and the first motor 106a, respectively. Whether the resolution target mechanism 200 reaches the near-end depth of field working position and the far-end depth of field working position can be detected through the near-end depth of field position photoelectric switch 103 and the far-end depth of field position photoelectric switch 104; the start and stop of the first motor 106a are further controlled by the debugging control system 600, so as to ensure that the resolution test board can reach the near-end depth of field working position and the far-end depth of field working position.

In this embodiment, the resolution target mechanism 200 includes a connection bottom plate 201 fixed on the first moving sliding table 106c, a second moving sliding table 202 disposed on the connection bottom plate 201, a fixing plate 203 fixed on the second moving sliding table 202, and a light source supporting plate 205 transversely fixed on the fixing plate 203, where the light source supporting plate 205 is used to fix the resolution testing plate 207.

The light source support plate 205 is provided with a light source module 206.

The fixing plate 203 is provided with a second support plate 204 supporting a light source support plate 205.

In this embodiment, the depth-of-field debugging mechanism 400 includes a supporting block 411 fixed on the mobile platform 300, a debugging motor module 401 fixed on the supporting block 411, and a combined slider 405 fixedly connected with the debugging motor module 401; a clamping mechanism 406 for clamping the objective lens module 410, an upper pressing block 407b for clamping the objective lens holder 409 and a lower pressing block 407a for clamping the cmos image sensing chip 408 are fixed on the combined slide block 405.

The debugging motor module 401 comprises a second motor 401a electrically connected with the debugging control system 600, a second screw rod 401b fixedly connected with an output shaft of the second motor 401a, and a third movable sliding table 401c in threaded connection with the second screw rod 401 b.

The third moving sliding table 401c is fixedly connected with a combined sliding block 405 through a connecting block 404.

The debugging motor module 401 is further provided with a farthest position detection photoelectric switch 402 and a nearest position detection photoelectric switch 403; both the farthest position sensing photoelectric switch 402 and the nearest position sensing photoelectric switch 403 are electrically connected to the commissioning control system 600 and the second motor 401a, respectively. The distance between the objective lens module 410 and the objective lens holder 409 can be detected by the farthest position detecting photoelectric switch 402 and the nearest position detecting photoelectric switch 403; the debugging control system 600 further controls the second motor 401a to start and stop, so as to control the stroke of the debugging motor module moving up and down in the Z-axis direction.

The combined slide block 405 comprises a Z-axis slide rail 405a and a Z-axis slide block 405b matched with the Z-axis slide rail in a sliding manner; an X-axis slide rail 405c is fixed on the Z-axis slide block; an X-axis sliding block 405d is in sliding fit with the X-axis sliding rail; a Y-axis slide rail 405e is fixed on the X-axis slide block; a Y-axis slider 405f is slidably fitted on the Y-axis slide rail.

The chucking mechanism 406 is fixedly attached to the Y-axis slider 405 f.

The lower press block 407a is slidably fitted on the upper press block 407 b.

The mobile platform 300 includes a mobile sliding table 301 capable of driving the depth of field debugging mechanism 400 to move along the X-axis and Y-axis directions. In this embodiment, the movable sliding table 301 is fixed on the combined rotary sliding table 305; the depth of field debugging mechanism 400 can be driven to move linearly along the X-axis and Y-axis directions by adjusting the knob of the movable sliding table 301. A moving platform bottom plate 307 is arranged on the moving sliding table 301; the movable sliding table 302 is fixed on the left side of the movable platform bottom plate 307; the objective lens holder fixing mechanism at the lower end of the depth of field debugging mechanism 400 can be driven to move linearly along the directions of the X axis and the Y axis by adjusting the knob of the movable sliding table 302. The objective lens holder fixing mechanism at the lower end of the depth of field debugging mechanism 400 can be driven to slightly rotate by a certain angle around the Y axis by adjusting the knob of the rotary sliding table 303. The objective lens holder fixing mechanism at the lower end of the depth of field debugging mechanism 400 can be driven to slightly rotate by a certain angle around the X axis by adjusting the knob of the rotary sliding table 304. The combined rotary sliding table 305 is fixedly connected with the corresponding mounting position of the large base plate 500 through the combined rotary sliding table 306; the movable platform 300 and the depth-of-field debugging mechanism 400 can be driven to integrally rotate by a certain angle around the Y axis by adjusting the knob of the combined rotating sliding table 305; the movable platform 300 and the depth-of-field debugging mechanism 400 can be driven to integrally rotate by a certain angle around the X axis by adjusting the knob of the combined rotating sliding table 306; the 6 sets of sliding tables (301-306) facilitate the operator to correct the relative positions of the image transmission assembly (the objective lens module and the cmos image sensor chip) to be debugged and the resolution test board 207.

Before debugging, the resolution test board 207 is installed on the light source support plate 205 of the resolution target mechanism 200, the objective lens module 410 is clamped on the clamping mechanism 406, the objective lens seat 409 is clamped on the upper pressing block 407b, and the cmos image photosensitive chip 408 is clamped on the lower pressing block 407 a; the positions of the clamping mechanism 406 on the X axis, the Y axis and the Z axis are adjusted through the combined sliding block 405, so that the objective lens module 410 is aligned with the objective lens seat 409; then, the pressing block 407a is pushed to enable the COMS image photosensitive chip 408 to be installed in the objective lens seat 409, and therefore the objective lens module and the COMS image photosensitive chip are centered; then, the depth-of-field debugging mechanism 400 is driven by the mobile platform 300 to move along the X-axis and Y-axis directions; in this embodiment, the mobile platform 300 may further drive the depth-of-field debugging mechanism 400 to slightly rotate around the X axis and the Y axis; the resolution test board 207, the objective lens module 410 and the cmos image sensor chip 408 are made to be concentric.

The debugging process is as follows:

the depth of field debugging device of the electronic endoscope image transmission assembly is powered on and started, and the debugging control system 600 turns on the light source of the light source module 206; after the system is started, the debugging control system 600 controls the motor module 106 to drive the resolution test board 207 to move to the near-end depth of field working position N; meanwhile, the debugging control system 600 controls the debugging motor module 401 to drive the clamping mechanism 406 to move up and down along the Z axis so as to adjust the distance between the objective lens module 410 and the COMS image photosensitive chip 408; the COMS image photosensitive chip 408 collects the resolution target image on the resolution test plate 207, and transmits the image to the image processor for image comparison and analysis; the debug control system 600 automatically determines whether the near-end depth-of-field resolution and the image quality meet the requirements.

If the near-end depth of field resolution meets the requirement, the debugging control system 600 controls the motor module 106 to drive the resolution test board 207 to move to the far-end depth of field working position F; the remote depth-of-field photoelectric switch 104 transmits a signal to the debugging control system 600 after detecting that the resolution test board 207 is in place; the debugging control system 600 controls the motor module 106 to stop working; then, acquiring a resolution target image on the resolution test plate 207 through the COMS image photosensitive chip 408, transmitting the image to an image processor, and then performing image comparison analysis processing; the debug control system 600 automatically determines whether the far-end depth-of-field resolution and the image quality meet the requirements.

The debugging control system 600 automatically debugs and automatically compares and analyzes the acquired image information; when the near-end resolution and the far-end resolution can meet the standard requirements, the system is shut down and a test result is fed back; an employee can visually observe the depth of field debugging result after the system is debugged through the display; after the depth of field is debugged to be qualified, the staff manually carries out glue dispensing and fixing on the objective lens module, the objective lens seat and the COMS image photosensitive chip; and finally completing the depth of field debugging work of the image transmission assembly.

The foregoing has described in detail preferred embodiments of the present invention. It should be understood that numerous modifications and variations can be devised by those skilled in the art in light of the teachings of the present invention without undue experimentation. Therefore, the technical solutions that can be obtained by a person skilled in the art through logic analysis, reasoning or limited experiments based on the prior art according to the concepts of the present invention should be within the scope of protection defined by the claims.

Claims (12)

1. The depth-of-field debugging device for the image transmission assembly of the electronic endoscope is characterized by comprising a large bottom plate (500), wherein a target moving mechanism (100) is arranged on one side of the upper side of the large bottom plate (500), and a resolution target mechanism (200) capable of moving along the Z-axis direction is arranged on the target moving mechanism (100) and used for installing a resolution test plate (207);

a moving platform (300) is arranged on the other side of the upper side of the large bottom plate (500), and a depth-of-field debugging mechanism (400) capable of moving along the X-axis direction and the Y-axis direction is arranged on the moving platform (300) and used for installing an objective lens module (410) and a COMS image photosensitive chip (408) which are positioned below the resolution test plate (207);

the large bottom plate (500) is further provided with a debugging control system (600), the debugging control system (600) comprises an image processor electrically connected with the COMS image photosensitive chip (408), and the debugging control system (600) is respectively electrically connected with the target moving mechanism (100) and the depth-of-field debugging mechanism (400) and used for adjusting the distance between the objective lens module (410) and the COMS image photosensitive chip (408) in the Z-axis direction.

2. The depth-of-field debugging device of the electronic endoscope image transmission assembly according to claim 1, wherein the target moving mechanism (100) comprises a base plate (101) fixed on the large base plate (500), and a mounting and fixing plate (105) vertically arranged on the base plate (101), and a motor module (106) is arranged on the mounting and fixing plate (105);

the motor module (106) comprises a first motor (106a) electrically connected with the debugging control system (600), a first screw rod (106b) fixedly connected with an output shaft of the first motor (106a), and a first movable sliding table (106c) in threaded connection with the first screw rod (106 b);

the resolution target mechanism (200) is fixed on the first movable sliding table (106 c).

3. The depth of field adjustment device for an electronic endoscope image transmission assembly according to claim 2, wherein the base plate (101) is provided with a first support plate (102) for supporting the mounting and fixing plate (105).

4. The depth-of-field debugging device of the electronic endoscope image transmission assembly according to claim 2, wherein the motor module (106) is further provided with a proximal depth-of-field position photoelectric switch (103) and a distal depth-of-field position photoelectric switch (104), and the proximal depth-of-field position photoelectric switch (103) and the distal depth-of-field position photoelectric switch (104) are electrically connected to the debugging control system (600) and the first motor (106a), respectively.

5. The depth-of-field debugging device for electronic endoscope image transmission assembly according to claim 2, wherein the resolution target mechanism (200) comprises a connecting bottom plate (201) fixed on the first moving sliding table (106c), a second moving sliding table (202) arranged on the connecting bottom plate (201), a fixing plate (203) fixed on the second moving sliding table (202), and a light source supporting plate (205) transversely fixed on the fixing plate (203), wherein the light source supporting plate (205) is used for fixing the resolution testing plate (207).

6. The depth-of-field adjustment device for an electronic endoscope image transmission assembly according to claim 5, wherein a light source module (206) is disposed on the light source support plate (205).

7. The depth-of-field adjustment apparatus for an electronic endoscope image-transmitting unit according to claim 5, wherein a second support plate (204) for supporting the light source support plate (205) is provided on the fixing plate (203).

8. The depth-of-field debugging device of the electronic endoscope image-transmitting component of claim 1, wherein the depth-of-field debugging mechanism (400) comprises a supporting block (411) fixed on the mobile platform (300), a debugging motor module (401) fixed on the supporting block (411), and a combined sliding block (405) fixedly connected with the debugging motor module (401), and a clamping mechanism (406) for clamping the objective lens module (410), an upper pressing block (407b) for clamping an objective lens holder (409), and a lower pressing block (407a) for clamping the cmos image sensing chip (408) are fixed on the combined sliding block (405);

the debugging motor module (401) comprises a second motor (401a) electrically connected with the debugging control system (600), a second screw rod (401b) fixedly connected with an output shaft of the second motor (401a), and a third movable sliding table (401c) in threaded connection with the second screw rod (401 b);

and the third movable sliding table (401c) is fixedly connected with the combined sliding block (405) through a connecting block (404).

9. The depth-of-field adjustment device for an electronic endoscope image transmission assembly according to claim 8, wherein a farthest position detection photoelectric switch (402) and a nearest position detection photoelectric switch (403) are further disposed on the adjustment motor module (401), and the farthest position detection photoelectric switch (402) and the nearest position detection photoelectric switch (403) are electrically connected to the adjustment control system (600) and the second motor (401a), respectively.

10. The depth-of-field debugging device of an electronic endoscope image-transmitting component according to claim 8, wherein the combined slide block (405) comprises a Z-axis slide rail (405a) and a Z-axis slide block (405b) slidably fitted on the Z-axis slide rail, an X-axis slide rail (405c) is fixed on the Z-axis slide block (405b), an X-axis slide block (405d) is slidably fitted on the X-axis slide rail (405c), a Y-axis slide rail (405e) is fixed on the X-axis slide block (405d), and a Y-axis slide block (405f) is slidably fitted on the Y-axis slide rail (405 e);

the clamping mechanism (406) is fixedly connected to the Y-axis slide block (405 f).

11. The depth of field adjustment device of an electronic endoscope image transmission assembly according to claim 8, characterized in that the lower press block (407a) is slidably fitted on the upper press block (407 b).

12. The depth-of-field debugging device of electronic endoscope image transmission assembly according to claim 1, wherein said moving platform (300) comprises a moving slide table (301) capable of driving said depth-of-field debugging mechanism (400) to move along X-axis and Y-axis directions.

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