High-precision intelligent eye disease detection and treatment instrument
The design of the lifting and position adjustment components solves the problem of head fixation for testers of different body types, ensuring the accuracy and stability of the test.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 沙润生
- Filing Date
- 2025-01-07
- Publication Date
- 2026-06-05
AI Technical Summary
Existing eye disease detection instruments cannot effectively fix the head position of test subjects of different body types, causing head shaking during the test, which affects the accuracy and normal operation of the test.
The device employs a lifting and position adjustment assembly, including an electric push rod, gears, racks, and screws, to adjust the height of the detection unit and chin rest. Combined with the position adjustment of the head rest, this ensures that the subject's head is accurately positioned under the combined action of the detection unit, chin rest, and head rest.
It effectively fixed the head position of test subjects of different body types, ensuring smooth and accurate testing.
Smart Images

Figure CN224320703U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of medical equipment technology, and in particular to a high-precision intelligent eye disease detection and treatment instrument. Background Technology
[0002] Eye disease detection and treatment instruments are devices used for clinical diagnosis and treatment in ophthalmology. They can measure the structural and functional parameters of the eye to help doctors diagnose and treat eye diseases.
[0003] These instruments include a variety of devices such as ophthalmic optical biometers, slit-lamp microscopes, visual acuity testers, tonometers, corneal topography instruments, and fundus cameras. They can measure parameters of various parts of the eye, such as visual acuity, intraocular pressure, corneal curvature, corneal thickness, vitreous depth, lens thickness, axial length, and pupil diameter. During eye examinations, these instruments provide accurate and reliable data, helping doctors diagnose eye diseases and develop appropriate treatment plans. Furthermore, they are frequently used in ophthalmic surgeries, such as cataract surgery and corneal surgery, providing preoperative examinations and intraoperative guidance.
[0004] Existing eye disease detection and treatment methods cannot effectively stabilize the head position of subjects of different body types. Head movement during the test can affect the normal progress and accuracy of the examination. This invention addresses this issue by proposing a high-precision intelligent eye disease detection and treatment instrument. This instrument aims to solve the aforementioned problems by accurately locating the head of subjects of different body types, thereby ensuring smooth and accurate testing. Utility Model Content
[0005] To address the aforementioned shortcomings in the existing technology, this utility model provides a high-precision intelligent eye disease detection and treatment instrument.
[0006] To achieve the aforementioned objectives, the technical solution adopted by this utility model is as follows:
[0007] A high-precision intelligent eye disease detection and treatment instrument includes a base plate, a detection body, and a detection unit. The detection unit is located on the back of the detection body.
[0008] The upper surface of the base plate is provided with an equipment box, and a lifting block is slidably connected to the equipment box. The upper end of the lifting block is connected to the detection body. A lifting assembly is provided inside the equipment box. The lifting assembly adjusts the length of the lifting block protruding from the equipment box.
[0009] A chin rest is provided above the rear end of the equipment box, and a second lifting component is provided inside the rear end of the equipment box. The second lifting component adjusts the height of the chin rest.
[0010] The equipment box has telescopic rods on both sides of the detection body above it. The upper end of the telescopic rods is equipped with a mounting block. The detection unit has a head support on the rear side. The head support is connected to the mounting block through a connecting plate. The upper surface of the equipment box is equipped with a position adjustment component, which adjusts the position of the telescopic rods.
[0011] As an improvement, the lifting assembly includes an electric push rod, a rack, a gear, and a screw. The screw is rotatably connected inside the equipment box and is threadedly connected to the lifting block. The lower end of the screw is provided with a gear. An electric push rod is provided on one side of the screw inside the equipment box. A rack is provided on the piston rod of the electric push rod, and the rack meshes with the gear.
[0012] As an improvement, the second lifting component includes a motor, a second gear, and a second rack. The motor is located inside the equipment box, and the second gear is located on the output end of the motor. The second rack is slidably connected to the equipment box, and the upper end of the second rack is connected to the chin support. The second rack meshes with the second gear.
[0013] As an improvement, the position adjustment component includes a groove, a slider, and a second electric push rod. The upper end face of the device box has grooves on both sides of the detection body. A slider is slidably connected in the groove. The slider is connected to the lower end of the telescopic rod. One of the grooves has a second electric push rod, and the piston rod of the second electric push rod is connected to the slider.
[0014] As an improvement, the detection body is provided with a stabilizing guide component on its side. The stabilizing guide component is connected to the fixed rod of the telescopic rod and provides stable guidance for its movement direction.
[0015] As an improvement, the stabilizing guide component includes a groove, a movable block, and a connecting piece. The detection body has a groove on its side, and a movable block is slidably connected in the groove. The movable block is connected to the fixed rod of the telescopic rod through the connecting piece.
[0016] Compared to traditional technologies, the advantages of this utility model are:
[0017] 1. During use, the distance between the lifting blocks protruding from the equipment box is adjusted by the lifting assembly, thereby adjusting the height of the detection body and the detection unit to accommodate users of different body types.
[0018] 2. The lifting component two adjusts the height of the chin rest and adjusts the height of the head rest by adjusting the length of the telescopic rod. After the height of the head rest is determined, the position adjustment component adjusts the position of the head rest in the horizontal direction. Under the combined action of the detection unit, chin rest and head rest, the position of the test subject's head is limited, thereby ensuring the accuracy of the detection. Attached Figure Description
[0019] Figure 1 This is a schematic diagram of the structure of the present invention. Figure 1 ;
[0020] Figure 2 This is a schematic diagram of the structure of the present invention. Figure 2 ;
[0021] Figure 3 This is a structural schematic diagram of the first utility model lifting component;
[0022] Figure 4 This is a schematic diagram of the structure of the second practical lifting component;
[0023] Appendix Label Reference Table:
[0024] 1. Base plate; 2. Detection body; 3. Detection unit; 4. Equipment box; 5. Lifting block; 6. Chin support; 7. Telescopic rod; 8. Mounting block; 9. Head support; 10. Connecting plate; 11. Electric push rod one; 12. Rack one; 13. Gear one; 14. Screw; 15. Motor; 16. Gear two; 17. Rack two; 18. Groove; 19. Slider; 20. Electric push rod two; 21. Slide groove; 22. Movable block; 23. Connecting piece. Detailed Implementation
[0025] The specific embodiments of this utility model will be further described below with reference to the accompanying drawings. Identical components are indicated by the same reference numerals.
[0026] It should be noted that the terms “front,” “back,” “left,” “right,” “up,” and “down” used in the following description refer to the directions shown in the attached diagram, while the terms “inside” and “outside” refer to the directions toward or away from the geometric center of a specific component, respectively.
[0027] To make the content of this utility model easier to understand, the technical solutions of this utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of this utility model.
[0028] Example 1
[0029] Combined with appendix Figure 1-3 The upper surface of the base plate 1 is provided with an equipment box 4, and a lifting block 5 is slidably connected to the equipment box 4. The upper end of the lifting block 5 is connected to the detection body 2. A lifting assembly is provided inside the equipment box 4. The lifting assembly adjusts the length of the lifting block 5 protruding from the equipment box 4.
[0030] The lifting assembly includes an electric push rod 11, a rack 12, a gear 13, and a screw 14. The screw 14 is rotatably connected inside the equipment box 4. The screw 14 is threadedly connected to the lifting block 5. The lower end of the screw 14 is provided with a gear 13. An electric push rod 11 is provided on one side of the screw 14 inside the equipment box 4. The piston rod of the electric push rod 11 is provided with a rack 12, and the rack 12 meshes with the gear 13.
[0031] During use, the piston rod of the electric push rod 11 is extended or retracted according to the body shape of the person being tested, thereby driving the rack 12 to move. The movement of the rack 12 drives the gear 13 meshing with it to rotate. The gear 13 drives the screw 14 to rotate. The screw 14 drives the lifting block 5 threadedly connected to it to move. The lifting block 5 adjusts the height of the detection body 2 and the detection unit 3 so that the detection unit 3 can be level with the eyes of the person being tested, making it suitable for the person to use.
[0032] Combined with appendix Figure 1 , 2 4. A chin support 6 is provided above the rear end of the equipment box 4. A lifting component 2 is provided inside the rear end of the equipment box 4. The lifting component 2 adjusts the height of the chin support 6.
[0033] The second lifting component includes a motor 15, a second gear 16, and a second rack 17. The motor 15 is installed inside the equipment box 4. The second gear 16 is installed on the output end of the motor 15. The second rack 17 is slidably connected to the equipment box 4. The upper end of the second rack 17 is connected to the chin support 6. The second rack 17 meshes with the second gear 16.
[0034] After the test subject's eyes are in contact with the testing unit 3, their chin is positioned above the chin support 6. At this time, the motor 15 rotates, and through the meshing of gear 2 16 and rack 2 17, it drives rack 2 17 to move, adjusting the length of rack 2 17 protruding from the device box 4. Rack 2 17 drives chin support 6 to move, so that chin support 6 is in contact with the test subject's chin.
[0035] Combined with appendix Figure 1-2 The equipment box 4 has telescopic rods 7 on both sides of the detection body 2 above it. The telescopic rods 7 have mounting blocks 8 at their upper ends. The detection unit 3 has a head support 9 at its rear. The head support 9 is connected to the mounting blocks 8 through a connecting plate 10. The equipment box 4 has a position adjustment component on its upper surface. The position adjustment component adjusts the position of the telescopic rods 7.
[0036] The position adjustment assembly includes a groove 18, a slider 19, and an electric push rod 20. The upper end face of the device box 4 has grooves 18 on both sides of the detection body 2. A slider 19 is slidably connected in the groove 18. The slider 19 is connected to the lower end of the telescopic rod 7. An electric push rod 20 is provided in one of the grooves 18. The piston rod of the electric push rod 20 is connected to the slider 19.
[0037] The length of the telescopic rod 7 is adjusted to adjust the height of the mounting block 8. The mounting block 8 adjusts the height of the headrest 9 through the connecting plate 10, so that the headrest 9 is located at the back of the tester's head. At this time, the piston rod of the electric push rod 20 extends, driving the slider 19 to slide in the groove 18. The slider 19 drives the headrest 9 to move towards the detection body 2 through the telescopic rod 7, the mounting block 8 and the connecting plate 10. Under the combined action of the detection unit 3, the chin rest 6 and the headrest 9, the position of the tester's head is limited. The detection body 2 detects the tester's eyes through the detection unit 3, thereby ensuring the accuracy of the detection.
[0038] Example 2
[0039] Combined with appendix Figure 1-2 The detection body 2 is provided with a stabilizing guide component on its side. The stabilizing guide component is connected to the fixed rod of the telescopic rod 7 and provides stable guidance for its movement direction.
[0040] The stabilizing guide component includes a slide groove 21, a movable block 22, and a connecting piece 23. The side of the detection body 2 is provided with a slide groove 21, and the movable block 22 is slidably connected in the slide groove 21. The movable block 22 is connected to the fixed rod of the telescopic rod 7 through the connecting piece 23.
[0041] Based on Embodiment 1, during the movement of the headrest 9, the telescopic rod 7 drives the movable block 22 to move within the slide groove 21 via the connecting piece 23. With the cooperation of the movable block 22 and the slide groove 21, the movement direction of the telescopic rod 7 is stably guided, thereby stably guiding the movement direction of the headrest 9.
[0042] The above description is only a preferred embodiment of this utility model patent and is not intended to limit this utility model patent. Any modifications, equivalent substitutions and improvements made within the spirit and principles of this utility model patent should be included within the protection scope of this utility model patent.
Claims
1. A high-precision intelligent eye disease detection and treatment instrument, comprising a base plate (1), a detection body (2), and a detection unit (3), wherein the detection body (2) has a detection unit (3) on its back side, characterized in that: The upper surface of the base plate (1) is provided with an equipment box (4), and a lifting block (5) is slidably connected to the equipment box (4). The upper end of the lifting block (5) is connected to the detection body (2). A lifting assembly is provided inside the equipment box (4). The lifting assembly adjusts the length of the lifting block (5) protruding from the equipment box (4). The device box (4) is provided with a chin support (6) above the rear end, and the device box (4) is provided with a lifting component two at the rear end, which adjusts the height of the chin support (6). The equipment box (4) has telescopic rods (7) on both sides of the detection body (2) on top. The telescopic rods (7) have mounting blocks (8) on their upper ends. The detection unit (3) has a head support (9) on its rear side. The head support (9) is connected to the mounting block (8) through a connecting plate (10). The equipment box (4) has a position adjustment component on its upper surface. The position adjustment component adjusts the position of the telescopic rods (7).
2. The high-precision intelligent eye disease detection and treatment instrument according to claim 1, characterized in that: The lifting assembly includes an electric push rod (11), a rack (12), a gear (13), and a screw (14). The screw (14) is rotatably connected inside the equipment box (4). The screw (14) is threadedly connected to the lifting block (5). The lower end of the screw (14) is provided with a gear (13). An electric push rod (11) is provided on one side of the screw (14) inside the equipment box (4). The piston rod of the electric push rod (11) is provided with a rack (12). The rack (12) meshes with the gear (13).
3. The high-precision intelligent eye disease detection and treatment instrument according to claim 1, characterized in that: The second lifting component includes a motor (15), a second gear (16), and a second rack (17). The motor (15) is installed inside the equipment box (4). The output end of the motor (15) is equipped with a second gear (16). The second rack (17) is slidably connected to the equipment box (4). The upper end of the second rack (17) is connected to the chin support (6). The second rack (17) meshes with the second gear (16).
4. The high-precision intelligent eye disease detection and treatment instrument according to claim 1, characterized in that: The position adjustment component includes a groove (18), a slider (19), and an electric push rod (20). The upper end face of the device box (4) has grooves (18) on both sides of the detection body (2). A slider (19) is slidably connected in the groove (18). The slider (19) is connected to the lower end of the telescopic rod (7). An electric push rod (20) is provided in one of the grooves (18). The piston rod of the electric push rod (20) is connected to the slider (19).
5. The high-precision intelligent eye disease detection and treatment instrument according to claim 4, characterized in that: The detection body (2) is provided with a stabilizing guide component on its side. The stabilizing guide component is connected to the fixed rod of the telescopic rod (7) and provides stable guidance for its movement direction.
6. The high-precision intelligent eye disease detection and treatment instrument according to claim 5, characterized in that: The stabilizing guide component includes a groove (21), a movable block (22), and a connecting piece (23). The detection body (2) has a groove (21) on its side. The movable block (22) is slidably connected in the groove (21). The movable block (22) is connected to the fixed rod of the telescopic rod (7) through the connecting piece (23).