CN116949661A - Adhesion type partition device of circular weft knitting machine and fly eliminating method - Google Patents

Abstract

The invention relates to the technical field of textile equipment, in particular to an adhesive type partition device of a circular weft knitting machine and a fly eliminating method, wherein the device comprises a plurality of water baffles, each water baffle is provided with a water storage box, a baffle plate, a buoyancy component, an atomization component and a flushing component; the adhesion capability to the fly ash is improved through the end cap on the baffle plate, the fly ash adhered to the end cap can be cleaned when the end cap is flush with the water baffle plate, the water baffle plate is matched with the flushing assembly, the subsequent collection and cleaning capability to the fly ash is improved, and the stability and the sustainability of the partition device are improved.

Description

Adhesion type partition device of circular weft knitting machine and fly eliminating method

Technical Field

The invention relates to the technical field of textile equipment, in particular to an adhesive type partition device of a circular weft knitting machine and a fly eliminating method.

Background

The technical scheme is that a circular knitting machine is named as a circular knitting machine or a circular knitting machine, fly is generated in the working process of the circular knitting machine, one of the problems puzzling manufacturers is solved, chinese patent CN204898254U discloses a circular knitting machine air house special for colored knitting, the circular knitting machine air house is characterized in that an air blower is arranged at the top of the circular knitting machine in a closed space, an exhaust fan is arranged at the bottom of the circular knitting machine to pump air to the closed space, the problem of fly in a room is solved, but for a factory building, a plurality of independent spaces do not exist in the factory building, therefore, a device capable of meeting the cleaning of fly and realizing space isolation is needed, chinese patent CN215051099U discloses a circular knitting machine isolation device which comprises a flexible water pipe, a three-way valve, a water pump, a water drain groove, a water baffle plate, a fixing piece and a connecting piece, wherein the water drain groove is arranged at the bottom of the water baffle plate in the height direction, the three-way valve is arranged on the closed space, one end of the water pump is communicated with the three-way valve, the other end of the water pump is communicated with the water drain groove, the water drain groove is arranged at the bottom of the water drain groove, and the water drain groove is arranged at the side of the water drain groove and is arranged around the water drain ring, and the water drain plate is arranged around the water drain ring and has the effect of the function that the water drain plate is arranged around the water drain ring and the water drain device; in the use of weft knitting machine, the three-way valve is gone into with the liquid pump in the water drainage tank to the water pump, because three-way valve and flexible water piping connection, consequently, the wash port on the flexible water piping is gone into the breakwater with liquid, the fly in the air is brought into the water drainage tank through the liquid on the breakwater, realize the elimination to the fly from this, rivers all flow through from the both sides of breakwater, but the breakwater can only adhere to the fly to one side wherein, easily cause the waste to the water resource, the in-process that the fly was collected on the breakwater simultaneously, the fly adhesion is on the breakwater, the accumulation of elapsed time can cause the fly to accumulate too much on the breakwater, cause the jam of breakwater and water course easily, be difficult for the clearance, device sustainability is relatively poor, and the fly is in the mode through the fly adhesion with the breakwater, the fly is difficult to be controlled, make equipment be difficult to collect the fly.

Disclosure of Invention

According to the adhesion type partition device and the fly eliminating method for the circular weft knitting machine, when the fly on the water baffle is accumulated too much, the fly on the water baffle is washed regularly through the washing component, so that the buoyancy component in the water storage box is driven, the atomization component and the partition plate are driven through the buoyancy component, the environment is humidified through spraying of the atomization component, and the fly is not easy to fly and is accelerated to subside; the adhesion capability to the fly ash is improved through the end cap on the baffle plate, the fly ash adhered to the end cap can be cleaned when the end cap is flush with the water baffle plate, the water baffle plate is matched with the flushing assembly, the subsequent collection and cleaning capability to the fly ash is improved, and the stability and the sustainability of the partition device are improved.

In order to solve the problems in the prior art, the adhesion type partition device of the circular weft knitting machine comprises a plurality of water baffles which are equidistantly and circumferentially arranged on the periphery of the weft knitting machine, and is characterized in that the water baffles are obliquely arranged, each water baffle is provided with a plurality of through holes which are arranged in a rectangular array, the water baffles are provided with baffle plates which can slide along the axial direction of the through holes, the baffle plates are provided with plugs which are the same in number with the through holes and correspond to the through holes one by one, and the plugs are in sliding fit with the through holes; the top of each water baffle is provided with a water storage box, and the water storage box is provided with an atomization component for humidifying the environment and a flushing component for flushing the water baffles at regular time; the buoyancy component is positioned in the water storage box, can slide along the vertical direction of the water storage box, and can float on water flow of the water storage box; the atomizing assembly is positioned at the top of the water storage box; the flushing component is positioned below the water storage box; the atomizing assembly and the baffle plate are in transmission connection with the buoyancy assembly.

Preferably, the flushing assembly comprises a valve and a U-shaped bent pipe, the valve is arranged at the top of the water storage box, the bent pipe is inverted in the water storage box, a water outlet is formed in the bottom of the water storage box, one end of the bent pipe is communicated with the water outlet, the other end of the bent pipe is located at the side of the water outlet, and a gap is formed at the end part of the bent pipe away from the bottom of the water storage box.

Preferably, both sides of the water baffle are provided with baffles extending along the length direction of the water baffle, and the flushing assembly further comprises a first nozzle with a flat opening, and the first nozzle is arranged below the water outlet of the water storage box.

Preferably, the atomizing subassembly includes atomizer, the water suction pipe, the intake pipe, the piston, head rod and first spring, the water suction pipe is L shape structure, the water suction pipe is vertical state and sets up on the water storage box, the top of water suction pipe is located to the atomizer cover, the central authorities of water suction pipe are provided with the connecting hole that matches each other with the intake pipe, intake pipe fixed connection is on the connecting hole and with its intercommunication, the piston can be gliding be located the intake pipe, first spring is located between piston and the water suction pipe for the piston passes through first spring and intake pipe elastic connection, head rod fixed connection keeps away from the one end of first spring on the piston.

Preferably, the atomizing assembly further comprises a steel ball and a second spring, a narrow opening which is radially retracted along the pipeline is arranged below the water suction pipe, the steel ball is matched with the narrow opening, a mounting frame through which water can flow is arranged in the water suction pipe, one end of the second spring is connected with the steel ball, and the other end of the second spring is connected with the mounting frame.

Preferably, the buoyancy component comprises a stand column and a buoyancy ring capable of floating on the water surface, the stand column is in a vertical state and fixedly connected in the water storage box, the buoyancy ring is of a hollow structure, a plurality of raised strips encircling the stand column are arranged on the stand column, the raised strips extend along the length direction of the raised strips, and grooves matched with the raised strips are formed in the inner wall of the buoyancy ring.

Preferably, the buoyancy ring is provided with a second connecting rod hinged with the buoyancy ring, and the second connecting rod is hinged with the end part of the first connecting rod.

Preferably, the second connecting rod is provided with a first sliding rail extending along the length direction of the second connecting rod, the top and the bottom of the water storage box are respectively provided with a third connecting rod capable of sliding along the horizontal direction, a fixing frame is arranged between the two third connecting rods on the outer wall of the water storage box, a fourth connecting rod is arranged on the fixing frame, the middle part of the fourth connecting rod is hinged with the fixing frame, the two ends of the fourth connecting rod are respectively provided with a second sliding rail extending along the length direction of the fourth connecting rod, one end of the third connecting rod positioned at the top of the water storage box is in sliding fit with the first sliding rail, and the other end of the third connecting rod is in sliding fit with the second sliding rail; the top of baffle is provided with the slide bar, and the bottom of water storage box is provided with the gliding carriage of horizontal direction that can follow the water storage box, and the below of carriage is provided with the third slide rail that matches each other with the slide bar, slide bar and third slide rail sliding fit, the wherein one end and the second slide rail sliding fit of the third connecting rod that is located water storage box bottom, its other end and carriage fixed connection.

Preferably, the bottom of the water baffle is also provided with a water receiving tank, and the top of the water receiving tank is provided with a filter screen.

The fly eliminating method for circular weft knitting machine is applied to the adhering type partition device of the circular weft knitting machine and comprises the following steps:

s1, draining water for the water storage box, so that the buoyancy component is positioned at the top of the water storage box, the atomization component is in a closed state, and a plug on the baffle plate can penetrate through the through hole to be ejected out of the water baffle plate;

s2a, releasing water flow in the water storage box by starting the flushing component, wherein the reduction of the water flow drives the buoyancy component to descend, so that the baffle plate and the atomization component which are in transmission connection with the buoyancy component are driven to move;

s2b, humidifying the environment through the atomization assembly, so that flying and scattering are reduced, and sedimentation of flying and scattering is accelerated;

s2c, through the movement of the baffle plate, the fly waste accumulated on the plug can be cleaned, and meanwhile, the flushing assembly can release water flow along the water baffle plate, so that the fly waste accumulated on the water baffle plate can be cleaned uniformly;

s3, repeating the steps of S2a, S2b and S2c until water storage is stopped in the water storage box.

Compared with the prior art, the invention has the beneficial effects that: according to the invention, a plurality of water baffles which are equidistantly and circumferentially arranged on the periphery of the weft knitting machine can form a space isolated from the outside, so that the purpose of isolating the periphery of the weft knitting machine is achieved; the splash can be better collected through the obliquely arranged water baffle, when the number of the splash on the water baffle is too large, the splash on the water baffle is regularly washed through the washing component, so that the excessive splash is prevented from adhering to the water baffle, the buoyancy component in the water storage box can be driven when the water is drained, the buoyancy component can drive the movement of the atomization component and the baffle plate, the environment is humidified through the spraying of the atomization component, the splash is not easy to fly away, and the sedimentation of the splash is accelerated; can improve the adhesion capability to the fly-by-fly through the end cap on the baffle, can clear up the fly-by-fly that adheres to on the end cap when buoyancy subassembly drives end cap and breakwater parallel and level simultaneously, the cooperation washes the subassembly and clear up the fly-by-fly on the breakwater, improves the breakwater follow-up collection and the clearance ability to the fly-by-fly from this, improves partition device's stability and sustainability.

Drawings

FIG. 1 is a schematic perspective view of an adhesive cut-off device of a circular weft knitting machine;

FIG. 2 is a schematic view of a partial perspective view of an adhesive cut-off device of a circular weft knitting machine;

FIG. 3 is a schematic view of a partial cross-sectional structure of an adhesive cut-off device of a circular weft knitting machine;

fig. 4 is an enlarged view at a in fig. 3;

FIG. 5 is a schematic perspective view of a water storage box and a barrier plate in an adhesive type partition device of a circular weft knitting machine;

FIG. 6 is a schematic perspective view of a water storage box in an adhesive cut-off device of a circular weft knitting machine;

fig. 7 is an enlarged view at B in fig. 5;

fig. 8 is an enlarged view at C in fig. 5;

FIG. 9 is a schematic perspective view of an atomizing assembly in an adhesive cut-off device of a circular weft knitting machine;

FIG. 10 is a schematic perspective view of a buoyancy module in an adhesive cut-off device of a circular weft knitting machine;

fig. 11 is a schematic perspective view of a water deflector in an adhesive cut-off device of a circular weft knitting machine.

The reference numerals in the figures are: 1-a water baffle; 11-through holes; 12-baffle plate; 121-plugs; 122-sliding bar; 13-a baffle; 14-a water receiving tank; 141-a filter screen; 2-a water storage box; 21-a buoyancy module; 211-upright posts; 2111-protruding strips; 212-buoyancy ring; 2121-grooves; 213-a second connecting rod; 2131-a first slide rail; 22-flushing assembly; 221-valve; 222-bending the pipe; 223-water outlet; 224-first spray head; 23-an atomizing assembly; 231-a suction tube; 2311-an atomizer; 2312-a narrow opening; 2313-steel balls; 2314-a second spring; 2315-mounting rack; 2316-connecting holes; 232-an air inlet pipe; 2321-a piston; 2322-a first connecting rod; 2323—a first spring; 24-a third connecting rod; 25-fixing frame; 251-fourth connecting rod; 252-a second slide rail; 26-a carriage; 261-third slide rail.

Detailed Description

The invention will be further described in detail with reference to the drawings and the detailed description below, in order to further understand the features and technical means of the invention and the specific objects and functions achieved.

As shown in fig. 1 to 3, 5, 8 and 11: the adhering type partition device of the circular weft knitting machine comprises a plurality of water baffles 1 which are equidistantly and circumferentially arranged on the periphery of the weft knitting machine, wherein the water baffles 1 are obliquely arranged, a plurality of through holes 11 which are arranged in rectangular rows are formed in each water baffle 1, baffle plates 12 which can slide along the axial direction of the through holes 11 are arranged on the water baffles 1, plugs 121 which are the same in number with the through holes 11 and correspond to the through holes 11 one by one are arranged on the baffle plates 12, and the plugs 121 are in sliding fit with the through holes 11; the top of each water baffle 1 is provided with a water storage box 2, and the water storage box 2 is provided with an atomization assembly 23 for humidifying the environment and a flushing assembly 22 for flushing the water baffle 1 at regular time, wherein the buoyancy assembly 21 is arranged on the water storage box 2; the buoyancy component 21 is positioned in the water storage box 2, the buoyancy component 21 can slide along the vertical direction of the water storage box 2, and the buoyancy component 21 can float on water flow of the water storage box 2; the atomizing assembly 23 is positioned at the top of the water storage box 2; the flushing assembly 22 is positioned below the water storage box 2; both the atomizing assembly 23 and the baffle 12 are in driving connection with the buoyancy assembly 21.

The water baffle plates 1 which are equidistantly and circumferentially arranged on the periphery of the weft knitting machine can form a space isolated from the outside, so that the purpose of isolating the periphery of the weft knitting machine is achieved; the water storage box 2 is fully filled with water in advance, the water flow in the water storage box 2 can enable the buoyancy component 21 to be located at the top of the water storage box 2, the atomization component 23 is in a closed state at the moment, the plug 121 on the baffle plate 12 can penetrate through the through hole 11 to be ejected out of the water baffle plate 1, and before the water baffle plate 1 is used, the water baffle plate 1 can be flushed by a plurality of flushing components 22, so that the water baffle plate 1 is in a wet state; at this time, the water storage box 2 is kept in a water inlet state, the flushing component 22 can regularly jet water flow in the water storage box 2 from the bottom of the water storage box 2, the water flow can flow along the surface of the inclined water baffle 1, the weft knitting machine can generate fly in the working process, when the fly flows towards the water baffle 1, the fly falls on the water baffle 1 and is rich in water due to the residual water flow on the water baffle 1, so that the fly can be adhered, a fan capable of continuously blowing air towards the peripheral side of the weft knitting machine can be arranged at the top of the weft knitting machine, and the fly generated in the working process of the weft knitting machine can be continuously blown onto the water baffle 1 through the fan, so that the separation device can collect the fly conveniently, and the collecting capacity of the fly is improved; meanwhile, in order to reduce the flying and scattering around, the collecting of the flying and scattering of the water baffle plate 1 is improved, after each flushing component 22 discharges the water flow in the water storage box 2, the buoyancy component 21 slides along the vertical direction of the water storage box 2 due to the reduction of the water flow, the atomization component 23 connected with the buoyancy component is driven by the sliding, the environment in the water baffle plate 1 is sprayed with water mist through the atomization component 23, the humidity of the environment is increased, the flying and scattering around capacity is reduced, the flying and scattering can be better adhered to the water baffle plate 1, and the flushing component 22 can regularly discharge the water for the water storage box 2, so that the buoyancy component 21 can regularly start the atomization component 23, and the atomization component 23 can regularly humidify the environment; after the fly leaves fall on the water baffle 1, the fly leaves can adhere to the water baffle 1, the capacity of the fly leaves adhering to the water baffle 1 can be improved through the plug 121 on the baffle 12, but the capacity of the baffle 12 for collecting the fly leaves can be influenced after the fly leaves accumulate too much, the baffle 12 connected with the fly leaves can be driven by the motion of the buoyancy component 21, the plug 121 can slide along the axial direction of the through hole 11 towards one end far away from the water baffle 1 until the end of the plug 121 is flush with the water baffle 1, the fly leaves accumulated on the plug 121 can be cleaned and adhered to the water baffle 1 through the motion of the plug 121, at the moment, the flushing component 22 drives water flow to flow out of the water storage box 2, the fly leaves adhered to the water baffle 1 can be flushed through the flushing component 22, the fly leaves can flow towards the bottom of the water baffle 1, the cleaning of the water baffle 1 is completed, the subsequent collecting capacity of the fly leaves is improved, and the stability and the sustainability of the isolation device are improved.

As shown in fig. 2 to 6: the flushing assembly 22 comprises a valve 221 and a U-shaped elbow 222, the valve 221 is arranged at the top of the water storage box 2, the elbow 222 is inverted inside the water storage box 2, a water outlet 223 is arranged at the bottom of the water storage box 2, one end of the elbow 222 is communicated with the water outlet 223, the other end of the elbow 222 is positioned beside the water outlet 223, and a gap is formed between the end of the elbow and the bottom of the water storage box 2.

Through the setting of valve 221, can carry out continuous drainage to water storage box 2, water can store in water storage box 2, because U-shaped return bend 222 one end is connected with delivery port 223, all rivers can only get into its inside through the other end of return bend 222, and return bend 222 is placed upside down in water storage box 2, make water storage box 2 can be when rivers do not reach the bend of return bend 222, rivers can constantly store, after the horizontal plane of rivers is higher than the bend of return bend 222, under the effect of siphon principle, rivers can be because the pressure differential makes the rivers in the water storage box 2 discharge from delivery port 223 through return bend 222, thereby empty the water in the water storage box 2, make buoyancy subassembly 21 can move along with the rivers, drive atomizing subassembly 23 and the baffle 12 of being connected with buoyancy subassembly 21 transmission, make water storage box 2 have the function of timing drainage, make flushing subassembly 22 can wash the splash on the breakwater 1, improve the collection ability of breakwater 1 to the flyings. The water flow is controlled by the valve 221, the water draining time of the water storage box 2 can be controlled, the adaptability of the device is improved, and two adjacent water baffles 1 can be connected in series through the water pipe, so that the water storage boxes 2 of all the water baffles 1 can be controlled through one valve 221.

As shown in fig. 2 to 6 and 8: both sides of the water baffle 1 are provided with baffles 13 extending along the length direction thereof, and the flushing assembly 22 further comprises a first nozzle 224 with a flat opening, wherein the first nozzle 224 is arranged below the water outlet 223 of the water storage box 2.

Through the setting of baffle 13 for the rivers of breakwater 1 can be better flow on breakwater 1, through the setting of the first shower nozzle 224 of flat mouthful, make rivers better with breakwater 1 mutual match, make homoenergetic on the breakwater 1 by moist, improve its to the collection ability of fly.

As shown in fig. 2 to 6 and 9: the atomizing subassembly 23 includes atomizer 2311, the water suction pipe 231, the intake pipe 232, piston 2321, head rod 2322 and first spring 2323, the water suction pipe 231 is L shape structure, the water suction pipe 231 is vertical state and sets up on water storage box 2, atomizer 2311 cover is located the top of water suction pipe 231, the central authorities of water suction pipe 231 are provided with the connecting hole 2316 that mutually matches with intake pipe 232, intake pipe 232 fixed connection is on connecting hole 2316 and communicates with it, piston 2321 slidable is located intake pipe 232, first spring 2323 is located between piston 2321 and the water suction pipe 231, make piston 2321 pass through first spring 2323 and intake pipe 232 elastic connection, head rod 2322 fixed connection keeps away from the one end of first spring 2323 on piston 2321.

According to the Bernoulli principle, when the fluid speed is high and the pressure is low, water flow automatically flows from high pressure to low pressure, the first connecting rod 2322 drives the piston 2321 fixedly connected with the first connecting rod 2322 by pushing the first connecting rod 2322, so that the piston 2321 slides along the axial direction of the air inlet pipe 232, the first spring 2323 is extruded, and after one-time driving is finished, the first spring 2323 drives the first connecting rod 2322 to reset, so that the subsequent driving of the atomization assembly 23 is facilitated; through the motion of piston 2321 makes the air can be moved in the intake pipe 232 from the top of water suction pipe 231 rapidly, and the air near atomizer 2311 can flow fast this moment, and then the pressure diminishes, and the inside air pressure of water storage box 2 can grow, the inside water can flow along the bottom of water suction pipe 231 towards the top of water suction pipe 231 under the effect of high pressure, when squeezing head rod 2322 once more, the air current can follow the connecting hole 2316 of inlet tube and move towards in the water suction pipe 231, the rivers can receive the influence of air current impact, can promote rivers to pass through atomizer 2311 along the pipeline of water suction pipe 231 from this, thereby accomplish the humidification operation to the environment. In order to ensure the movement of the atomizing assembly 23, the atomizing assembly 23 is driven to operate several times by the buoyancy assembly 21 in advance, so that the suction water flow exists in the suction pipe 231, and the atomizing assembly 23 can continuously humidify the environment by spraying the water flow during continuous operation. The bottom of the water suction pipe 231 has a certain gap with the water storage box 2, and the gap is smaller than the gap between the U-shaped bent pipe 222 and the bottom of the water storage box 2, so that the water flow in the water storage box 2 can be ensured not to influence the work of the atomization assembly 23 after being released by the flushing assembly 22, and the water in the water storage box 2 can still be sucked.

As shown in fig. 2 to 6 and 9: the atomizing assembly 23 further comprises a steel ball 2313 and a second spring 2314, a narrow opening 2312 which is radially retracted along the pipe is arranged below the water suction pipe 231, the steel ball 2313 is matched with the narrow opening 2312, a mounting frame 2315 through which water can flow is arranged in the water suction pipe 231, one end of the second spring 2314 is connected with the steel ball 2313, and the other end of the second spring 2314 is connected with the mounting frame 2315.

When the first connecting rod 2322 drives air to push into the water suction pipe 231, the air can move from the connecting hole 2316 of the water suction pipe 231 to two sides of the water suction pipe 231, one side of the air can blow into the water storage box 2, the other side of the air blows water flow positioned at the top of the water suction pipe 231, at the moment, the water flow can be possibly caused to be sprayed out of the atomizing spray head 2311 in an unstable mode, through the arrangement of the steel balls 2313 and the second springs 2314, when the water flow in the water storage box 2 moves to the top of the water suction pipe 231 due to pressure, the steel balls 2313 can be pushed out by the water flow, the second springs 2314 shrink, and when the subsequent air flow enters the water suction pipe 231, the steel balls 2313 can block the narrow opening 2312 in the water suction pipe 231 under the action of resetting of the second springs 2314 and the air flow, so that the air flow can not enter the water storage box 2, and therefore the air flow can be stably pushed to the top of the water suction pipe 231, the water flow positioned in the water suction pipe 231 can be pushed out by larger air flow, and the atomizing stability of the water flow is improved.

As shown in fig. 3 to 6 and 10: the buoyancy module 21 comprises a stand column 211 and a buoyancy ring 212 capable of floating on the water surface, the stand column 211 is fixedly connected in the water storage box 2 in a vertical state, the buoyancy ring 212 is of a hollow structure, a plurality of raised strips 2111 surrounding the stand column 211 are arranged on the stand column 211, the raised strips 2111 extend along the length direction of the raised strips 2111, and grooves 2121 matched with the raised strips 2111 are formed in the inner wall of the buoyancy ring 212.

Through the setting of stand 211 and buoyancy ring 212 for buoyancy ring 212 can slide along the length direction of stand 211, and the hollow structure of buoyancy ring 212 is convenient for it can float on the surface of water, through the setting of sand grip 2111 and recess 2121, can lead the direction of motion of buoyancy ring 212, improves its stability of motion.

As shown in fig. 9 and 10: the buoyancy ring 212 is provided with a second connecting rod 213 hinged thereto, and the second connecting rod 213 is hinged to an end of the first connecting rod 2322.

The buoyancy ring 212 slides along the length direction of the upright post 211, so that the second connecting rod 213 hinged with the buoyancy ring is driven, the first connecting rod 2322 hinged with the buoyancy ring is driven by the second connecting rod 213, and the piston 2321 positioned in the air inlet pipe 232 is pushed by the first connecting rod 2322, so that the water suction pipe 231 can spray water from the atomizing nozzle 2311, and the atomization assembly 23 is driven.

As shown in fig. 2 to 10: the second connecting rod 213 is provided with a first sliding rail 2131 extending along the length direction thereof, the top and the bottom of the water storage box 2 are respectively provided with a third connecting rod 24 capable of sliding along the horizontal direction, a fixed frame 25 is arranged between the two third connecting rods 24 on the outer wall of the water storage box 2, a fourth connecting rod 251 is arranged on the fixed frame 25, the middle part of the fourth connecting rod 251 is hinged with the fixed frame 25, the two ends of the fourth connecting rod 251 are respectively provided with a second sliding rail 252 extending along the length direction thereof, one end of the third connecting rod 24 positioned at the top of the water storage box 2 is in sliding fit with the first sliding rail 2131, and the other end of the third connecting rod 24 is in sliding fit with the second sliding rail 252; the top of baffle plate 12 is provided with slide bar 122, and the bottom of water storage box 2 is provided with the carriage 26 that can follow the horizontal direction of water storage box 2, and the below of carriage 26 is provided with the third slide rail 261 that matches each other with slide bar 122, slide bar 122 and third slide rail 261 sliding fit, and the one end and the second slide rail 252 sliding fit of the third connecting rod 24 that is located the bottom of water storage box 2, its other end and carriage 26 fixed connection.

The second connecting rod 213 connected with the buoyancy ring 212 is driven by the motion of the buoyancy ring 212, the second connecting rod 213 can drive the first slide rail 2131 to move, the first slide rail 2131 can drive the third connecting rod 24 at the top of the water storage box 2 to slide along the horizontal direction, thereby driving the fourth connecting rod 251 in sliding fit with the other end of the third connecting rod 24 to move, as the middle part of the fourth connecting rod 251 is hinged with the fixing frame 25, the fourth connecting rod 251 rotates at the hinging point of the fourth connecting rod 251 and the fixing frame 25, thereby driving the third connecting rod 24 in sliding fit with the second slide rail 252 at the other end of the fourth connecting rod 251 to move, so that the third connecting rod 24 at the bottom of the water storage box 2 can relatively move with the third connecting rod 24 at the top of the water storage box 2, the third connecting rod 24 at the bottom of the water storage box 2 can drive the sliding frame 26 to move, the sliding frame 26 can drive the third slide rail 261 to move, and the sliding rod 122 in sliding fit with the third slide rail 261, and the movement of the sliding rod 122 drives the baffle 12, so that the baffle 12 can drive the plug 121 to rotate along the hinging point of the fixing frame 25, thereby driving the through hole 11 of the baffle plate 1, the third connecting rod 24 can relatively move with the third connecting rod 24 at the bottom of the water storage box 2 to move with the third connecting rod 24 at the third connecting rod 24, the third connecting rod 26, the movement of the third connecting rod 26 can drive the sliding rod 122 with the sliding rod 122, the sliding fit with the sliding rod other end of the sliding rod 122 with the sliding rod other connecting rod 251, and the sliding rod other connecting rod 251.

As shown in fig. 3 and 11: the bottom of the water baffle 1 is also provided with a water receiving tank 14, and the top of the water receiving tank 14 is provided with a filter screen 141.

Through the setting of water receiving tank 14 and filter screen 141 for the splash that leaves along breakwater 1 can be separated by filter screen 141, makes rivers and the separation of flight, thereby retrieves the rivers of breakwater 1 blowout, reduces the waste of water resource by this.

As shown in fig. 1 to 3, 5, 8 and 11: the fly eliminating method for circular weft knitting machine is applied to the adhering type partition device of the circular weft knitting machine and comprises the following steps:

s1, draining water from the water storage box 2, so that the buoyancy component 21 is positioned at the top of the water storage box 2, the atomization component 23 is in a closed state, and the plug 121 on the baffle plate 12 can penetrate through the through hole 11 to be ejected out of the water baffle plate 1;

s2a, releasing water flow in the water storage box 2 by starting the flushing assembly 22, wherein the reduction of the water flow drives the buoyancy assembly 21 to descend, so that the baffle plate 12 and the atomization assembly 23 which are in transmission connection with the buoyancy assembly 21 are driven to move;

s2b, humidifying the environment through the atomization assembly 23, so that flying and scattering are reduced, and the sedimentation of flying and scattering is accelerated;

s2c, the fly ash accumulated on the plug 121 can be cleaned through the movement of the baffle plate 12, and meanwhile, the flushing assembly 22 can release water flow along the water baffle plate 1, so that the fly ash accumulated on the water baffle plate 1 can be cleaned uniformly;

s3, repeating the steps of S2a, S2b and S2c until water storage in the water storage box 2 is stopped.

The foregoing examples merely illustrate one or more embodiments of the invention, which are described in greater detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of the invention should be assessed as that of the appended claims.

Claims (10)

1. The adhering type partition device of the circular weft knitting machine comprises a plurality of water baffles (1) which are equidistantly and circumferentially arranged on the periphery of the weft knitting machine, and is characterized in that the water baffles (1) are obliquely arranged, a plurality of through holes (11) which are arranged in a rectangular array are formed in each water baffle (1), baffle plates (12) which can slide along the axial direction of the through holes (11) are arranged on the water baffles (1), plugs (121) which are the same in number with the through holes (11) and correspond to the through holes (11) one by one are arranged on the baffle plates (12), and the plugs (121) are in sliding fit with the through holes (11); the top of each water baffle (1) is provided with a water storage box (2), and the water storage box (2) is provided with a buoyancy component (21), an atomization component (23) for humidifying the environment and a flushing component (22) for flushing the water baffles (1) at regular time; the buoyancy component (21) is positioned in the water storage box (2), the buoyancy component (21) can slide along the vertical direction of the water storage box (2), and the buoyancy component (21) can float on water flow of the water storage box (2); the atomizing assembly (23) is positioned at the top of the water storage box (2); the flushing assembly (22) is positioned below the water storage box (2); the atomizing component (23) and the baffle plate (12) are in transmission connection with the buoyancy component (21).

2. The adhesion-type partition device of a circular weft knitting machine according to claim 1, wherein the flushing assembly (22) comprises a valve (221) and a U-shaped bent pipe (222), the valve (221) is arranged at the top of the water storage box (2), the bent pipe (222) is inverted inside the water storage box (2), a water outlet (223) is arranged at the bottom of the water storage box (2), one end of the bent pipe (222) is communicated with the water outlet (223), the other end of the bent pipe (222) is located beside the water outlet (223), and a gap is formed at the end part of the bent pipe away from the bottom of the water storage box (2).

3. A circular weft knitting machine adhesion type partition device according to claim 2, characterized in that both sides of the water deflector (1) are provided with baffles (13) extending in the length direction thereof, the flushing assembly (22) further comprises a first nozzle (224) with a flat mouth, and the first nozzle (224) is mounted below the water outlet (223) of the water storage box (2).

4. The adhesion type partition device of a circular weft knitting machine according to claim 2, wherein the atomizing assembly (23) comprises an atomizing nozzle (2311), a water suction pipe (231), an air inlet pipe (232), a piston (2321), a first connecting rod (2322) and a first spring (2323), the water suction pipe (231) is of an L-shaped structure, the water suction pipe (231) is arranged on the water storage box (2) in a vertical state, the atomizing nozzle (2311) is sleeved on the top of the water suction pipe (231), a connecting hole (2316) matched with the air inlet pipe (232) is formed in the center of the water suction pipe (231), the air inlet pipe (232) is fixedly connected to the connecting hole (2316) and communicated with the connecting hole, the piston (2321) is slidably arranged in the air inlet pipe (232), the first spring (2323) is arranged between the piston (2321) and the water suction pipe (231), the piston (2321) is elastically connected with the air inlet pipe (232) through the first spring (2323), and the first connecting rod (2322) is fixedly connected to the piston (2321) far away from the first spring (2323).

5. A circular weft knitting machine adhesion type partition device according to claim 4, characterized in that the atomizing assembly (23) further comprises a steel ball (2313) and a second spring (2314), a narrow opening (2312) which is radially retracted along the pipe of the suction pipe (231) is arranged below the suction pipe, the steel ball (2313) is matched with the narrow opening (2312), a mounting frame (2315) through which water can pass is arranged in the suction pipe (231), one end of the second spring (2314) is connected with the steel ball (2313), and the other end of the second spring (2314) is connected with the mounting frame (2315).

6. The adhesion-type partition device of a circular weft knitting machine according to claim 4, wherein the buoyancy component (21) comprises a stand column (211) and a buoyancy ring (212) capable of floating on the water surface, the stand column (211) is fixedly connected in the water storage box (2) in a vertical state, the buoyancy ring (212) is of a hollow structure, a plurality of raised strips (2111) encircling the stand column (211) are arranged on the stand column (211), the raised strips (2111) extend along the length direction of the raised strips, and grooves (2121) matched with the raised strips (2111) are formed in the inner wall of the buoyancy ring (212).

7. A circular weft knitting machine adhesion shut off device according to claim 6, characterized in that the buoyancy ring (212) is provided with a second connecting rod (213) hinged thereto, the second connecting rod (213) being hinged to the end of the first connecting rod (2322).

8. The adhesion type partition device of a circular weft knitting machine according to claim 7, wherein a first slide rail (2131) extending along the length direction of the second connecting rod (213) is arranged on the second connecting rod, a third connecting rod (24) capable of sliding along the horizontal direction is arranged at the top and the bottom of the water storage box (2), a fixing frame (25) is arranged between the two third connecting rods (24) on the outer wall of the water storage box (2), a fourth connecting rod (251) is arranged on the fixing frame (25), the middle part of the fourth connecting rod (251) is hinged with the fixing frame (25), a second slide rail (252) extending along the length direction of the second connecting rod is arranged at two ends of the fourth connecting rod (251), one end of the third connecting rod (24) positioned at the top of the water storage box (2) is in sliding fit with the first slide rail (2131), and the other end of the third connecting rod (24) is in sliding fit with the second slide rail (252); the top of baffle (12) is provided with slide bar (122), and the bottom of water storage box (2) is provided with can be along the gliding carriage (26) of the horizontal direction of water storage box (2), and the below of carriage (26) is provided with third slide rail (261) that mutually matches with slide bar (122), slide bar (122) and third slide rail (261) sliding fit, and wherein one end and second slide rail (252) sliding fit of third connecting rod (24) that are located the bottom of water storage box (2), its other end and carriage (26) fixed connection.

9. A circular weft knitting machine adhesion type partition device according to any one of claims 1-8, characterized in that the bottom of the water deflector (1) is also provided with a water receiving tank (14), the top of the water receiving tank (14) being provided with a filter screen (141).

10. A circular weft knitting machine fly eliminating method applied to the circular weft knitting machine adhesion type partition device according to any one of claims 1 to 9, characterized by comprising the steps of:

s1, draining water for the water storage box (2) to enable the buoyancy component (21) to be located at the top of the water storage box (2), enabling the atomization component (23) to be in a closed state, and enabling the plug (121) on the baffle plate (12) to penetrate through the through hole (11) and be ejected out of the water baffle plate (1);

s2a, releasing water flow in the water storage box (2) by starting the flushing component (22), wherein the reduction of the water flow drives the buoyancy component (21) to descend, so that the baffle plate (12) and the atomization component (23) which are in transmission connection with the buoyancy component (21) are driven to move;

s2b, humidifying the environment through an atomization assembly (23), so that flying and scattering are reduced, and sedimentation of flying and scattering is accelerated;

s2c, the fly accumulated on the plug (121) can be cleaned through the movement of the baffle plate (12), and meanwhile, the flushing assembly (22) can release water flow along the water baffle plate (1) so that the fly accumulated on the water baffle plate (1) can be cleaned uniformly;

s3, repeating the steps of S2a, S2b and S2c until water storage in the water storage box (2) is stopped.