CN114951144B - Based on spout STREAMING intelligent instrument production is with inside dust clean-up equipment - Google Patents

Abstract

The invention relates to the technical field of dust cleaning of intelligent instruments and meters. The invention relates to an internal dust cleaning device for production of intelligent instruments based on jet flow. The intelligent instrument and meter cleaning device comprises a fixing device and a cleaning device arranged at the top of the fixing device, wherein the fixing device is used for fixing the position of an intelligent instrument and meter, and the cleaning device comprises a pressing mechanism. According to the invention, before the optical lens is fixed, dust around the intelligent instrument shell is blown clean under the action of the cleaning mechanism, and when the optical lens moves to the inside of the intelligent instrument shell, the dust in the intelligent instrument shell is blown clean, when the optical lens is fixed, the pressing mechanism and the cleaning mechanism are matched to clamp and fix the optical lens, and the dust on the surface of the optical lens is cleaned, and meanwhile, the cleaning mechanism cleans the dust in the surrounding environment.

Description

Based on spout STREAMING intelligent instrument production is with inside dust clean-up equipment

Technical Field

The invention relates to the technical field of dust cleaning of intelligent instruments and meters, in particular to internal dust cleaning equipment for production of intelligent instruments and meters based on jet flow.

Background

The instrument is an appliance or equipment for detecting, measuring, observing and calculating various physical quantities, material compositions, physical parameters and the like, and the instrument can also have the functions of automatic control, alarming, signal transmission, data processing and the like, such as a pneumatic adjusting instrument and an electric adjusting instrument which are used in the automatic control of the industrial production process, and a distributed instrument control system also belong to the instruments, in the existing intelligent instrument, an optical lens is very common, the optical lens is required to avoid dust during production, the imaging effect is seriously influenced by the dust, when the optical lens is installed, the dust is required to be prevented from entering the inside of the intelligent instrument and the surface of the optical lens, so the dust cleaning treatment is required to be carried out on the inside of the intelligent instrument and the optical lens during installation, and the common installation method has inevitable dust in the working environment, and the operator is inevitably in direct contact with the optical lens when mounting, which results in dust around the optical lens.

Disclosure of Invention

The invention aims to provide internal dust cleaning equipment for production of a jet-flow-based intelligent instrument, so as to solve the problems in the background technology.

In order to achieve the purpose, the internal dust cleaning equipment for the production of the jet-flow type intelligent instrument comprises a fixing device and a cleaning device arranged at the top of the fixing device, wherein the fixing device is used for fixing the position of the intelligent instrument, the cleaning device comprises a pressing mechanism, the pressing mechanism comprises an output pipe, a cleaning groove is formed in the side wall of the output pipe, the cleaning groove penetrates through the output pipe, a flow guide structure is arranged inside the output pipe, when one end of the output pipe is not attached to an optical lens, the flow guide structure guides air flow to be sprayed out from the end part of the output pipe, when one end of the output pipe is attached to the optical lens, the flow guide structure guides the air flow to be sprayed out from the cleaning groove, a cleaning mechanism is arranged on one side of the output pipe, the cleaning device comprises an output sleeve, a leakage groove is formed in the side wall of the output sleeve, and a guide structure is arranged inside the output sleeve, when one end of the output sleeve is not attached to the optical lens, the guide structure guides the air flow in the output sleeve to be sprayed out from the end part of the output sleeve and the leakage groove, after one end of the output sleeve is attached to the optical lens, the guide structure guides the air flow in the output sleeve to be sprayed out from the leakage groove, pumping pressure structures are arranged on one sides of the output pipe and the output sleeve, and the pumping pressure structures are used for pumping the air flow to the output pipe and the output sleeve.

As a further improvement of the technical scheme, the water conservancy diversion structure includes flexible cover, flexible cover slides and sets up in the inner wall of output tube, the air channel has been seted up to flexible cover's lateral wall, the air channel runs through flexible cover, when the one end of output tube and optical lens laminating, the outer wall of air channel and the inner wall in clearance groove coincide, the one end fixedly connected with expanding spring of flexible cover, expanding spring's one end and output tube fixed connection, the sliding tray has been seted up to flexible cover's inside, the inside slip of sliding tray is provided with airtight cover, when flexible cover and optical lens laminating, airtight cover gives airtightly with the air channel.

As a further improvement of the technical scheme, one end position fixedly connected with sliding toothed plate of airtight cover both sides, one side meshing of sliding toothed plate has the gear, gear and flexible cover rotate to be connected, one side meshing of gear has fixed toothed plate, fixed toothed plate and output tube fixed connection.

As a further improvement of the technical scheme, the guide structure comprises a sliding sleeve, the sliding sleeve is arranged on the inner wall of the output sleeve in a sliding mode, a leakage hole is formed in the side wall of the sliding sleeve, a cleaning spring is fixedly connected to one end of the sliding sleeve, and one end of the cleaning spring is fixedly connected with the output sleeve.

As a further improvement of the technical solution, the guiding structure further includes a baffle, when one end of the output sleeve is attached to the optical lens, the baffle seals one end of the sliding sleeve, one end of the baffle is fixedly connected to a sealing frame, a receiving groove is formed in one side of the inner portion of the output sleeve, the sealing frame is slidably disposed in the receiving groove, one end of the sealing frame is fixedly connected to a sealing spring, and one end of the sealing spring is fixedly connected to the receiving groove.

As a further improvement of this technical scheme, the inside of output cover is equipped with positioning mechanism, positioning mechanism includes the wedge, wedge and airtight frame joint cooperation, the bottom fixedly connected with crane of wedge, the bottom fixedly connected with location spring of wedge, location spring's bottom and output cover fixed connection, one side of crane is equipped with the wedge, the one end fixedly connected with drive lever of wedge, when the small opening removed to the inside of drive lever, the one end of small opening and the one end laminating of drive lever.

As a further improvement of the technical scheme, the pumping pressure structure comprises an air guide pipe, one end of the air guide pipe is fixedly connected with the output pipe, and the bottom end of the air guide pipe is fixedly connected with an air delivery pump.

As a further improvement of the technical scheme, the pumping structure further comprises an input pipe, one end of the input pipe is fixedly connected with the output sleeve, and the bottom end of the input pipe is fixedly connected with a gas making pump.

As a further improvement of this technical scheme, fixing device includes fixed establishment, fixed establishment includes the base, the gas transmission pump slides and sets up in one side at base top, the system air pump slides and sets up in the opposite side at base top, one side of gas transmission pump is equipped with fixed telescopic link, fixed telescopic link is fixed to be set up in the top of base, the piston rod and the gas transmission pump fixed connection of fixed telescopic link, one side of system air pump is equipped with the slip telescopic link, the piston rod and the system air pump fixed connection of slip telescopic link.

As a further improvement of this technical scheme, the top of base is equipped with fixture, fixture includes two grip blocks, one side fixedly connected with supporting rod of grip block, one side of grip block articulates there is the dead lever, the bottom and the base fixed connection of dead lever, the cooperation of pegging graft in the bottom of supporting rod has the dwang, the top fixedly connected with activity spring of dwang, activity spring's one end and supporting rod fixed connection, one side of dwang is equipped with the lifter plate, lifter plate and dwang rotate to be connected, the bottom fixedly connected with inserted bar of lifter plate, the jack has been seted up at the top of base, inserted bar and jack cooperation of pegging graft, the bottom fixedly connected with clamping spring of lifter plate.

Compared with the prior art, the invention has the beneficial effects that:

1. this based on in inside dust clean-up equipment is used in production of efflux formula intelligent instrument, before fixed optical lens, make dust around the intelligent instrument shell blow clean under clean mechanism's effect, and when removing to the inside of intelligent instrument shell, blow clean its inside dust, when fixed optical lens, pressing means and clean mechanism cooperation give the centre gripping with optical lens and fix, and give the dust on optical lens surface clean-up, after installing optical lens, pressing means lasts for a thrust of optical lens, and clean mechanism no longer gives optical lens thrust, be convenient for to optical lens's firm, clean mechanism cleans totally to the dust of surrounding environment again simultaneously, compare in common mounting method, it has attached to the dust when installing optical lens to have removed from.

2. This based on inside dust cleaning equipment is used in production of efflux formula intelligent instrument, avoid when installation optical lens, operator's hand direct contact to optical lens's surface to at the in-process of installation, change the direction of blowing of air current according to the change of positional relation between output tube, flexible cover and output cover, the slip cover, accomplish the inside clearance to optical lens and intelligent instrument meter case.

Drawings

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

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

FIG. 3 is a schematic structural view of the securing mechanism of the present invention;

FIG. 4 is a schematic structural view of the securing mechanism of the present invention;

FIG. 5 is a schematic view of the cleaning apparatus of the present invention;

FIG. 6 is a schematic structural diagram of a pressing mechanism according to the present invention;

FIG. 7 is a second schematic structural view of the pressing mechanism of the present invention;

FIG. 8 is a schematic view of the cleaning mechanism of the present invention;

FIG. 9 is a second schematic structural view of the cleaning mechanism of the present invention;

FIG. 10 is a third schematic view of the cleaning mechanism of the present invention;

fig. 11 is a schematic structural diagram of the positioning mechanism of the present invention.

The various reference numbers in the figures mean:

1. a fixing device;

11. a fixing mechanism; 111. a base; 112. fixing the telescopic rod; 113. fixing the rod; 114. sliding the telescopic rod; 115. a jack; 12. a clamping mechanism; 121. inserting a rod; 122. a clamping spring; 123. a lifting plate; 124. rotating the rod; 125. a movable spring; 126. a clamping rod; 127. a clamping plate;

2. a cleaning device;

21. a pressing mechanism; 211. an air delivery pump; 212. an air duct; 213. an output pipe; 2131. a sliding groove; 214. cleaning the tank; 215. a telescopic sleeve; 2151. a tension spring; 216. a vent groove; 217. sealing the sleeve; 2171. a sliding toothed plate; 218. a gear; 219. a fixed toothed plate; 22. a cleaning mechanism; 221. preparing an air pump; 222. an input tube; 223. an output sleeve; 2231. accommodating a tank; 224. a leak groove; 225. a sliding sleeve; 226. a leak hole; 227. cleaning the spring; 228. a baffle plate; 229. a hermetic frame; 2291. a sealing spring; 23. a positioning mechanism; 231. a driving lever; 232. a wedge plate; 233. a lifting frame; 234. a positioning spring; 235. a wedge block.

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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the equipment or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

Example 1

Referring to fig. 1 to 11, the present embodiment aims to provide an internal dust cleaning apparatus for jet-flow-based intelligent instrument and meter production, in view of the need of cleaning and fixing an optical lens during installation, including a fixing device 1 and a cleaning device 2 disposed on the top of the fixing device 1, where the fixing device 1 is used to fix a position of an intelligent instrument and meter, the cleaning device 2 includes a pressing mechanism 21, the pressing mechanism 21 includes an output tube 213, the output tube 213 is used to assist in fixing the position of the optical lens, a cleaning groove 214 is disposed on a side wall of the output tube 213, the cleaning groove 214 is used to guide an air flow inside the output tube 213 to a side wall position of the output tube 213, the cleaning groove 214 penetrates through the output tube 213, a flow guiding structure is disposed inside the output tube 213, and when one end of the output tube 213 is not attached to the optical lens, the flow guiding structure guides the air flow to be ejected from an end of the output tube 213, when one end of the output pipe 213 is attached to the optical lens, the flow guiding structure guides the air flow to be ejected from the cleaning groove 214;

the flow guide structure comprises a telescopic sleeve 215, the telescopic sleeve 215 is used for sealing a cleaning groove 214, the telescopic sleeve 215 is arranged on the inner wall of an output pipe 213 in a sliding manner, a vent groove 216 is formed in the side wall of the telescopic sleeve 215, the vent groove 216 is used for enabling air flow in the output pipe 213 to flow to the position of the cleaning groove 214, the vent groove 216 penetrates through the telescopic sleeve 215, when one end of the output pipe 213 is attached to an optical lens, the outer wall of the vent groove 216 is matched with the inner wall of the cleaning groove 214, one end of the telescopic sleeve 215 is fixedly connected with a telescopic spring 2151, the telescopic spring 2151 is used for pushing the telescopic sleeve 215, and one end of the telescopic spring 2151 is fixedly connected with the output pipe 213;

a sliding groove 2131 is formed in the telescopic sleeve 215, a sealing sleeve 217 is arranged in the sliding groove 2131 in a sliding mode, the sliding groove 2131 is used for determining the moving track of the sealing sleeve 217, and when the telescopic sleeve 215 is not attached to the optical lens, the sealing sleeve 217 seals the vent groove 216;

one end of the two sides of the sealing sleeve 217 is fixedly connected with a sliding toothed plate 2171, the sliding toothed plate 2171 is used for driving the sealing sleeve 217 to slide, one side of the sliding toothed plate 2171 is meshed with a gear 218, the gear 218 is used for driving the sliding toothed plate 2171 to slide, the gear 218 is rotationally connected with the telescopic sleeve 215, one side of the gear 218 is meshed with a fixed toothed plate 219, the fixed toothed plate 219 is used for enabling the gear 218 to rotate when sliding, and the fixed toothed plate 219 is fixedly connected with the output pipe 213;

when one end of the telescopic sleeve 215 is not attached to the optical lens, under the action of the elastic force of the telescopic spring 2151, the telescopic sleeve 215 is in a position for sealing the cleaning groove 214, at the moment, the sealing sleeve 217 is also in a position for sealing the vent groove 216, after the air flow enters the output pipe 213, because the cleaning groove 214 and the vent groove 216 are in a sealed state, the air flow is directly sprayed out along the inner walls of the telescopic sleeve 215 and the output pipe 213, the air flow can directly wash the side wall of the optical lens, and dust on the surface of the optical lens is washed out;

when one end of the output pipe 213 is attached to the optical lens, the telescopic sleeve 215 is pressed by the optical lens to compress the elastic force of the telescopic spring 2151 to slide towards the inside of the output pipe 213, when the telescopic sleeve 215 slides towards the inside of the output pipe 213, the outer wall of the vent groove 216 gradually fits the inner wall of the cleaning groove 214, meanwhile, the gear 218 moves at one side of the fixed toothed plate 219, under the cooperation of the fixed toothed plate 219 and the gear 218, the gear 218 starts to rotate, the gear 218 drives the sliding toothed plate 2171, the sliding toothed plate 2171 drives the sealing sleeve 217 to slide in the sliding groove 2131, the sealing of the vent groove 216 is released, because one end of the output pipe 213 is attached to the optical lens and is blocked, the air flow flows to the periphery of the side wall of the output pipe 213 through the vent groove 216 and the cleaning groove 214, the air flow impacts the environment around the optical lens, and dust in the environment is prevented from falling to the surface of the optical lens and the inside of the intelligent instrument and meter during the installation of the optical lens, meanwhile, when the air flow is in the output pipe 213, the air flow can apply a pressure to the optical lens, so that the optical lens can be conveniently pressed and fixed;

after the optical lens is installed, when the output pipe 213 gradually moves away from the optical lens, the telescopic sleeve 215 and the sealing sleeve 217 return to the original positions, and the air flow is ejected from the inner walls of the telescopic sleeve 215 and the output pipe 213 to give an impact force to the optical lens, so that the optical lens is prevented from falling off after being installed.

Considering that the optical lens needs to be cleaned during installation, one side of the output pipe 213 is provided with the cleaning mechanism 22, the cleaning device 2 comprises an output sleeve 223, the output sleeve 223 is used for being matched with the output pipe 213 to fix the optical lens, the side wall of the output sleeve 223 is provided with a leakage groove 224, the leakage groove 224 is used for guiding air to flow towards two sides of the output sleeve 223, a guiding structure is arranged inside the output sleeve 223, when one end of the output sleeve 223 is not attached to the optical lens, the guiding structure guides the air flow inside the output sleeve 223 to be sprayed out from the end part of the output sleeve 223 and the leakage groove 224, and after one end of the output sleeve 223 is attached to the optical lens, the guiding structure guides the air flow inside the output sleeve 223 to be sprayed out from the leakage groove 224;

the guiding structure comprises a sliding sleeve 225, the sliding sleeve 225 is used for guiding airflow in the output sleeve 223 to flow, when one end of the sliding sleeve 225 is not attached to the optical lens, a leakage groove 224 is sealed, the sliding sleeve 225 is arranged on the inner wall of the output sleeve 223 in a sliding mode, a leakage hole 226 is formed in the side wall of the sliding sleeve 225 and used for guiding airflow to flow, a cleaning spring 227 is fixedly connected to one end of the sliding sleeve 225, the cleaning spring 227 is used for pushing the sliding sleeve 225, and one end of the cleaning spring 227 is fixedly connected with the output sleeve 223;

the guide structure further comprises a baffle 228, when one end of the output sleeve 223 is attached to the optical lens, one end of the sliding sleeve 225 is sealed by the baffle 228, one end of the baffle 228 is fixedly connected with a sealing frame 229, the sealing frame 229 is used for determining the moving track of the baffle 228, an accommodating groove 2231 is formed in one side inside the output sleeve 223, the accommodating groove 2231 is used for determining the moving track of the sealing frame 229, the sealing frame 229 is arranged inside the accommodating groove 2231 in a sliding mode, one end of the sealing frame 229 is fixedly connected with a sealing spring 2291, the sealing spring 2291 is used for providing a pulling force for the sealing frame 229, and one end of the sealing spring 2291 is fixedly connected with the accommodating groove 2231;

before one end of the sliding sleeve 225 is attached to the optical lens, under the influence of the elastic force of the cleaning spring 227, the sliding sleeve 225 is located at a position where the leak groove 224 is sealed, under the action of the sealing spring 2291, the sealing frame 229 and the baffle 228 are in a contraction state, the position of the sealing frame 229 is locked, at this time, the baffle 228 does not seal the inner wall of the sliding sleeve 225, airflow directly enters the inner part of the output sleeve 223 through the baffle 228, and directly flows out through the inner wall of the output sleeve 223 and the sliding sleeve 225, so that the cleaning of one side of the optical lens is completed, and the space of the optical lens is blown, so that dust is prevented from falling onto the surface of the optical lens when the optical lens is installed;

when one end of the output sleeve 223 is attached to the optical lens, the sliding sleeve 225 is pressed by the optical lens to overcome the elastic force of the cleaning spring 227 and slide into the output sleeve 223, the limitation on the sealing frame 229 is removed, at this time, the air flow in the output sleeve 223 pushes the baffle 228 to overcome the tensile force of the sealing spring 2291, so that the baffle 228 gradually slides to one end position of the inner wall of the sliding sleeve 225, the inner wall of the sliding sleeve 225 is sealed, at this time, the outer wall of the leakage hole 226 is matched with the inner wall of the leakage groove 224, the air flow flows out along the leakage hole 226 and the leakage groove 224, the air around the optical lens is blown, dust is prevented from being attached to the periphery of the lens in the installation process, and meanwhile, the air flow of the inner walls of the output sleeve 223 and the sliding sleeve 225 is prevented from impacting the surface of the optical lens;

considering that before the optical lens is installed, the inside of the shell of the intelligent instrument and meter needs to be cleaned, after the optical lens is installed, the optical lens needs to be prevented from being fixed by air flow, a positioning mechanism 23 is arranged inside the output sleeve 223, the positioning mechanism 23 comprises a wedge-shaped block 235, in order to push the wedge-shaped block 235 to move when the closed frame 229 slides, the position of the closed frame 229 can be limited, the wedge-shaped block 235 is set to be wedge-shaped, the wedge-shaped block 235 is in clamping fit with the closed frame 229, a lifting frame 233 is fixedly connected to the bottom end of the wedge-shaped block 235, the lifting frame 233 is used for driving the wedge-shaped block 235 to move, a positioning spring 234 is fixedly connected to the bottom end of the wedge-shaped block 235, the positioning spring 234 is used for pushing the wedge-shaped block 235 to move upwards, the bottom end of the positioning spring 234 is fixedly connected with the output sleeve 223, a wedge-shaped plate 232 is arranged on one side of the lifting frame 233, in order to drive the lifting frame 233 to slide when the wedge-shaped plate 232 moves, therefore, the wedge plate 232 is set to be wedge-shaped, one end of the wedge plate 232 is fixedly connected with the driving rod 231, and when the leak hole 226 moves to the inside of the driving rod 231, one end of the leak hole 226 is attached to one end of the driving rod 231;

when one end of the output sleeve 223 is not jointed with the optical lens, the wedge 235 fixes the sealing frame 229 under the elastic force of the positioning spring 234, and the air flow is ejected through one end of the inner wall of the output sleeve 223 and the leak hole 226;

when one end of the output sleeve 223 is attached to the optical lens, the sliding sleeve 225 slides into the output sleeve 223, the sliding sleeve 225 pushes the active rod 231 to slide, the active rod 231 drives the wedge-shaped plate 232 to slide, the wedge-shaped plate 232 drives the lifting frame 233 to move downwards, the lifting frame 233 drives the wedge-shaped block 235 to move downwards, at this time, the wedge-shaped block 235 does not limit the position of the closed frame 229 any more, the baffle 228 is impacted by the airflow to block one end of the inner wall of the sliding sleeve 225, at this time, the airflow can only flow to the periphery of the output sleeve 223 through the leak hole 226 and the leak groove 224, when the output sleeve 223 is far away from the optical lens, the air of the surrounding environment is blown to prevent dust from falling onto the optical lens, compared with a common optical lens installation method, the direct contact of the hands of an operator to the optical lens is avoided, and meanwhile, the surface of the optical lens, the shell of the intelligent instrument and the dust of the surrounding environment are cleaned in the installation process, dust is prevented from existing inside the housing of the smart meter.

Considering that the optical lens needs to be prevented from being directly contacted by the hands of an operator when being installed, one side of the output pipe 213 and one side of the output sleeve 223 are both provided with a pumping structure, and the pumping structure is used for pumping air flow to the inner parts of the output pipe 213 and the output sleeve 223;

the pumping pressure structure comprises an air duct 212, the air duct 212 is used for guiding the air flow to the interior of an output pipe 213, one end of the air duct 212 is fixedly connected with the output pipe 213, the bottom end of the air duct 212 is fixedly connected with an air conveying pump 211, and the air conveying pump 211 is used for producing the air flow and guiding the air flow to the interior of the air duct 212;

the pumping structure further comprises an input pipe 222, the input pipe 222 is used for guiding the air flow to the inside of the output sleeve 223, one end of the input pipe 222 is fixedly connected with the output sleeve 223, the bottom end of the input pipe 222 is fixedly connected with an air making pump 221, and the air making pump 221 is used for making the air flow and guiding the air flow to the inside of the input pipe 222;

the fixing device 1 comprises a fixing mechanism 11, the fixing mechanism 11 comprises a base 111, the base 111 is used for determining the moving tracks of an air delivery pump 211 and an air production pump 221, the air delivery pump 211 is arranged on one side of the top of the base 111 in a sliding mode, the air production pump 221 is arranged on the other side of the top of the base 111 in a sliding mode, a fixing telescopic rod 112 is arranged on one side of the air delivery pump 211 and used for driving the air delivery pump 211 to slide, the fixing telescopic rod 112 is fixedly arranged on the top of the base 111, a piston rod of the fixing telescopic rod 112 is fixedly connected with the air delivery pump 211, a sliding telescopic rod 114 is arranged on one side of the air production pump 221, the sliding telescopic rod 114 is fixedly arranged on the top of the base 111, and a piston rod of the sliding telescopic rod 114 is fixedly connected with the air production pump 221;

the top of the base 111 is provided with a clamping mechanism 12, the clamping mechanism 12 comprises two clamping plates 127, the clamping plates 127 are used for fixing the position of the intelligent instrument, one side of each clamping plate 127 is fixedly connected with a clamping rod 126, each clamping rod 126 is used for driving the corresponding clamping plate 127 to rotate, one side of each clamping plate 127 is hinged with a fixed rod 113, each fixed rod 113 is used for determining the rotating track of the corresponding clamping rod 126, the bottom end of each fixed rod 113 is fixedly connected with the base 111, the bottom end of each clamping rod 126 is in inserted fit with a rotating rod 124, each rotating rod 124 is used for driving the corresponding clamping rod 126 to rotate, the top end of each rotating rod 124 is fixedly connected with a movable spring 125, each movable spring 125 is used for providing thrust for the corresponding clamping rod 126, and one end of each movable spring 125 is fixedly connected with the corresponding clamping rod 126;

a lifting plate 123 is arranged on one side of the rotating rod 124, the lifting plate 123 is used for driving the rotating rod 124 to move, the lifting plate 123 is rotatably connected with the rotating rod 124, an insertion rod 121 is fixedly connected with the bottom end of the lifting plate 123, the insertion rod 121 is used for determining the moving track of the lifting plate 123, an insertion hole 115 is formed in the top of the base 111, the insertion hole 115 is used for determining the moving track of the insertion rod 121, a clamping spring 122 is fixedly connected with the bottom end of the lifting plate 123, the insertion rod 121 is in insertion fit with the insertion hole 115, the clamping spring 122 is used for providing downward tensile force to the lifting plate 123, and the bottom end of the clamping spring 122 is fixedly connected with the base 111;

the lifting plate 123 is pushed to enable the lifting plate 123 to overcome the elastic force of the clamping spring 122 to slide upwards, the lifting plate 123 drives one end of the rotating rod 124 to move, the rotating rod 124 drives the clamping rod 126 to rotate, the clamping rod 126 drives the clamping plate 127 to rotate to be in an open state, the shell of the intelligent instrument is placed between the two clamping plates 127, the lifting plate 123 is loosened, the clamping spring 122 drives the lifting plate 123 to move downwards, the two clamping plates 127 return to a closed state, the shell of the intelligent instrument is fixed, the sliding telescopic rod 114 drives the air making pump 221 to slide on the top of the base 111, the air making pump 221 drives the output sleeve 223 to move through the input pipe 222, the air making pump 221 makes air flow and guides the air flow to the inside of the output sleeve 223 through the input pipe 222, the wedge block 235 and the sealing frame 229 are in a clamping fit state at the moment, the sealing frame 229 cannot move due to the influence of the air flow, and the air flow passes through the inside of the output sleeve 223, flows out from one end position of the inner wall of the sliding sleeve 225 and the leak hole 226, at this time, the output sleeve 223 gradually enters the inside from one side of the intelligent instrument and meter shell and then moves from the inside to the outside position of the other side, in the process, dust in the air around the intelligent instrument and meter shell is blown away at first, dust attached to the inside of the intelligent instrument and meter shell is blown clean, the optical lens is placed on one side of the sliding sleeve 225, one side of the optical lens is cleaned, the fixing telescopic rod 112 drives the air transmission pump 211 to slide, the air transmission pump 211 drives the output pipe 213 to slide through the air guide pipe 212, one end of the output pipe 213 is gradually attached to the surface of the optical lens, the optical lens is firmly pressed, in the process, air generated by the air transmission pump 211 enters the inside of the output pipe 213 through the air guide pipe 212, the air cleans the other side of the optical lens, after the optical lens is clamped and fixed, the air current is from cleaning groove 214 and blowpit 224 to both sides blowout, accomplishes around the intelligent instrument and meter shell and inside dust and gives and blow away to clear up optical lens, compare in common optical lens mounting method, can effectively avoid on the optical lens that the dust in the in-process surrounding environment of installation falls on, also avoid the inside of intelligent instrument and meter shell to fall grey.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and the preferred embodiments of the present invention are described in the above embodiments and the description, and are not intended to limit the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. Based on spout STREAMING intelligent instrument production is with inside dust clean-up equipment, its characterized in that: including fixing device (1) and set up in cleaning device (2) at fixing device (1) top, fixing device (1) is used for the position of fixed intelligent instrument and meter, cleaning device (2) include pressing means (21), pressing means (21) include output tube (213), cleaning tank (214) have been seted up to the lateral wall of output tube (213), cleaning tank (214) run through output tube (213), the inside of output tube (213) is equipped with the water conservancy diversion structure, when the one end of output tube (213) was not laminated with optical lens, the water conservancy diversion structure guide air current was spout from the tip of output tube (213), when the one end of output tube (213) and optical lens laminated, the water conservancy diversion structure guide air current was spout from cleaning tank (214), one side of output tube (213) is equipped with cleaning mechanism (22), cleaning device (2) are including output cover (223), the side wall of the output sleeve (223) is provided with a leakage groove (224), a guide structure is arranged inside the output sleeve (223), when one end of the output sleeve (223) is not attached to the optical lens, the guide structure guides air flow inside the output sleeve (223) to be sprayed out from the end of the output sleeve (223) and the leakage groove (224), after one end of the output sleeve (223) is attached to the optical lens, the guide structure guides air flow inside the output sleeve (223) to be sprayed out from the leakage groove (224), one sides of the output pipe (213) and the output sleeve (223) are both provided with a pumping structure, and the pumping structure is used for pumping the air flow to the inside of the output pipe (213) and the output sleeve (223).

2. The internal dust cleaning device for jet-flow-based smart instrument production according to claim 1, wherein: the flow guide structure comprises a telescopic sleeve (215), the telescopic sleeve (215) is arranged on the inner wall of an output pipe (213) in a sliding mode, a vent groove (216) is formed in the side wall of the telescopic sleeve (215), the vent groove (216) penetrates through the telescopic sleeve (215), when one end of the output pipe (213) is attached to an optical lens, the outer wall of the vent groove (216) is matched with the inner wall of a cleaning groove (214), a telescopic spring (2151) is fixedly connected to one end of the telescopic sleeve (215), one end of the telescopic spring (2151) is fixedly connected with the output pipe (213), a sliding groove (2131) is formed in the telescopic sleeve (215), a sealing sleeve (217) is arranged in the sliding groove (2131) in a sliding mode, and when the telescopic sleeve (215) is not attached to the optical lens, the sealing sleeve (217) seals the vent groove (216).

3. The internal dust cleaning device for jet-flow-based smart instrument production according to claim 2, wherein: one end positions of two sides of the sealing sleeve (217) are fixedly connected with a sliding toothed plate (2171), one side of the sliding toothed plate (2171) is meshed with a gear (218), the gear (218) is rotatably connected with the telescopic sleeve (215), one side of the gear (218) is meshed with a fixed toothed plate (219), and the fixed toothed plate (219) is fixedly connected with the output pipe (213).

4. The internal dust cleaning device for jet-flow-based intelligent instrument and meter production according to claim 1, wherein: the guide structure comprises a sliding sleeve (225), the sliding sleeve (225) is arranged on the inner wall of the output sleeve (223) in a sliding mode, a leakage hole (226) is formed in the side wall of the sliding sleeve (225), one end of the sliding sleeve (225) is fixedly connected with a cleaning spring (227), and one end of the cleaning spring (227) is fixedly connected with the output sleeve (223).

5. The internal dust cleaning device for jet-flow-based smart instrument production according to claim 1, wherein: the guide structure still includes baffle (228), when the one end of output cover (223) and optical lens laminating, baffle (228) give airtight the one end of sliding sleeve (225), the one end fixedly connected with of baffle (228) seals frame (229), holding tank (2231) have been seted up to output cover (223) inside one side, sealed frame (229) slide and set up in the inside of holding tank (2231), the one end fixedly connected with of sealed frame (229) seals spring (2291), the one end and holding tank (2231) fixed connection of sealed spring (2291).

6. The internal dust cleaning device for jet-flow-based smart instrument production according to claim 4, wherein: the inside of output cover (223) is equipped with positioning mechanism (23), positioning mechanism (23) are including wedge (235), wedge (235) and airtight frame (229) joint cooperation, the bottom fixedly connected with crane (233) of wedge (235), the bottom fixedly connected with location spring (234) of wedge (235), the bottom and the output cover (223) fixed connection of location spring (234), one side of crane (233) is equipped with wedge (232), the one end fixedly connected with drive lever (231) of wedge (232), when small opening (226) remove to the inside of drive lever (231), the one end of small opening (226) and the one end laminating of drive lever (231).

7. The internal dust cleaning device for jet-flow-based intelligent instrument and meter production according to claim 1, wherein: the pumping pressure structure comprises an air duct (212), one end of the air duct (212) is fixedly connected with an output pipe (213), and the bottom end of the air duct (212) is fixedly connected with an air delivery pump (211).

8. The internal dust cleaning device for jet-flow-based smart instrument production according to claim 7, wherein: the pumping structure further comprises an input pipe (222), one end of the input pipe (222) is fixedly connected with the output sleeve (223), and the bottom end of the input pipe (222) is fixedly connected with a gas producing pump (221).

9. The internal dust cleaning device for jet-flow-based smart instrument production according to claim 8, wherein: fixing device (1) is including fixed establishment (11), fixed establishment (11) is including base (111), air delivery pump (211) slides and sets up in one side at base (111) top, air production pump (221) slides and sets up in the opposite side at base (111) top, one side of air delivery pump (211) is equipped with fixed telescopic link (112), fixed telescopic link (112) are fixed to be set up in the top of base (111), the piston rod and air delivery pump (211) fixed connection of fixed telescopic link (112), one side of air production pump (221) is equipped with slip telescopic link (114), the piston rod and air production pump (221) fixed connection of slip telescopic link (114).

10. The internal dust cleaning device for jet-flow-based smart instrument production according to claim 9, wherein: the top of base (111) is equipped with fixture (12), fixture (12) includes two grip blocks (127), one side fixedly connected with clamping rod (126) of grip block (127), one side of grip block (127) articulates there is dead lever (113), the bottom and base (111) fixed connection of dead lever (113), the cooperation of pegging graft has dwang (124) in the bottom of clamping rod (126), the top fixedly connected with activity spring (125) of dwang (124), the one end and the clamping rod (126) fixed connection of activity spring (125), one side of dwang (124) is equipped with lifter plate (123), lifter plate (123) and dwang (124) swivelling joint, the bottom fixedly connected with inserted bar (121) of lifter plate (123), jack (115) has been seted up at the top of base (111), the inserted bar (121) is in inserted connection with the insertion hole (115), and the bottom end of the lifting plate (123) is fixedly connected with a clamping spring (122).

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