CN121067212A - Water and oil removing device for guide rail rolling line - Google Patents

Abstract

This application discloses a dewatering and lubrication device for a guide rail rolling line, relating to the field of automotive guide rail production. It includes a conveyor table with a water collection hopper fixed on it. A dewatering conveyor frame is fixed inside the water collection hopper, and a high-pressure blowpipe is fixed on the dewatering conveyor frame. Three lubrication conveyor frames are fixed on the side of the conveyor table away from the water collection hopper, one of which has a lubrication pipe fixed on it. An auxiliary dewatering mechanism is provided between the dewatering conveyor frames and the lubrication conveyor frames. An auxiliary oscillation mechanism is provided on the side of the auxiliary dewatering mechanism closest to the dewatering conveyor frame. The auxiliary dewatering mechanism drives the auxiliary oscillation mechanism to oscillate the guide rail, causing it to vibrate slightly. The guide rail then passes through the dewatering mechanism's adsorption, further reducing the possibility of water residue in the guide rail. This reduces the likelihood of water in the guide rail causing rust during subsequent lubrication due to oil-water contact.

Description

Water and oil removing device for guide rail rolling line

Technical Field

The application relates to the field of production of guide rails for automobiles, in particular to a water and oil removing device for guide rail rolling lines.

Background

The guide rail is used as a precise transmission part, is widely applied to automobiles, numerical control machine tools and automatic equipment, and has the surface quality and rust resistance which directly affect the service life and the operation precision of the equipment. The water removal and lubrication oiling after cleaning are key links for guaranteeing the corrosion resistance and the motion stability of the guide rail, and the storage life and the service performance of the finished guide rail are directly determined.

At present, a guide rail rolling line generally adopts high-pressure air blowing as a main water removal means and is assisted with an oil dripping coating device to realize surface lubrication. Specifically, the guide rail enters a blow-drying area after passing through a cleaning station, surface clear water is blown off by high-speed air flow generated by a high-pressure air pump, then the guide rail enters an oiling area, lubricating oil is dripped on the surface of the guide rail through a guide pipe, and an oil film is formed by rolling and expanding of a conveying wheel.

The high-pressure gas has limited effect on structural dead angles such as grooves, threaded holes and joint surfaces, residual moisture is difficult to thoroughly remove, if an invisible water film exists on the surface of a guide rail in the oil dripping process, an oil-water mixed solution is extremely easy to form, the lubricating effect is reduced, the metal oxidation is more likely to be accelerated, and the guide rail is corroded in the storage or use initial stage.

Disclosure of Invention

The application aims to solve the problems that the high-pressure gas provided in the background art has limited effect on structural dead angles such as grooves, threaded holes and joint surfaces, residual moisture is difficult to thoroughly remove, oil-water mixed liquid is extremely easy to form if invisible water films exist on the surfaces of guide rails in the oil dripping process, the lubrication effect is reduced, metal oxidation is more likely to be accelerated, and the guide rails are corroded at the initial stage of storage or use.

The application adopts the following technical scheme for realizing the purposes:

The utility model provides a dewatering and oiling device of guide rail rolling line, includes the delivery platform, be fixed with the water catch bowl on the delivery platform, water catch bowl internal fixation has the dewatering carriage, be fixed with the high-pressure blowpipe on the dewatering carriage, be fixed with the dry blowpipe of two symmetries on the dewatering carriage, one side of delivery platform is fixed with high-pressure air pump, high-pressure blowpipe, dry blowpipe all utilize pipe connection with the high-pressure air pump, one side that the delivery platform kept away from the water catch bowl is fixed with three and refuels the carriage, and is three refuel the carriage and be slope distribution, one of them be fixed with the oil filler pipe on the carriage, one side of delivery platform is fixed with the oil drum frame, be fixed with the oil drum on the oil drum frame, the oil drum is linked together with the oil filler pipe, be fixed with control valve on the oil filler pipe, be provided with supplementary dewatering mechanism between dewatering carriage and the oil drum frame, supplementary dewatering mechanism is close to one side of dewatering carriage and is provided with supplementary oscillating mechanism.

Through adopting above-mentioned technical scheme, supplementary dewatering mechanism drives supplementary oscillating mechanism and oscillates the guide rail, the guide rail produces tiny vibration, shake out the water that probably does not blow off in the guide rail dead angle, then the guide rail is through supplementary dewatering mechanism's absorption, thereby can further reduce the possibility that appears water residue in the guide rail, when reducing the guide rail to have water to lead to follow-up oiling, oil and water contact formation oil-water mixture, influence the effect of guide rail coating, the guide rail lacks the protection of oil, lead to the rusty possibility of guide rail, can clear away the debris on guide rail surface simultaneously, reduce the possibility that has debris to remain and influence guide rail coating quality on the guide rail.

Further, be fixed with the dewatering frame on the transport table, the dewatering frame is the U type, be fixed with two symmetrical backup pads on the dewatering frame, two be provided with two symmetrical sponge rollers between the backup pad, one of them be provided with on the sponge roller with the protruding corresponding arch of guide rail recess, another be provided with on the sponge roller with the protruding corresponding recess of guide rail, be provided with the support coupling assembling between the both ends of sponge roller and two backup pads, be provided with on the dewatering frame and collect the subassembly.

Through adopting above-mentioned technical scheme, let ponding on the guide rail by highly-compressed air blow behind, let the guide rail pass through two sponge rollers, let the sponge roller wrap up the guide rail, let the sponge roller absorb the remaining water on the guide rail to can further reduce the possibility of remaining water on the guide rail, reduce water remain on the guide rail with the oil contact of follow-up coating, form the oil-water mixture, influence the possibility of oil coating effect on the guide rail.

Further, the support coupling assembling includes two symmetries and sets up the supporting shoe at the sponge roller both ends, the supporting shoe rotates with the sponge roller to be connected, be fixed with the sliding block on the supporting shoe, set up the sliding tray corresponding with the sliding block in the backup pad, the sliding block is located the sliding tray in the backup pad, and with backup pad sliding connection, be provided with supporting spring between sliding block and the backup pad, supporting spring's both ends are fixed connection with sliding block, backup pad.

Through adopting above-mentioned technical scheme, under supporting spring's promotion, let the direction extrusion of sliding block towards the guide rail, let the supporting shoe on the sliding block drive the sponge roller and extrude towards the guide rail to can let the sponge roller fully contact with the guide rail, conveniently let the water on the guide rail be absorbed by the sponge roller.

Further, collection subassembly includes two symmetries setting up the collection cabin between two backup pads, two all be fixed with conflict flat mouth on the collection cabin, conflict flat mouth is linked together with the collection cabin, two conflict flat mouth on the collection cabin is corresponding with two sponge rollers, the both ends and the supporting shoe fixed connection that correspond of collection cabin, two all be fixed with spiral flexible pipe on the collection cabin, one side of carrying the platform is fixed with the aspirator, the pipeline fixed connection of spiral flexible pipe and aspirator to communicate.

Through adopting above-mentioned technical scheme, let the conflict flat mouth on the collection cabin conflict on the sponge roller, let the water suction of conflict flat mouth on with the sponge roller away to can reduce the possibility that the sponge roller appears saturating, reduce the possibility that water on the sponge roller contacts with the guide rail once more simultaneously.

Further, the edge of the abutting flat mouth is abutted against the sponge roller, and one side of the abutting flat mouth is subjected to lifting treatment.

Through adopting above-mentioned technical scheme, will contradict one side of flat mouth and do raise the processing, let the one side of raising not contact with the sponge roller, the sponge roller another side is contradicted with the sponge roller to can let when contradicting flat mouth and extrude the water on the sponge, can let water first time by the suction away, reduce extruded water outside contradicting flat mouth, can follow the sponge roller and fall the possibility on the guide rail again.

Further, the auxiliary oscillating mechanism comprises two oscillating rods symmetrically arranged between the two supporting plates, two supporting rods are fixed at two ends of each oscillating rod, the two supporting rods are fixedly connected with corresponding supporting blocks, an oscillating assembly is arranged on each oscillating rod, and a driving assembly is arranged between one supporting block and each oscillating rod.

Through adopting above-mentioned technical scheme, let the guide rail drive sponge roller rotate, let the sponge roller drive assembly, drive assembly drives the oscillating assembly, let oscillating assembly let the oscillating bar produce the vibration, let the oscillating bar drive guide rail vibration to can let the water in the guide rail dead angle come out by the vibration, reduce the remaining water in dead angle in the guide rail, convenient follow-up is absorbed by the sponge roller.

Further, the oscillating assembly comprises a rotating shaft arranged on the oscillating rod, the two ends of the rotating shaft are respectively connected with a connecting rod in a rotating mode, the two connecting rods are fixedly connected with corresponding supporting blocks, an oscillating gear is fixed on the rotating shaft, an oscillating block is fixed on the oscillating rod, and the oscillating gear is meshed with the oscillating block.

Through adopting above-mentioned technical scheme, let the axis of rotation drive oscillating gear rotation under the support of two connecting rods, oscillating gear drives the oscillating piece to can conveniently let the oscillating bar vibration that two bracing pieces supported, let the oscillating bar strike the guide rail of process.

Further, the driving assembly comprises a first driving gear fixed at one end of the sponge roller, a second driving gear is fixed on the rotating shaft, and a driving chain is connected between the first driving gear and the second driving gear in a transmission manner.

Through adopting above-mentioned technical scheme, a drive chain is driven to drive gear, and drive chain drives drive gear two, and drive gear two drives the axis of rotation and rotates to can let the sponge roller when the rotation, let the oscillating bar keep synchronous vibration.

In summary, the present application includes at least one of the following advantages;

1. According to the application, the guide rail passes through the space between the two sponge rollers, the two sponge rollers are abutted against the guide rail under the support of the support connecting assembly, the protruding part of one sponge roller corresponds to the groove on the guide rail, then the groove on the other sponge roller corresponds to the protrusion of the guide rail, so that the two sponge rollers can completely wrap the guide rail, when the guide rail moves, the guide rail drives the two sponge rollers to rotate, the sponge rollers rotate to contact with the guide rail, the residual water on the guide rail is absorbed, when the sponge rollers rotate to one side far away from the guide rail, the collecting assembly scrapes and extrudes the sponge rollers, the absorbed water on the sponge rollers is extruded, the extruded water is sucked and collected, and the water on the guide rail is further removed, so that the possibility of further reducing the residual water on the guide rail is achieved, the contact of the water residual on the guide rail with the oil coated subsequently is reduced, the possibility of affecting the effect of the oil-water mixture on the guide rail is formed, and the possibility of affecting the coating quality of the guide rail due to the impurity residue on the surface of the guide rail is reduced.

2. According to the application, the sponge roller drives the first driving gear to rotate while the sponge roller rotates, the driving gear drives the driving chain, the driving chain drives the second driving gear, the second driving gear drives the rotating shaft to rotate, the rotating shaft drives the oscillating gear, teeth on the oscillating gear pass through the oscillating block, the oscillating block drives the oscillating rod to vibrate rapidly under the support of the two supporting rods, the two oscillating rods vibrate the passing guide rail, and water at dead angles of the guide rail of the passing two oscillating rods is vibrated out, so that the purpose that water in dead angles of the guide rail can be oscillated out, residual water at dead angles in the guide rail is reduced, the subsequent absorption by the sponge roller is facilitated, and the water removing effect is further improved is achieved.

3. According to the application, one side of the abutting flat nozzle is lifted, so that the lifted side is not contacted with the sponge roller, the other side of the sponge roller is abutted against the sponge roller, and the sponge roller is extruded, so that when the sponge roller rotates, the sponge roller is contacted with the abutting flat nozzle after passing through the lifted side, the abutting flat nozzle extrudes moisture on the sponge roller, and when the moisture on the sponge roller is extruded, the moisture is positioned in the abutting flat nozzle and is directly sucked away after the water is extruded, thereby achieving the purposes of enabling the abutting flat nozzle to suck away the water at the first time and reducing the possibility that the extruded water can fall on the guide rail again along the sponge roller outside the abutting flat nozzle.

Drawings

FIG. 1 is a schematic view of a first perspective structure of a water and oil removal device of the present application;

FIG. 2 is a schematic view of a second perspective structure of the water and oil removing device of the present application;

FIG. 3 is a schematic perspective view of an auxiliary water removal mechanism according to the present application;

FIG. 4 is a schematic view of a split structure of the support connection assembly of the present application;

FIG. 5 is a schematic view of the collection assembly of the present application in a disassembled configuration;

fig. 6 is a schematic perspective view of an auxiliary oscillating mechanism in the present application.

Reference numerals illustrate:

1. Conveying table, 2, water collecting bucket, 3, water removing conveying frame, 4, high-pressure blowing pipe, 5, drying blowing pipe, 6, auxiliary water removing mechanism, 61, water removing frame, 62, supporting plate, 63, sponge roller, 64, supporting connecting component, 641, supporting block, 642, sliding block, 643, supporting spring, 65, collecting component, 651, collecting cabin, 652, abutting flat nozzle, 653, spiral telescopic pipe, 654, aspirator, 7, auxiliary oscillating mechanism, 71, supporting rod, 72, oscillating rod, 73, oscillating component, 731, connecting rod, 732, rotating shaft, 733, oscillating gear, 734, oscillating block, 74, driving component, 741, driving gear one, 742, driving gear two, 743, driving chain, 8, oil adding conveying frame, 9, oil adding pipe, 10, oil adding barrel, 11, oil barrel frame, 12, high-pressure air pump.

Detailed Description

The application is described in further detail below with reference to fig. 1-6.

The embodiment of the application discloses a water and oil removing device for a guide rail rolling line.

Referring to fig. 1, fig. 2 and fig. 3, the dewatering and oiling device of guide rail rolling line comprises a conveying table 1, be fixed with water collecting bucket 2 on the conveying table 1, water collecting bucket 2 internal fixation has dewatering carriage 3, be fixed with high-pressure blowpipe 4 on the dewatering carriage 3, be fixed with two symmetrical dry blowpipes 5 on the dewatering carriage 3, one side of conveying table 1 is fixed with high-pressure air pump 12, high-pressure blowpipe 4, dry blowpipe 5 all utilizes pipe connection with high-pressure air pump 12, one side that conveying table 1 kept away from water collecting bucket 2 is fixed with three refueling carriage 8, three refueling carriage 8 is the slope and distributes, be fixed with oil filler pipe 9 on one of them refueling carriage 8, one side of conveying table 1 is fixed with oil tank frame 11, be fixed with oil filler pipe 10 on the oil tank frame 11, oil filler pipe 10 is linked together with oil filler pipe 9, be fixed with control valve on the oil filler pipe 9, be provided with supplementary dewatering mechanism 6 between dewatering carriage 3 and the carriage 8, supplementary dewatering mechanism 6 is close to one side of dewatering carriage 3 is provided with supplementary oscillating mechanism 7.

When the guide rail rolling line is used for the dewatering and oiling device, firstly, the conveying table 1 is arranged at the position of the guide rail rolling line, at which the guide rail is cleaned, the guide rail passes through the dewatering conveying frame 3, the dewatering conveying frame 3 is rotationally connected with the conveying guide wheel, the guide rail moves under the support of the conveying guide wheel, the high-pressure blowing pipe 4 inclines towards the moving guide rail, the high-pressure air pump 12 conveys high-pressure air into the high-pressure blowing pipe 4, the high-pressure air blows water in the guide rail groove to the water collecting hopper 2, the guide rail continuously moves, meanwhile, the high-pressure air pump 12 conveys the air to the drying blowing pipe 5, the guide rail passes through the two drying blowing pipes 5 which are symmetrical up and down, the air blown out by the drying blowing pipe 5 further blows residual water on the guide rail, the guide rail is preliminarily dewatered, the guide rail passes through the auxiliary oscillating mechanism 7 and the auxiliary dewatering mechanism 6, the guide rail drives the auxiliary dewatering mechanism 6 in the moving process, the auxiliary dewatering mechanism 6 is contacted with the guide rail, residual water on the guide rail is sucked away when the guide rail moves, the residual water on the guide rail is further reduced, the auxiliary dewatering mechanism 6 drives the auxiliary oscillating mechanism 7 when the guide rail moves to drive the auxiliary dewatering mechanism 6, the auxiliary oscillating mechanism 7 generates high-speed oscillation, the guide rail passes through the auxiliary oscillating mechanism 7, the auxiliary oscillating mechanism 7 oscillates residual water at dead angles of the guide rail out, the residual water is sucked away by the auxiliary dewatering mechanism 6 when the guide rail passes through the auxiliary dewatering mechanism 6, the guide rail moves along the three oiling conveying frames 8, when the guide rail is about to enter the oiling conveying frames 8, oil in the oiling barrel 10 is dripped along the oiling pipe 9 from the end head of the oiling pipe 9, the oil is dripped in the groove of the guide rail, the guide rail moves under the support of the conveying guide wheels on the oiling conveying frames when the guide rail passes through the oiling conveying station, in the moving process, oil dropping on the guide rail is driven by the conveying guide roller on the oiling conveying frame 8, oil is uniformly distributed on the guide rail, finally, the guide rail moves to the tail end of the guide rail rolling line to be cut, surface clear water is blown off through the guide rail by the high-pressure blowing pipe 4, the guide rail is sequentially vibrated by the auxiliary oscillating mechanism 7 and the auxiliary dewatering mechanism 6, the auxiliary oscillating mechanism 7 oscillates the guide rail, fine vibration is generated on the guide rail, water possibly not blown off in dead angles of the guide rail is vibrated out, then the guide rail is adsorbed by the auxiliary dewatering mechanism 6, so that the possibility of water residue in the guide rail can be further reduced, the possibility of oil and water contact to form an oil-water mixture when the guide rail has water to cause follow-up oiling is reduced, the effect of guide rail coating is influenced, the guide rail lacks oil protection, the possibility of rusting the guide rail is reduced, sundries on the surface of the guide rail can be cleared, and the possibility that sundries remain on the guide rail affect the coating quality of the guide rail is reduced.

Referring to fig. 1, 2 and 3, a dewatering frame 61 is fixed on a conveying table 1, the dewatering frame 61 is in a U shape, two symmetrical supporting plates 62 are fixed on the dewatering frame 61, two symmetrical sponge rollers 63 are arranged between the two supporting plates 62, a protrusion corresponding to a guide rail groove is arranged on one sponge roller 63, a groove corresponding to the guide rail protrusion is arranged on the other sponge roller 63, supporting connection assemblies 64 are arranged between two ends of the sponge roller 63 and the two supporting plates 62, and a collecting assembly 65 is arranged on the dewatering frame 61.

The guide rail passes between two sponge rollers 63, two sponge rollers 63 are supported by a supporting connection assembly 64 and are abutted against the guide rail, the protruding portion on one sponge roller 63 corresponds to the groove on the guide rail, then the groove on the other sponge roller 63 corresponds to the protrusion of the guide rail, two sponge rollers 63 can wrap the guide rail completely, when the guide rail moves, the guide rail drives two sponge rollers 63 to rotate, the sponge rollers 63 rotate to be in contact with the guide rail, residual water on the guide rail is absorbed, when the sponge rollers 63 rotate to one side far away from the guide rail, the collecting assembly 65 scrapes and extrudes the sponge rollers 63, the absorbed water on the sponge rollers 63 is extruded, the extruded water is sucked and collected, the water on the guide rail is further removed, after accumulated water on the guide rail is blown down by high-pressure air, the guide rail passes through the two sponge rollers 63, the sponge rollers 63 wrap the guide rail, the residual water on the guide rail is absorbed by the sponge rollers 63, the possibility of residual water on the guide rail can be further reduced, the residual water on the guide rail is contacted with subsequent coating oil can be reduced, and the coating oil can be influenced on the guide rail.

Referring to fig. 3 and 4, the support connection assembly 64 includes two support blocks 641 symmetrically disposed at two ends of the sponge roller 63, the support blocks 641 are rotatably connected with the sponge roller 63, a sliding block 642 is fixed on the support blocks 641, a sliding groove corresponding to the sliding block 642 is formed in the support plate 62, the sliding block 642 is located in the sliding groove of the support plate 62 and is slidably connected with the support plate 62, a support spring 643 is disposed between the sliding block 642 and the support plate 62, and two ends of the support spring 643 are fixedly connected with the sliding block 642 and the support plate 62.

The supporting blocks 641 at two ends of the sponge roller 63 support the sponge roller 63, the sliding block 642 supports the supporting blocks 641, the sliding block 642 slides on the supporting plate 62, meanwhile, under the pushing of the supporting spring 643, the sliding block 642 extrudes towards the direction of the guide rail, the supporting blocks 641 on the sliding block 642 drive the sponge roller 63 to extrude towards the guide rail, the sponge roller 63 tightly props against the guide rail, the supporting blocks 641 on the sliding block 642 are utilized to support the sponge roller 63, the sliding block 642 extrudes towards the guide rail under the pushing of the supporting spring 643, and accordingly the sponge roller 63 can be fully contacted with the guide rail, and water on the guide rail is conveniently sucked away by the sponge roller 63.

Referring to fig. 3 and 5, the collecting assembly 65 includes two collecting chambers 651 symmetrically disposed between two supporting plates 62, each of the two collecting chambers 651 is fixedly provided with a flat interference nozzle 652, the flat interference nozzle 652 is communicated with the collecting chamber 651, the flat interference nozzle 652 on the two collecting chambers 651 corresponds to the two sponge rollers 63, two ends of the collecting chamber 651 are fixedly connected with corresponding supporting blocks 641, each of the two collecting chambers 651 is fixedly provided with a spiral telescopic tube 653, one side of the conveying table 1 is fixedly provided with an aspirator 654, and the spiral telescopic tube 653 is fixedly connected with a pipeline of the aspirator 654 and is communicated with the pipeline.

The collection cabin 651 fixed between the two supporting blocks 641 supports the abutting flat mouth 652, the abutting flat mouth 652 abuts against the sponge roller 63, the aspirator 654 is started, the aspirator 654 is a high-power dust collector, the collection cabin 651 generates strong negative pressure, water on the sponge roller 63 is sucked away from the abutting flat mouth 652, the sucked water enters the aspirator 654 along the spiral telescopic tube 653, the sponge roller 63 can continuously keep in a state to be saturated, when the sponge roller 63 contacts with the guide rail, water on the guide rail can be continuously absorbed, the abutting flat mouth 652 on the collection cabin 651 abuts against the sponge roller 63, the abutting flat mouth 652 sucks water on the sponge roller 63, and therefore the possibility that the sponge roller 63 is saturated can be reduced, and the possibility that water on the sponge roller 63 contacts with the guide rail again can be reduced.

Referring to fig. 3 and 5, the edge of the abutting flat nozzle 652 abuts against the sponge roller 63, and one side of the abutting flat nozzle 652 is raised.

The sponge roller 63 is pressed against the sponge roller 63 by the sponge roller 63, the sponge roller 63 is pressed against the sponge roller 63, the sponge roller 63 is contacted with the pressing flat nozzle 652 after being pressed against the sponge roller 63 after being pressed against the sponge roller 652 when rotating, the pressing flat nozzle 652 is used for pressing out water on the sponge roller 63, the pressing flat nozzle 652 is positioned in the sponge roller 63 and is directly sucked away after the water is pressed out, the pressing flat nozzle 652 is pressed against the sponge roller 63 after being pressed out, and therefore the pressing flat nozzle 652 can be pressed against the sponge roller 63, the first time of the water can be sucked away, and the possibility that the pressed water can fall on a guide rail again along the sponge roller 63 outside the pressing flat nozzle 652 is reduced.

Referring to fig. 3 and 6, the auxiliary oscillating mechanism 7 includes two oscillating rods 72 symmetrically disposed between two support plates 62, support rods 71 are fixed at both ends of the two oscillating rods 72, the two support rods 71 are fixedly connected with corresponding support blocks 641, an oscillating assembly 73 is disposed on the oscillating rod 72, and a driving assembly 74 is disposed between one of the support blocks 641 and the oscillating rod 72.

Before the guide rail is about to enter two sponge rollers 63, let the guide rail pass between two oscillating bars 72, let the guide rail pass between two sponge rollers 63 again, oscillating bar 72 is on the guide rail under the support of bracing piece 71, oscillating bar 72 is the rubber pole, bracing piece 71 is the sheetmetal that has elasticity, when the guide rail removes and drives two sponge rollers 63 rotation, sponge roller 63 drives actuating assembly 74, actuating assembly 74 drives oscillating assembly 73, oscillating assembly 73 carries out quick vibration to oscillating bar 72, oscillating bar 72 is contradicted on the guide rail and drives the guide rail and carry out quick vibration, let the water in the guide rail dead angle come out by the oscillation, drive sponge roller 63 through letting the guide rail rotate, let sponge roller 63 drive actuating assembly 74, actuating assembly 74 drives oscillating assembly 73, let oscillating assembly 73 let oscillating bar 72 produce the vibration, let oscillating bar 72 drive the guide rail vibration, thereby can let the water in the guide rail dead angle be oscillated out, reduce the water that remains in the guide rail, convenient follow-up is absorbed by sponge roller 63.

Referring to fig. 3 and 6, the oscillating assembly 73 includes a rotation shaft 732 provided on the oscillating bar 72, both ends of the rotation shaft 732 are rotatably connected with connection rods 731, the two connection rods 731 are fixedly connected with corresponding support blocks 641, an oscillating gear 733 is fixed on the rotation shaft 732, an oscillating block 734 is fixed on the oscillating bar 72, and the oscillating gear 733 is engaged with the oscillating block 734.

Let axis of rotation 732 under the support of two connecting rods 731, drive assembly 74 drive axis of rotation 732 rotation, axis of rotation 732 drives oscillating gear 733 rotation, tooth on the oscillating gear 733 passes through on oscillating block 734, oscillating block 734 is triangle-shaped, let oscillating block 734 vibrate fast when oscillating gear 733 rotates fast, oscillating block 734 drives oscillating bar 72 vibration, drive oscillating gear 733 rotation through letting axis of rotation 732 under the support of two connecting rods 731, oscillating gear 733 drives oscillating block 734, thereby can conveniently let oscillating bar 72 vibration that two bracing pieces 71 supported, let oscillating bar 72 beat the guide rail of passing through.

Referring to fig. 3 and 6, the driving assembly 74 includes a first driving gear 741 fixed to one end of the sponge roller 63, a second driving gear 742 fixed to the rotating shaft 732, and a driving chain 743 drivingly connected between the first driving gear 741 and the second driving gear 742. When the sponge roller 63 rotates, the sponge roller 63 drives the first driving gear 741 to rotate, the first driving gear 741 drives the driving chain 743, the driving chain 743 drives the second driving gear 742, the second driving gear 742 drives the rotating shaft 732 to rotate, the rotating shaft 732 drives the oscillating gear 733, teeth on the oscillating gear 733 pass through the oscillating block 734, and the sponge roller 63 and the rotating shaft 732 are connected by using the first driving gear 741, the second driving gear 742 and the driving chain 743, so that the sponge roller 63 can keep the oscillating rod 72 vibrating synchronously when rotating.

Working principle: when the water and oil removing device using the guide rail rolling line is used, the guide rail passes through the water removing conveying frame 3 after cleaning, the high-pressure blowing pipe 4 inclines towards the moving guide rail, the high-pressure air pump 12 supplies high-pressure air to the high-pressure blowing pipe 4, the high-pressure air blows water in the guide rail groove to the water collecting bucket 2, the guide rail continues to move and passes through between the two oscillating rods 72, passes through the two oscillating rods 72 and then passes through between the two sponge rollers 63, the guide rail continues to move, the two sponge rollers 63 are abutted against the guide rail under the pushing of the supporting springs 643, the convex part on one sponge roller 63 corresponds to the groove on the guide rail, then the groove on the other sponge roller 63 corresponds to the convex part of the guide rail, the guide rail drives the two sponge rollers 63 to rotate in the moving process to contact with the guide rail, residual water on the guide rail is absorbed, when the sponge roller 63 rotates to one side far away from the guide rail, the aspirator 654 is started, the collecting cabin 651 generates stronger negative pressure, water on the sponge roller 63 is sucked away from the abutting flat mouth 652, the sucked water enters the aspirator 654 along the spiral telescopic tube 653, the sponge roller 63 can keep a state to be saturated continuously, when the sponge roller 63 contacts with the guide rail, the sponge roller 63 can absorb water on the guide rail continuously, the sponge roller 63 drives the driving gear one 741 to rotate while the sponge roller 63 rotates, the driving gear one 741 drives the driving chain 743, the driving gear two 742 drives the driving gear two 742 to rotate the rotating shaft 732, the rotating shaft 732 drives the oscillating gear 733, teeth on the oscillating gear 733 pass through the oscillating block 734, the oscillating block 734 drives the oscillating rod 72 to vibrate rapidly under the support of the two support rods 71, let the water at the guide rail dead angle of two oscillating bars 72 poles of process be shaken out, the guide rail is after accomplishing the cleanness, let the guide rail continue to remove, the guide rail is along three refueling carriage 8 removal, when the guide rail is about to get into in the refueling carriage 8, let the oil in the oil drum 10 along the oil pipe 9, drip from the end of oil pipe 9, let the oil drop fall in the recess of guide rail, the guide rail is when refueling the transfer station in process, the guide rail removes under the support of the transport guide pulley on the refueling protective feeding frame, the oil of drip on the guide rail in the in-process of removal is driven by the transport guide roller on the refueling carriage 8, let oil evenly distributed on the guide rail, the guide rail removes the end of guide rail rolling line and decides at last.

Claims (8)

1. A dewatering and lubrication device for a guide rail rolling line, comprising a conveyor platform (1), characterized in that: a water collection hopper (2) is fixed on the conveyor platform (1), a dewatering conveyor frame (3) is fixed inside the water collection hopper (2), a high-pressure blowpipe (4) is fixed on the dewatering conveyor frame (3), two symmetrical drying blowpipes (5) are fixed on the dewatering conveyor frame (3), a high-pressure air pump (12) is fixed on one side of the conveyor platform (1), the high-pressure blowpipe (4) and the drying blowpipe (5) are both connected to the high-pressure air pump (12) via pipes, and three lubrication devices are fixed on the side of the conveyor platform (1) away from the water collection hopper (2). Oil conveying frame (8), three oil conveying frames (8) are distributed at an angle, one of the oil conveying frames (8) is fixed with an oil pipe (9), an oil drum rack (11) is fixed on one side of the conveying platform (1), an oil drum (10) is fixed on the oil drum rack (11), the oil drum (10) is connected to the oil pipe (9), a control valve is fixed on the oil pipe (9), an auxiliary water removal mechanism (6) is provided between the water removal conveying frame (3) and the oil conveying frame (8), and an auxiliary oscillation mechanism (7) is provided on the side of the auxiliary water removal mechanism (6) near the water removal conveying frame (3). 2. The dewatering and lubrication device for the guide rail rolling line according to claim 1, characterized in that: a dewatering frame (61) is fixed on the conveying table (1), the dewatering frame (61) is U-shaped, two symmetrical support plates (62) are fixed on the dewatering frame (61), two symmetrical sponge rollers (63) are arranged between the two support plates (62), one of the sponge rollers (63) is provided with a protrusion corresponding to the guide rail groove, the other sponge roller (63) is provided with a groove corresponding to the guide rail protrusion, a support connection assembly (64) is provided between the two ends of the sponge roller (63) and the two support plates (62), and a collection assembly (65) is provided on the dewatering frame (61). 3. The dewatering and lubrication device for the guide rail rolling line according to claim 2, characterized in that: the support connection assembly (64) includes two support blocks (641) symmetrically arranged at both ends of the sponge roller (63), the support blocks (641) are rotatably connected to the sponge roller (63), a sliding block (642) is fixed on the support block (641), a sliding groove corresponding to the sliding block (642) is opened on the support plate (62), the sliding block (642) is located in the sliding groove on the support plate (62) and is slidably connected to the support plate (62), a support spring (643) is provided between the sliding block (642) and the support plate (62), and both ends of the support spring (643) are fixedly connected to the sliding block (642) and the support plate (62). 4. The dewatering and lubrication device for the guide rail rolling line according to claim 3, characterized in that: the collection assembly (65) includes two collection chambers (651) symmetrically arranged between two support plates (62), each of the two collection chambers (651) is fixed with abutting flat nozzle (652), the abutting flat nozzle (652) is connected to the collection chamber (651), the abutting flat nozzle (652) on the two collection chambers (651) corresponds to two sponge rollers (63), both ends of the collection chamber (651) are fixedly connected to the corresponding support block (641), each of the two collection chambers (651) is fixed with a spiral telescopic tube (653), a suction device (654) is fixed on one side of the conveying table (1), the spiral telescopic tube (653) is fixedly connected to the pipe of the suction device (654) and communicates with it. 5. The dewatering and lubrication device for the guide rail rolling line according to claim 4, characterized in that: the edge of the contacting flat nozzle (652) abuts against the sponge roller (63), and one side of the contacting flat nozzle (652) is raised. 6. The dewatering and lubrication device for the guide rail rolling line according to claim 2, characterized in that: the auxiliary oscillation mechanism (7) includes two oscillation rods (72) symmetrically arranged between two support plates (62), both ends of the two oscillation rods (72) are fixed with support rods (71), the two support rods (71) are fixedly connected with corresponding support blocks (641), an oscillation component (73) is provided on the oscillation rod (72), and a drive component (74) is provided between one of the support blocks (641) and the oscillation rod (72). 7. The dewatering and lubrication device for the guide rail rolling line according to claim 6, characterized in that: the oscillation assembly (73) includes a rotating shaft (732) disposed on the oscillation rod (72), both ends of the rotating shaft (732) are rotatably connected to connecting rods (731), the two connecting rods (731) are fixedly connected to the corresponding support blocks (641), an oscillation gear (733) is fixed on the rotating shaft (732), an oscillation block (734) is fixed on the oscillation rod (72), and the oscillation gear (733) meshes with the oscillation block (734). 8. The dewatering and lubrication device for the guide rail rolling line according to claim 7, characterized in that: the driving assembly (74) includes a first driving gear (741) fixed at one end of the sponge roller (63), a second driving gear (742) fixed on the rotating shaft (732), and a driving chain (743) drivingly connecting the first driving gear (741) and the second driving gear (742).