CN219742680U - Face-tongue inspection 3D imaging device based on high-speed digital micromirror device - Google Patents

Abstract

The utility model relates to the technical field of medical equipment, and discloses a facial-lingual inspection 3D imaging device based on a high-speed digital micro-mirror device, which is characterized in that: comprises a shading hood, a face scanner, a sliding table, a rotating shaft mechanism, a lamp ring and a jaw support; the rotating shaft mechanism is arranged at the top of the shading hood; the face scanner is connected to the sliding table through a connecting rod; the face scanner and the sliding table are arranged in the shading hood; the front end of the face scanner is provided with the lamp ring; the E Tuo is arranged on the inner bottom surface of the light shielding hood; according to the utility model, the three-dimensional information of the tongue and the face of the patient is obtained by using the face scanner, the medical staff can adjust the position of the face scanner through the sliding table to obtain a more complete three-dimensional image, and the doctor can be assisted to carry out objective and accurate analysis and diagnosis through the three-dimensional information of the tongue and the face.

Description

Face-tongue inspection 3D imaging device based on high-speed digital micromirror device

Technical Field

The utility model relates to the technical field of medical equipment, in particular to a facial-lingual inspection 3D imaging device based on a high-speed digital micro-mirror device.

Background

Inspection is the first four diagnostic methods of traditional Chinese medicine, and is an important means for disease diagnosis and health discrimination. The facial and tongue diagnosis is the main content of inspection, and the traditional Chinese medicine performs diagnosis and identification of the disease state by observing the changes of the colors, textures and morphological contours of the face and tongue, and is one of the most important and clinically valuable inspection methods in the inspection of the traditional Chinese medicine, and plays an extremely important role in the traditional Chinese medicine knowledge system and clinical diagnosis. Through the inspection of the face and tongue, not only the deficiency and excess of the viscera and the urgency of the disease can be known, but also the pathological conditions and abnormal functions of the viscera which cannot be checked by CT, MR, B ultrasonic equipment and the like can be found, and the device is a sunny and rainy watch for human health. The objective study of the inspection of the tongue of the traditional Chinese medicine is the main study problem of the diagnosis of the traditional Chinese medicine, and the development of the information technology of the diagnosis of the traditional Chinese medicine is greatly promoted.

However, the examination and analysis of the traditional inspection mainly depends on the accumulation of the knowledge of traditional Chinese medicine, is greatly influenced by external environmental factors, has strong subjectivity, and cannot provide objective and quantized examination results. Since the early eighties, many research institutions at home and abroad work together to objectively study the inspection of the tongue, and most of the research is currently based on two-dimensional tongue images for analysis and diagnosis, however, the two-dimensional tongue images cannot provide three-dimensional information of the tongue body, such as morphological contours, tongue coating thickness, tongue crack length, tooth trace depth and the like, which directly affect the subsequent traditional Chinese medicine diagnosis results. Compared with a two-dimensional tongue image, the three-dimensional information such as the morphological outline, tongue coating thickness, tongue crack length and the like of the tongue body can provide more complete diagnosis information for traditional Chinese medicine, and can provide objective and quantitative basis for inspection of the traditional Chinese medicine. In addition, complexion, tongue color and tongue coating color are important basis for distinguishing diseases in inspection of Chinese medicine. Therefore, the acquisition of the color three-dimensional information of the face and the tongue has extremely profound significance for the objectification analysis and diagnosis of the doctor inspection. Therefore, aiming at the problems, based on the traditional Chinese medicine inspection theory, the imaging system of the color three-dimensional face-to-tongue inspection instrument is designed by adopting a line structured light vision measurement technology to assist doctors in objective and accurate analysis and diagnosis, so that the traditional Chinese medicine theory can be better developed, the mutual learning and promotion of the traditional Chinese medicine inspection are facilitated, and the final establishment of a comprehensive intelligent traditional Chinese medicine inspection system is greatly promoted, so that the informatization and intelligent development of the traditional Chinese medicine inspection are promoted.

Disclosure of Invention

The utility model aims to provide a facial lingual inspection 3D imaging device based on a high-speed digital micro-mirror device so as to assist doctors to carry out objective and accurate analysis and diagnosis.

In order to achieve the above purpose, the technical scheme provided by the utility model is as follows:

the face-to-tongue inspection 3D imaging device based on the high-speed digital micromirror device comprises a shading hood 1, a face scanner 2, a sliding table 3, a rotating shaft mechanism 4, a lamp ring 5 and a jaw support 6; the rotating shaft mechanism 4 is arranged at the top of the light shielding hood 1; the face scanner 2 is connected to the sliding table 3 through a connecting rod 12; the face scanner 2 and the sliding table 3 are arranged in the shading hood 1; the front end of the face scanner 2 is provided with the lamp ring 5; the jaw support 6 is arranged on the inner bottom surface of the light shielding hood 1.

The light shielding head cap 1 includes a head cap 101, a first side baffle 102, and a second side baffle 103; the first side baffle 102 and the second side baffle 103 are connected to the outside of the head cover 101 through the rotating shaft mechanism 4 at the upper end of the head cover 101.

The rotating shaft mechanism 4 comprises a first rotating shaft 401, a second rotating shaft 402 and a connecting shaft 403; the first rotating shaft 401 and the second rotating shaft 402 are connected through the connecting shaft 403.

The back of the lamp ring 5 is provided with a lamp ring base 13; the lower end of the lamp ring base 13 is arranged on the inner bottom surface of the light shielding hood 1 through a bracket 9; the back of the bracket 9 is provided with a power supply 8 and a control module 7; the side of the control module 7 is connected with a controller 11 through a wire 10.

The specific model of the sliding table 3 is MOS-M45.

The specific model of the face scanner 2 is 8BTM.

The model of the control module 7 is ZWK072040A.

The model of the power supply 8 is s-120-12.

The controller 11 controls the lateral position and the switching of the face scanner 2.

The first side baffle 102 and the second side baffle 103 are respectively connected with the first rotating shaft 401 and the second rotating shaft 402; when in use, the head of a person is covered by the whole light shielding hood 1 through manual rotation; the first side baffle 102 and the second side baffle 103 function as a light shield to assist in better forming 3D images.

Compared with the prior art, the utility model has the beneficial effects that:

according to the utility model, the three-dimensional information of the tongue and the face of the patient is obtained by using the face scanner, the medical staff can adjust the position of the face scanner through the sliding table to obtain a more complete three-dimensional image, and the doctor can be assisted to carry out objective and accurate analysis and diagnosis through the three-dimensional information of the tongue and the face.

Drawings

FIG. 1 is one of the schematic diagrams of the present utility model;

FIG. 2 is a second schematic diagram of the present utility model;

FIG. 3 is a schematic view of the present utility model with parts disassembled;

FIG. 4 is a schematic illustration of a portion of the components of the present utility model.

In the figure: 1. a light shield; 2. a face scanner; 3. a sliding table; 4. a spindle mechanism; 5. a lamp ring; 6. a jaw support; 7. a control module; 8. a power supply; 9. a bracket; 10. an electric wire; 11. a controller; 12. a connecting rod; 101. a head cover; 102. a first side baffle; 103. a second side baffle; 401. a first rotating shaft; 402. a second rotating shaft; 403. and a connecting shaft.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model.

The face-to-tongue inspection 3D imaging device based on the high-speed digital micromirror device comprises a shading hood 1, a face scanner 2, a sliding table 3, a rotating shaft mechanism 4, a lamp ring 5 and a jaw support 6; the rotating shaft mechanism 4 is arranged at the top of the light shielding hood 1; the face scanner 2 is connected to the sliding table 3 through a connecting rod 12; the face scanner 2 and the sliding table 3 are arranged in the shading hood 1; the front end of the face scanner 2 is provided with the lamp ring 5; the jaw support 6 is arranged on the inner bottom surface of the light shielding hood 1.

The light shielding head cap 1 includes a head cap 101, a first side baffle 102, and a second side baffle 103; the first side baffle 102 and the second side baffle 103 are connected to the outside of the head cover 101 through the rotating shaft mechanism 4 at the upper end of the head cover 101.

The rotating shaft mechanism 4 comprises a first rotating shaft 401, a second rotating shaft 402 and a connecting shaft 403; the first rotating shaft 401 and the second rotating shaft 402 are connected through the connecting shaft 403.

The back of the lamp ring 5 is provided with a lamp ring base 13; the lower end of the lamp ring base 13 is arranged on the inner bottom surface of the light shielding hood 1 through a bracket 9; the back of the bracket 9 is provided with a power supply 8 and a control module 7; the side of the control module 7 is connected with a controller 11 through a wire 10.

The specific model of the sliding table 3 is MOS-M45.

The specific model of the face scanner 2 is 8BTM.

The model of the control module 7 is ZWK072040A.

The model of the power supply 8 is s-120-12.

The first side baffle 102 and the second side baffle 103 are respectively connected with the first rotating shaft 401 and the second rotating shaft 402; when in use, the head of a person is covered by the whole light shielding hood 1 through manual rotation; the first side baffle 102 and the second side baffle 103 function as a light shield to assist in better forming 3D images.

In use, the patient places the chin on the chin rest 6, closing the first side guards 102 and the second side guards 103; the medical staff can adjust the position of the face scanner 2 through the controller 11 to obtain clear three-dimensional information of the tongue body.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the above-described embodiments, and that the above-described embodiments and descriptions are only preferred embodiments of the present utility model, and are not intended to limit the utility model, and that various changes and modifications may be made therein without departing from the spirit and scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (4)

1. Face and tongue inspection 3D image device based on high-speed digital micromirror device, its characterized in that: comprises a shading hood (1), a face scanner (2), a sliding table (3), a rotating shaft mechanism (4), a lamp ring (5) and a jaw support (6); the rotating shaft mechanism (4) is arranged at the top of the shading hood (1); the face scanner (2) is connected to the sliding table (3) through a connecting rod (12); the face scanner (2) and the sliding table (3) are arranged in the shading hood (1); the front end of the face scanner (2) is provided with the lamp ring (5); the E Tuo (6) is arranged on the inner bottom surface of the light shielding hood (1).

2. The high-speed digital micromirror device-based facial inspection 3D imaging apparatus according to claim 1, wherein the light shielding hood (1) comprises a hood (101), a first side baffle (102) and a second side baffle (103); the first side baffle (102) and the second side baffle (103) are connected to the outer side of the head cover (101) through the rotating shaft mechanism (4) at the upper end of the head cover (101).

3. The high-speed digital micromirror device-based facial-lingual inspection 3D imaging apparatus according to claim 1, wherein the rotation axis mechanism (4) comprises a first rotation axis (401), a second rotation axis (402), and a connection axis (403); the first rotating shaft (401) and the second rotating shaft (402) are connected through the connecting shaft (403).

4. The high-speed digital micromirror device-based facial-lingual inspection 3D imaging device according to claim 1, wherein a back surface of the lamp ring (5) is provided with a lamp ring base (13); the lower end of the lamp ring base (13) is arranged on the inner bottom surface of the shading head cover (1) through a bracket (9); a power supply (8) and a control module (7) are arranged on the back of the bracket (9); the side surface of the control module (7) is connected with the controller (11) through an electric wire (10).