CN113976503B

CN113976503B - Bioengineering image analysis input device

Info

Publication number: CN113976503B
Application number: CN202111465043.3A
Authority: CN
Inventors: 刘磊; 李红艳; 李洁静; 段学习; 张洪强; 吴倩; 王楠; 宋晓晔; 王训; 陆泽阳
Original assignee: Cangzhou Technoical College
Current assignee: Cangzhou Technoical College
Priority date: 2021-12-03
Filing date: 2021-12-03
Publication date: 2023-03-14
Anticipated expiration: 2041-12-03
Also published as: CN113976503A

Abstract

The invention discloses a bioengineering image analysis input device, and relates to the technical field of bioengineering. This bioengineering image analysis input device, including the organism, the bottom fixed mounting of organism has the adaptor, the front of organism is provided with water conservancy diversion mechanism, water conservancy diversion mechanism's inboard is provided with cleans the mechanism, water conservancy diversion mechanism includes fixed block, air intake and arc guiding gutter, fixed block fixed mounting is in the front of organism, the surface at the fixed block is seted up to the air intake, the inboard at the fixed block is seted up to the arc guiding gutter, the arc guiding gutter meets with the air intake. The bioengineering image analysis input device sets up water conservancy diversion mechanism and wipes the mechanism, when the outside air of device flows, wipes the activity camera lens, has avoided the dust to adhere to on the activity camera lens surface, influences the definition of image analysis input device department input image.

Description

Bioengineering image analysis input device

Technical Field

The invention relates to the technical field of bioengineering, in particular to a bioengineering image analysis input device.

Background

Bioengineering, generally considered to be an emerging technology based on biological theory and technology, combining modern engineering technologies such as chemical engineering, machinery and electronic computers, and fully utilizing the latest achievements of molecular biology to consciously manipulate genetic materials, directionally modify organisms or their functions, create new species with ultra-distant characters in a short time, and then culture such "engineering bacteria" or "engineering cell strains" in a large scale through a proper bioreactor to produce a large amount of useful metabolites or exert their unique physiological functions.

When the bioengineering image analysis input device is in use, dust can adhere to the lens, and the dust adhesion can influence the definition of the input image, so that the difficulty of image analysis is increased.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides the bioengineering image analysis input device, the movable lens is wiped when air flows outside the device through the cooperation of the diversion mechanism and the wiping mechanism, and dust is prevented from being attached to the surface of the movable lens.

In order to achieve the purpose, the invention is realized by the following technical scheme: the bioengineering image analysis input device comprises a machine body, wherein an adapter is fixedly mounted at the bottom of the machine body, a flow guide mechanism is arranged on the front face of the machine body, and a wiping mechanism is arranged on the inner side of the flow guide mechanism.

Preferably, the guide mechanism comprises a fixing block, an air inlet and an arc-shaped guide groove, the fixing block is fixedly mounted on the front of the machine body, the air inlet is formed in the outer surface of the fixing block, the arc-shaped guide groove is formed in the inner side of the fixing block, and the arc-shaped guide groove is connected with the air inlet.

Preferably, the wiping mechanism comprises a fixed cylinder, a wiping piece and a moving piece, the fixed cylinder is fixedly inserted in the front of the fixed block, the wiping piece is arranged in the fixed cylinder, and the moving piece is arranged on the inner side of the fixed block.

Preferably, the wiper includes activity groove, activity lens, annular brush and support bar, the inboard at a fixed section of thick bamboo is seted up to the activity groove, activity lens movable mounting is in the inside in activity groove, annular brush fixed mounting is in the inside of a fixed section of thick bamboo, the annular brush contacts with the front of activity lens, the support bar passes through shell fragment fixed mounting at the inner wall in activity groove, the support bar meets with the activity lens.

Preferably, the moving part includes elasticity strip, activity strip, connecting strip and pulling piece, elasticity strip fixed mounting is at the surface of fixed section of thick bamboo, the one end of fixed section of thick bamboo is kept away from to activity strip fixed mounting at the elasticity strip, the section of thick bamboo wall of fixed section of thick bamboo is run through to the activity strip, the one end that the elasticity strip was kept away from to the activity strip contacts with movable lens, the one end that the movable lens was kept away from to the connecting strip fixed mounting at the activity strip, the one end that the movable strip was kept away from to the connecting strip runs through the section of thick bamboo wall of fixed section of thick bamboo and meets with movable lens, the pulling piece sets up the inboard at the fixed block.

Preferably, the pulling part comprises a pulling rope and a movable wind-shielding sheet, the pulling rope is movably mounted on the inner side of the fixed block, the pulling rope is movably connected with the connecting strip through a sleeving ring, one end, far away from the connecting strip, of the pulling rope penetrates into the arc-shaped flow guide groove, the movable wind-shielding sheet is movably mounted inside the arc-shaped flow guide groove, and the movable wind-shielding sheet is connected with the pulling rope.

The invention provides a bioengineering image analysis input device. The method has the following beneficial effects:

(1) This bioengineering image analysis input device sets up water conservancy diversion mechanism and wipes the mechanism, when the device outside air flows, wipes the activity camera lens, has avoided the dust to adhere to on the activity camera lens surface, influences the definition of image analysis input device department input image.

(2) This bioengineering image analysis input device, under the promotion of air current, draws a work, and activity windshield piece is in the activity of arc guiding gutter, drives the pulling rope and draws the connecting strip downwards, and during the stress of connecting strip department, the support bar is to the one end activity of keeping away from movable lens, and under the cooperation of connecting strip, movable lens is to activity groove one side slope, and the movable lens is wiped away to annular brush this moment, has avoided movable lens surface dust to adhere to, influences the use of device.

(3) This bioengineering image analysis input device, when the activity lens activity, the elastic restoring force effect of elasticity strip drives the support bar and moves repeatedly down, promotes the activity lens activity repeatedly when the support bar moves about, and then makes the activity lens constantly contact with the annular brush, makes the positive dust of activity lens clear away more completely.

(4) This bioengineering image analysis input device, when the connecting strip pulling activity lens was movable, along with the activity of connecting strip, the activity lens took place to rotate, has increased the area of contact of activity lens and annular brush, makes the range increase of cleaning of wiping mechanism, has improved the work efficiency of wiping mechanism.

(5) According to the bioengineering image analysis input device, when the movable lens moves, the supporting bar moves along with the movable lens, and the elastic sheet at the lower end of the supporting bar increases the moving frequency of the movable lens, so that the moving frequency of the movable lens is increased, and the speed of wiping dust by the annular brush is increased.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the fixing cylinder of the present invention;

FIG. 3 is an enlarged view of the structure of FIG. 2;

FIG. 4 is a schematic view of the structure of the fixing block according to the present invention;

FIG. 5 is a schematic view of the internal structure of the fixing block of the present invention;

FIG. 6 is an enlarged view of the structure of FIG. 5 at B according to the present invention.

In the figure: 1. a body; 2. an adapter; 3. a flow guide mechanism; 31. a fixed block; 32. an air inlet; 33. an arc-shaped diversion trench; 4. a wiping mechanism; 41. a fixed cylinder; 42. a wiper; 421. a movable groove; 422. a movable lens; 423. an annular brush; 424. a supporting strip; 43. a movable member; 431. an elastic strip; 432. a movable bar; 433. a connecting strip; 434. a pulling member; 4341. pulling the rope; 4342. a movable wind shield sheet.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the invention and are not to be construed as limiting the invention.

Referring to fig. 1-6, the present invention provides a technical solution: a bioengineering image analysis input device, includes organism 1, and the bottom fixed mounting of organism 1 has adaptor 2, and the front of organism 1 is provided with water conservancy diversion mechanism 3, and the inboard of water conservancy diversion mechanism 3 is provided with wiping mechanism 4.

The guide mechanism 3 comprises a fixed block 31, an air inlet 32 and an arc guide groove 33, the fixed block 31 is fixedly arranged on the front surface of the machine body 1, the air inlet 32 is arranged on the outer surface of the fixed block 31, the arc guide groove 33 is arranged on the inner side of the fixed block 31, and the arc guide groove 33 is connected with the air inlet 32.

The wiping mechanism 4 includes a fixed cylinder 41, a wiping member 42 and a movable member 43, the fixed cylinder 41 is fixedly inserted in the front of the fixed block 31, the wiping member 42 is disposed inside the fixed cylinder 41, the wiping member 42 includes a movable groove 421, a movable lens 422, an annular brush 423 and a support strip 424, the movable groove 421 is disposed inside the fixed cylinder 41, the movable lens 422 is movably mounted inside the movable groove 421, the annular brush 423 is fixedly mounted inside the fixed cylinder 41, the annular brush 423 is in contact with the front of the movable lens 422, the support strip 424 is fixedly mounted on the inner wall of the movable groove 421 through a resilient sheet, the movable member 424 is connected with the movable lens 422, the support strip 43 is disposed inside the fixed block 31, the movable member 43 includes a resilient strip 431, a movable strip 432, a connecting strip 433 and a pulling member 434, the resilient strip 431 is fixedly mounted on the outer surface of the fixed cylinder 41, the movable strip 432 is fixedly mounted at one end of the resilient strip 431, which is far away from the fixed cylinder 41, the movable strip 432 is connected with a wall of the fixed cylinder 41, the movable rod 432 is connected with a movable rod 4342, the end of the movable rod 433, the movable rod 432 is connected with a guide rope 4342, the movable rod 434, the movable rod 4342 is mounted inside the movable groove 43422, and the movable rod 4342, the movable rod 4342 is connected with the movable guide rail 43422, and the movable rod 43434343434343434343434, and the movable rod 43422, and the movable rod 43434343434343434343434343434, the movable rod 43434343422, the movable rod 434343434343434343434343422, the movable rod 43434343434, the movable rod 4343434343434343422, the movable rod 434342 is mounted inside the movable rod 43422, the movable rod 4342 is mounted on the movable rod 43422, the movable rod 4343434343434343422, the movable rod 4342.

When the device is used, the device body 1 is arranged at the image receiving position through the adapter 2, when air flows outside the device body 1, the air flow enters the arc-shaped diversion groove 33 from the air inlet 32, the pulling part 434 works under the pushing of the air flow, the movable wind shield 4342 moves in the arc-shaped diversion groove 33 to drive the pulling rope 4341 to pull the connecting strip 433 downwards, when the connecting strip 433 is stressed, the supporting strip 424 moves towards one end far away from the movable lens 422, the movable lens 422 inclines towards one side of the movable groove 421 under the matching of the connecting strip 433, at the moment, the annular brush 423 wipes the movable lens 422, the adhesion of dust on the surface of the movable lens 422 is avoided, the use of the device is influenced, when the movable lens 422 moves, the supporting strip 424 is driven to move repeatedly under the action of the elastic restoring force of the elastic strip 431, promote the activity of movable lens 422 repeatedly when support bar 424 moves about, and then make movable lens 422 constantly contact with annular brush 423, make the positive dust of movable lens 422 clear away more completely, when connecting bar 433 stimulates movable lens 422 to move about, along with the activity of connecting bar 433, movable lens 422 rotates, movable lens 422 has increased the area of contact of movable lens 422 with annular brush 423, make the range of cleaning mechanism 4 increase, the work efficiency of cleaning mechanism 4 has been improved, when movable lens 422 moves about, support bar 424 moves about along with it, the shell fragment of support bar 424 lower extreme makes its frequency of activity increase this moment, make movable lens 422's frequency of activity increase, the speed that annular brush 423 cleaned the dust has been accelerated.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered as the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.

Claims

1. A bioengineering image analysis input device, includes organism (1), its characterized in that: the bottom of the machine body (1) is fixedly provided with an adapter (2), the front surface of the machine body (1) is provided with a flow guide mechanism (3), and the inner side of the flow guide mechanism (3) is provided with a wiping mechanism (4);

the flow guide mechanism (3) comprises a fixed block (31), an air inlet (32) and an arc-shaped flow guide groove (33), the fixed block (31) is fixedly arranged on the front surface of the machine body (1), the air inlet (32) is formed in the outer surface of the fixed block (31), the arc-shaped flow guide groove (33) is formed in the inner side of the fixed block (31), and the arc-shaped flow guide groove (33) is connected with the air inlet (32);

the wiping mechanism (4) comprises a fixed cylinder (41), a wiping piece (42) and a movable piece (43), the fixed cylinder (41) is fixedly inserted in the front of the fixed block (31), the wiping piece (42) is arranged in the fixed cylinder (41), and the movable piece (43) is arranged on the inner side of the fixed block (31);

the wiping piece (42) comprises a movable groove (421), a movable lens (422), an annular brush (423) and a supporting strip (424), the movable groove (421) is formed in the inner side of the fixed cylinder (41), the movable lens (422) is movably arranged in the movable groove (421), the annular brush (423) is fixedly arranged in the fixed cylinder (41), the annular brush (423) is in contact with the front surface of the movable lens (422), the supporting strip (424) is fixedly arranged on the inner wall of the movable groove (421) through an elastic sheet, and the supporting strip (424) is connected with the movable lens (422);

the movable piece (43) comprises an elastic strip (431), a movable strip (432), a connecting strip (433) and a pulling piece (434), the elastic strip (431) is fixedly installed on the outer surface of the fixed cylinder (41), the movable strip (432) is fixedly installed at one end, away from the fixed cylinder (41), of the elastic strip (431), the movable strip (432) penetrates through the cylinder wall of the fixed cylinder (41), one end, away from the elastic strip (431), of the movable strip (432) is in contact with the movable lens (422), the connecting strip (433) is fixedly installed at one end, away from the movable lens (422), of the movable strip (432), one end, away from the movable strip (433), of the connecting strip (433) penetrates through the cylinder wall of the fixed cylinder (41) and is connected with the movable lens (422), and the pulling piece (434) is arranged on the inner side of the fixed block (31);

the pulling piece (434) comprises a pulling rope (4341) and a movable wind-blocking sheet (4342), the pulling rope (4341) is movably mounted on the inner side of the fixed block (31), the pulling rope (4341) is movably connected with the connecting strip (433) through a sleeving ring, one end, far away from the connecting strip (433), of the pulling rope (4341) penetrates into the arc-shaped diversion trench (33), the movable wind-blocking sheet (4342) is movably mounted inside the arc-shaped diversion trench (33), and the movable wind-blocking sheet (4342) is connected with the pulling rope (4341).