CN113993311A

CN113993311A - Sample monitoring equipment for artificial intelligence data acquisition

Info

Publication number: CN113993311A
Application number: CN202111197214.9A
Authority: CN
Inventors: 马翠花; 龙海侠; 刘天跃
Original assignee: Hainan Normal University
Current assignee: Hainan Normal University
Priority date: 2021-10-14
Filing date: 2021-10-14
Publication date: 2022-01-28
Anticipated expiration: 2041-10-14
Also published as: CN113993311B

Abstract

The invention discloses a sample monitoring device for artificial intelligent data acquisition, which structurally comprises a temperature monitor, a data display panel, a gas flowing mechanism and a heat dissipation window, wherein the data display panel is embedded in the middle of the front end face of the temperature monitor and is electrically connected with the data display panel, a communicating sheet swings to adjust the pipe diameter of the inner part of a flow guide pipe, the flowing speed of low-temperature gas is accelerated, the accuracy of the temperature monitor in monitoring the low-temperature gas is ensured, the low-temperature gas forms water drops when being heated, the water drops are thrown into a water collecting tank in the swinging process of the communicating sheet, a large amount of water drops formed when being heated are collected into water flow in the long-time continuous low-temperature monitoring process, a gravity shaft on the outer side of a water permeable plate slides in an arc shape in the bent part of the bent pipe, so that the water permeable plate swings in the bent part of the bent pipe, the discharging speed of the water drops is accelerated, and the water drops are prevented from entering the temperature monitor to be affected with damp, the accuracy of the temperature monitor for temperature monitoring is ensured.

Description

Sample monitoring equipment for artificial intelligence data acquisition

Technical Field

The invention relates to the field of artificial intelligence, in particular to sample monitoring equipment for artificial intelligence data acquisition.

Background

The artificial intelligence refers to the ability of a computer system, which can fulfill the complex task that can only be completed by human intelligence originally, the sample acquired by the artificial intelligence needs to be stored at low temperature, and the temperature of the sample needs to be monitored by monitoring equipment during the low-temperature storage process, but because the monitoring equipment needs to discharge the gas temperature around the sample stored at low temperature into the monitoring equipment during the temperature monitoring process, the stored temperature can be known, when the gas temperature flows into the monitoring equipment, the monitoring equipment generates a certain amount of heat during the working process, the low-temperature gas contacts with the heat, so that the sampling and storing temperature at the monitoring part has a certain error, meanwhile, the low-temperature gas is easily atomized by preheating, the atomization can form tiny water drops, and the water drops can damp the inside of the monitoring equipment, the accuracy of the monitoring equipment for monitoring the temperature is influenced.

Disclosure of Invention

The technical scheme adopted by the invention for realizing the technical purpose is as follows: this artificial intelligence data acquisition's sample supervisory equipment, its structure includes temperature monitor, data display panel, gas flow mechanism, heat dissipation window, data display panel has been inlayed at the preceding terminal surface middle part of temperature monitor and the electricity is connected, gas flow mechanism establishes in temperature monitor upper right end, the heat dissipation window has been inlayed to temperature monitor right side terminal surface below, gas flow mechanism includes connecting pipe, water conservancy diversion mechanism, plastic strip, drainage mechanism, shell, the connecting pipe inlays in the upper right end of shell to water conservancy diversion mechanism link up with the connecting pipe mutually, the connecting pipe lower extreme is connected with plastic strip upper end, drainage mechanism upper end inlays admittedly and installs at water conservancy diversion mechanism middle part lower extreme and link up mutually, the shell inlays in temperature monitor upper right end, plastic strip lower extreme is connected with water conservancy diversion mechanism lower right end.

As a further improvement of the invention, the flow guide mechanism comprises a flow guide pipe, a sealing sheet, an adjusting mechanism and a limiting mechanism, wherein the right end of the flow guide pipe is fixed with and communicated with the left end of the connecting pipe, the sealing sheet is welded at the upper end of the flow guide pipe, the inner part of the upper end of the flow guide pipe is hinged with the upper end of the adjusting mechanism, the lower end of the adjusting mechanism is abutted against the inner part of the upper end of the limiting mechanism, the lower end of the limiting mechanism is welded at the lower end of the inner part of the flow guide pipe, the upper end of the drainage mechanism is fixedly embedded at the lower end of the middle part of the flow guide pipe and communicated with the drainage mechanism, and the adjusting mechanism and the limiting mechanism are respectively provided with five parts which are connected in pairs.

As a further improvement of the invention, the adjusting mechanism comprises a rotating block, a torsion shaft, a communicating piece, an air hole and a flowing groove, wherein the inside of the rotating block is hinged with the inside of the upper end of the flow guide pipe through the torsion shaft, the lower end of the rotating block is welded with the middle end of the top of the communicating piece, the air hole penetrates through the inside of the communicating piece, the inside of the air hole is communicated with the flowing groove, the flowing groove is embedded in the communicating piece, the lower end of the communicating piece is abutted against the inside of the upper end of the limiting mechanism, and the communicating piece is in a semi-disc structure, and the outer side of the communicating piece is in a vertical angle.

As a further improvement of the invention, the limiting mechanism comprises a limiting baffle, a water collecting tank, a sliding shaft and a sliding rail, the lower end of the limiting baffle is welded with the interior of the lower end of the flow guide pipe, the water collecting tank is welded on the left end face of the limiting baffle, the sliding shaft is arranged at the lower end of the communicating piece and is slidably mounted in the sliding rail, the sliding rail is fixedly mounted at the upper end of the interior of the water collecting tank, the water collecting tank and the sliding rail are both in an arc structure, and the center of the arc sliding rail and the axis of the torsion shaft are located at the same point.

As a further improvement of the invention, the drainage mechanism comprises a water inlet hopper, a bending pipe, a gravity shaft, a permeable plate, a pushing mechanism and an opening and closing plate, wherein the upper end of the water inlet hopper is fixedly embedded at the lower end of the middle part of the flow guide pipe and communicated with the lower end of the middle part of the flow guide pipe, the lower end of the water inlet hopper is welded with the left upper end of the bending pipe, the gravity shaft is arranged in the upper end of the bending pipe in a sliding manner and is arranged at the outer side end of the permeable plate, the pushing mechanism is arranged at the inner right end of the bending pipe, the right end of the pushing mechanism is abutted against the left end face of the opening and closing plate, the gravity shaft is totally provided with two parts which are respectively arranged at the upper end and the lower end of the bent part of the bending pipe, and the two gravity shafts are respectively fixed with the two ends of the outer side of the disc-shaped permeable plate.

As a further improvement of the invention, the pushing mechanism comprises a collision ball, a push rod, a guide tube, a spring and a guide block, wherein the collision ball is welded at the left end of the push rod, the spring is arranged at the outer side of the right end of the push rod, the push rod is arranged in the guide tube in a clearance fit manner, the guide block is slidably arranged in the guide tube, the guide block is welded at the right end of the push rod, the collision ball, the push rod and the spring are respectively arranged in a bilateral symmetry manner, and the two push rods are respectively welded with the end surfaces of the left side and the right side of the guide block.

The invention has the beneficial effects that:

1. inside low-temperature gas entered into the honeycomb duct, the mediation piece swung, adjusted the inside pipe diameter size of honeycomb duct, changeed low-temperature gas and also flowed inside the bleeder vent for low-temperature gas's flow speed ensures the accuracy of temperature monitor to low-temperature gas control, and low-temperature gas meets heat and forms the drop of water, and the mediation piece carries out wobbling in-process, and inside the drop of water got rid of the water catch bowl, avoided the drop of water to enter into temperature monitor.

2. In the low temperature monitoring process of long-time continuity, a large amount of beads that meet the hot formation collect and be rivers, and the gravity axle in the porous disk outside is in the inside arc of buckling of the pipe department of buckling and is carried out the arc and slide to make the porous disk buckle the inside swing of department of buckling, thereby accelerate the exhaust rate of beads, avoid the beads to enter into the inside emergence of temperature monitor and wet, ensure the accuracy of temperature monitor to temperature monitor.

Drawings

Fig. 1 is a schematic structural diagram of a sample monitoring device for artificial intelligence data acquisition according to the present invention.

Fig. 2 is a schematic diagram of the internal structure of a gas flow mechanism according to the present invention.

Fig. 3 is a schematic view of an internal structure of a flow guide mechanism according to the present invention.

Fig. 4 is a schematic side perspective view of an adjusting mechanism according to the present invention.

Fig. 5 is a schematic cross-sectional structural view of a limiting mechanism according to the present invention.

FIG. 6 is an enlarged view of the interior of a drainage mechanism according to the present invention.

Fig. 7 is a schematic view of an internal structure of a pusher jack according to the present invention.

In the figure: temperature monitor-1, data display panel-2, gas flow mechanism-3, heat dissipation window-4, connecting pipe-31, flow guide mechanism-32, plastic strip-33, water discharge mechanism-34, shell-35, flow guide pipe-321, sealing sheet-322, adjusting mechanism-323, limiting mechanism-324, rotating block-23 a, torsion shaft-23 b, adjusting sheet-23 c, air vent-23 d, flow groove-23 e, limiting baffle-24 a, water collecting tank-24 b, sliding shaft-24 c, sliding rail-24 d, water inlet bucket-341, bending pipe-342, gravity shaft-343, water permeable plate-344, pushing mechanism-345, opening and closing sheet-346, collision ball-45 a, push rod-45 b, A guide tube-45 c, a spring-45 d and a guide block-45 e.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

example 1:

as shown in figures 1 to 5:

the invention relates to a sample monitoring device for artificial intelligent data acquisition, which structurally comprises a temperature monitor 1, a data display panel 2, a gas flow mechanism 3 and a heat dissipation window 4, wherein the data display panel 2 is embedded in the middle of the front end face of the temperature monitor 1 and is electrically connected with the data display panel, the gas flow mechanism 3 is arranged at the upper right end of the temperature monitor 1, the heat dissipation window 4 is embedded below the right end face of the temperature monitor 1, the gas flow mechanism 3 comprises a connecting pipe 31, a flow guide mechanism 32, a plastic strip 33, a drainage mechanism 34 and a shell 35, the connecting pipe 31 is embedded at the upper right end of the shell 35, the flow guide mechanism 32 is communicated with the connecting pipe 31, the lower end of the connecting pipe 31 is connected with the upper end of the plastic strip 33, the upper end of the drainage mechanism 34 is fixedly installed at the lower middle part of the flow guide mechanism 32 and is communicated with the lower end of the flow guide mechanism, the shell 35 is embedded at the upper right end of the temperature monitor 1, the lower end of the plastic strip 33 is connected with the right lower end of the flow guide mechanism 32.

Wherein, water conservancy diversion mechanism 32 includes honeycomb duct 321, gasket 322, adjustment mechanism 323, stop gear 324, honeycomb duct 321 right-hand member is fixed and link up mutually with connecting pipe 31 left end, the welding of honeycomb duct 321 upper end has gasket 322, honeycomb duct 321 upper end is inside to be articulated mutually with adjustment mechanism 323 upper end, adjustment mechanism 323 lower extreme is inconsistent with stop gear 324 upper end is inside, stop gear 324 lower extreme welds in the inside lower extreme of honeycomb duct 321, drainage mechanism 34 upper end is inlayed admittedly and is installed at honeycomb duct 321 middle part lower extreme and link up mutually, adjustment mechanism 323 and stop gear 324 all are equipped with five to two liang of being connected do benefit to stop gear 324 and carry out spacing fender to every adjustment mechanism 323 lower extreme to ensure that adjustment mechanism 323 is the slope installation, with higher speed low temperature gas's velocity of flow.

Wherein the adjusting mechanism 323 comprises a rotating block 23a, a torsion shaft 23b, an adjusting sheet 23c, an air hole 23d and a flow groove 23e, the inside of the rotating block 23a is hinged with the inside of the upper end of the guide pipe 321 through a torsion shaft 23b, the lower end of the rotating block 23a is welded with the middle end of the top of the communicating sheet 23c, the communicating sheet 23c is internally provided with a vent hole 23d, and the inside of the ventilation hole 23d is communicated with the flow groove 23e, the flow groove 23e is embedded in the communicating piece 23c, the lower end of the communicating sheet 23c is abutted against the inner part of the upper end of the limiting mechanism 324, the communicating sheet 23c is in a semi-disc structure, and the outer side is vertical, which is beneficial to the automatic angle swing adjustment in the limiting mechanism 324 according to the lower end of the air pressure adjusting piece 23c of the low-temperature gas, thereby adjusting the inner pipe diameter of the draft tube 321 and ensuring high-speed flow of the low-temperature gas.

The limiting mechanism 324 comprises a limiting baffle plate 24a, a water collecting tank 24b, a sliding shaft 24c and a sliding rail 24d, the lower end of the limiting baffle plate 24a is welded with the inside of the lower end of the flow guide pipe 321, the water collecting tank 24b is welded on the left end face of the limiting baffle plate 24a, the sliding shaft 24c is arranged at the lower end of the communicating piece 23c, the sliding shaft 24c is slidably mounted inside the sliding rail 24d, the sliding rail 24d is fixedly mounted at the upper end inside the water collecting tank 24b, the water collecting tank 24b and the sliding rail 24d are both in an arc structure, the circle center of the arc sliding rail 24d is located at the same point as the axle center of the torsion shaft 23b, the lower end of the communicating piece 23c is ensured to perform stable arc-shaped swing at the upper end inside the water collecting tank 24b, and the preheated water beads are thrown into the inside the water collecting tank 24 b.

The specific use mode and function of the embodiment are as follows:

in the invention, the connecting pipe 31 is connected with the low-temperature gas stored in the collected sample, the low-temperature gas enters the flow guide pipe 321, the rotating block 23a rotates around the torsion shaft 23b after receiving air pressure, so that the communicating piece 23c swings, the pipe diameter inside the flow guide pipe 321 is adjusted, the communicating piece 23c slides inside the slide rail 24d through the slide shaft 24c in the swinging process, the swinging stability of the communicating piece 23c is improved, the low-temperature gas also flows inside the air holes 23d, so that the flowing speed of the low-temperature gas is accelerated, the accuracy of the temperature monitor 1 for monitoring the low-temperature gas is ensured, the low-temperature gas forms water drops when being heated, the water drops flow downwards inside the flowing groove 23e, and the water drops are thrown into the water collection groove 24b and pass through the through holes at the lower end inside the water collection groove 24b in the swinging process of the communicating piece 23c, the water drops are discharged downwards and enter the water discharging mechanism 34, so that the water drops are prevented from entering the temperature monitor 1.

Example 2:

as shown in fig. 6 to 7:

wherein the drainage mechanism 34 comprises a water inlet bucket 341, a bent pipe 342, a gravity shaft 343, a water permeable plate 344, a pushing mechanism 345 and an opening and closing sheet 346, the upper end of the water inlet funnel 341 is fixedly embedded at the lower end of the middle part of the draft tube 321 and communicated with the draft tube, the lower end of the water inlet hopper 341 is welded with the upper left end of the bent pipe 342, a gravity shaft 343 is slidably mounted inside the upper end of the bent pipe 342, and a gravity shaft 343 is provided at the outer end of the permeable plate 344, the pushing mechanism 345 is installed at the right end inside the bent pipe 342, the right end of the pushing mechanism 345 is contacted with the left end face of the opening-closing sheet 346, two gravity shafts 343 are arranged, which are respectively arranged at the upper and lower ends of the bending part of the bending pipe 342, and two gravity shafts 343 are respectively fixed with the two ends of the outer side of the disc-shaped water permeable plate 344, which is beneficial to driving the water permeable plate 344 to swing at the bending part of the bending pipe 342, thereby accelerating the discharging speed of water drops.

Wherein, advancing mechanism 345 includes collision ball 45a, push rod 45b, stand pipe 45c, spring 45d, guide block 45e, collision ball 45a welds in push rod 45b left end to push rod 45b right-hand member outside is equipped with spring 45d, push rod 45b adopts clearance fit to install inside stand pipe 45c, guide block 45e slidable mounting is inside at stand pipe 45c, guide block 45e welds in push rod 45b right-hand member, collision ball 45a, push rod 45b and spring 45d all are equipped with two and are bilateral symmetry, and two push rods 45b weld with the stand block 45e left and right sides terminal surface respectively, do benefit to two push rods 45b and carry out reciprocal lateral shifting inside stand pipe 45c to promote switching piece 346 and carry out automatic switching, discharge the drop of water during the opening, avoid outside dust to get into during the closure.

The specific use mode and function of the embodiment are as follows:

in the invention, water drops flow from the inside of the water inlet hopper 341 to the inside of the bent pipe 342, during the long-time continuous low-temperature monitoring process, a large amount of water drops formed by heating are collected into water flow, the water permeable plate 344 is pressed down by water pressure, at the moment, the water permeable plate 344 swings in the bent part of the bent pipe 342 through the gravity shaft 343 at the outer side of the water permeable plate 344, so that the water permeable plate 344 swings in the bent part of the bent pipe 342, the discharge speed of the water drops is accelerated, the water flow is prevented from flowing back, the water permeable plate 344 swings downwards and collides with the collision ball 45a, the push rod 45b elastically moves transversely in the guide pipe 45c through the elastic potential energy of the spring 45d, the upper end of the opening and closing piece 346 is fixed with the plastic strip 33, so that the collision ball 45a at the right end pushes the opening and closing piece 346 to open and discharge water, and the opening and closing piece 346 automatically closes when the collision ball 45a resets, prevent that outside dust from getting into, avoid the drop of water to enter into temperature monitor 1 inside and take place to wet, ensure temperature monitor 1 to the accuracy of temperature monitoring.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention to achieve the above technical effects.

Claims

1. The utility model provides an artificial intelligence data acquisition's sample supervisory equipment, its structure includes temperature monitor (1), data display panel (2), gas flow mechanism (3), radiator window (4), data display panel (2) and electricity are inlayed at temperature monitor (1) preceding terminal surface middle part, gas flow mechanism (3) are established in temperature monitor (1) upper right end, radiator window (4), its characterized in that have been inlayed to temperature monitor (1) right side terminal surface below:

gas flow mechanism (3) include connecting pipe (31), water conservancy diversion mechanism (32), plastic strip (33), drainage mechanism (34), shell (35), connecting pipe (31) are inlayed in shell (35) upper right end to water conservancy diversion mechanism (32) link up with connecting pipe (31) mutually, connecting pipe (31) lower extreme is connected with plastic strip (33) upper end, drainage mechanism (34) upper end is inlayed and is installed at water conservancy diversion mechanism (32) middle part lower extreme and link up mutually, shell (35) are inlayed in temperature monitor (1) upper right end, plastic strip (33) lower extreme is connected with water conservancy diversion mechanism (32) lower right end.

2. The artificial intelligence data collection sample monitoring device of claim 1, wherein: the water conservancy diversion mechanism (32) includes honeycomb duct (321), gasket (322), adjustment mechanism (323), stop gear (324), honeycomb duct (321) right-hand member is fixed and link up mutually with connecting pipe (31) left end, honeycomb duct (321) upper end welding has gasket (322), honeycomb duct (321) upper end is inside to be articulated mutually with adjustment mechanism (323) upper end, adjustment mechanism (323) lower extreme and stop gear (324) upper end are inside inconsistent, stop gear (324) lower extreme welds in honeycomb duct (321) inside lower extreme, drainage mechanism (34) upper end is embedded admittedly and is installed at honeycomb duct (321) middle part lower extreme and link up mutually.

3. The artificial intelligence data collection sample monitoring device of claim 2, wherein: adjustment mechanism (323) is including turning block (23 a), torsion shaft (23 b), transfer piece (23 c), bleeder vent (23 d), flowing groove (23 e), turning block (23 a) is inside to be articulated mutually through torsion shaft (23 b) and honeycomb duct (321) upper end, turning block (23 a) lower extreme and transfer piece (23 c) top middle-end mutually weld, transfer piece (23 c) inside to run through bleeder vent (23 d) to bleeder vent (23 d) inside link up with flowing groove (23 e), flowing groove (23 e) inlay inside transfer piece (23 c), transfer piece (23 c) lower extreme and stop gear (324) upper end inside inconsistent.

4. An artificial intelligence data collection sample monitoring device as claimed in claim 3, wherein: stop gear (324) include limit baffle (24 a), water catch bowl (24 b), sliding shaft (24 c), slide rail (24 d), limit baffle (24 a) lower extreme welds mutually with honeycomb duct (321) lower extreme is inside to water catch bowl (24 b) welds in limit baffle (24 a) left side terminal surface, establish at the piece (23 c) lower extreme of transferring to sliding shaft (24 c) slidable mounting is inside in slide rail (24 d), slide rail (24 d) fixed mounting is in the inside upper end of water catch bowl (24 b).

5. The artificial intelligence data collection sample monitoring device of claim 2, wherein: the drainage mechanism (34) comprises a water inlet hopper (341), a bent pipe (342), a gravity shaft (343), a water permeable plate (344), a pushing mechanism (345) and a switching piece (346), wherein the upper end of the water inlet hopper (341) is fixedly installed at the lower end of the middle part of the flow guide pipe (321) and communicated with the lower end of the middle part of the flow guide pipe (321), the lower end of the water inlet hopper (341) is welded with the upper left end of the bent pipe (342), the gravity shaft (343) is installed inside the upper end of the bent pipe (342) in a sliding mode, the gravity shaft (343) is arranged at the outer side end of the water permeable plate (344), the pushing mechanism (345) is installed at the right end inside the bent pipe (342), and the right end of the pushing mechanism (345) is abutted to the left end face of the switching piece (346).

6. The artificial intelligence data collection sample monitoring device of claim 5, wherein: advancing mechanism (345) is including colliding ball (45 a), push rod (45 b), stand pipe (45 c), spring (45 d), guide block (45 e), collide ball (45 a) and weld in push rod (45 b) left end to push rod (45 b) right-hand member outside is equipped with spring (45 d), push rod (45 b) adopt clearance fit to install inside stand pipe (45 c), inside stand pipe (45 c) is installed in stand pipe (45 e) slidable mounting, guide block (45 e) weld in push rod (45 b) right-hand member.