CN212502700U - Auxiliary feeding conveying device of heating furnace - Google Patents

Abstract

The utility model discloses a conveyor is assisted in unloading of heating furnace belongs to the forged technical field of heating furnace, and it includes receiving platform and transportation subassembly, and the receiving platform level is fixed in the heating furnace exit, and the transportation subassembly includes slide and transportation piece, the slide slope sets up to its one end and receiving platform fixed connection, the other end are fixed with the horizontally transition way, and the transition way end is fixed with the hoistway, and the terminal height with the workstation of next process of hoistway, transportation piece set up on transition way and hoistway for transport the forging. The staff dials the forging to the take-up table for the forging gets into the slide, and on the slope effect gliding of slide moved to the transition way, then started the transportation piece, made transportation piece transportation forging to lifting way end, owing to adopted the automatic transportation mode of transportation piece and slide to replace the mode of manual centre gripping, consequently reduced staff's the amount of labour, thereby reduced staff's fatigue.

Description

Auxiliary feeding conveying device of heating furnace

Technical Field

The utility model relates to a forged technical field of heating furnace, more specifically say, it relates to a conveyor is assisted in unloading of heating furnace.

Background

The heating furnace is a device (industrial furnace) for heating materials or workpieces (generally metal) to a rolling forging temperature, and is generally used for heating forgings cut by a sawing machine in the process of producing flange plates.

As shown in fig. 1, the prior art discloses a heating furnace, which includes a furnace body 100, a furnace chamber is arranged in the furnace body 100, furnace doors 110 for opening and closing the furnace chamber are arranged at two ends of the furnace chamber, a winch 120 is arranged on the furnace body 100, and the winch 120 provides power for the furnace doors 110. A frame 140 is fixed at one end of the furnace body 100, a horizontal feeding hydraulic cylinder 150 is hinged on the frame 140, a piston rod of the feeding hydraulic cylinder 150 is hinged with a push plate 160, and the power of the feeding hydraulic cylinder 150 is provided by a hydraulic pump. The frame 140 is fixed with a bearing plate 170, and the push plate 160 is connected with the bearing plate 170 in a sliding manner. During operation, a forged piece is placed on the bearing plate 170, the winch 120 is started to open the furnace door 110, the feeding hydraulic cylinder 150 is started, and the feeding hydraulic cylinder 150 stretches, so that the pushing plate 160 pushes the forged piece to be placed in the heating furnace, the winch 120 is started to close the furnace door 110, the heating furnace heats the forged piece, after heating is completed, the furnace door at the other end is opened, a worker pulls the forged piece out by using a hook, and then clamps the forged piece to the next process by using a clamp.

When the heating furnace is far away from the next process, because the forging temperature is higher and weight is heavier, therefore the staff is when pressing from both sides the forging to the next process with the clip, has increased staff's the amount of labour to increase staff's fatigue.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art exists, the utility model aims at providing a conveyor is assisted in unloading of heating furnace has and reduces staff's work volume to reduce the effect that the staff is tired.

The above object of the present invention can be achieved by the following technical solutions:

the utility model provides a conveyor is assisted in unloading of heating furnace, includes and holds platform and transportation subassembly, hold platform level fixation in heating furnace exit, the transportation subassembly includes slide and transportation piece, the slide slope sets up to its one end and holding platform fixed connection, the other end is fixed with the horizontally transition way, the transition way end is fixed with the lifting road, the end of lifting road and the workstation of next process are equal height, the transportation piece sets up on transition way and lifting road for transport the forging.

Through adopting above-mentioned technical scheme, the staff dials the forging to the take-up platform on, then for the forging gets into the slide, on the slope effect gliding of slide moved to the transition way, then starts transportation piece, makes transportation piece transportation forging to promote the way end, owing to adopted the automatic transportation mode of transportation piece and slide to replace the mode of manual centre gripping, consequently reduced staff's the amount of labour, thereby reduced staff's fatigue.

The present invention may be further configured in a preferred embodiment as: the transportation piece includes push pedal and motor, and the motor is fixed in on the lateral wall of transition way, the lateral wall all rotates on transition way and the lifting way has a plurality of sprockets, connects through chain drive between a plurality of sprockets, the chain slides with the lateral wall of transition way and lifting way and is connected, the output shaft and one of them sprocket coaxial fixed connection of motor, the movable plate sets up on the chain.

By adopting the technical scheme, initially, the movable plate is arranged at the starting end of the transition channel, after the forge piece is arranged on the transition channel, the motor is started, and the motor drives the chain wheel to rotate, so that the chain is driven to transmit, the movable plate pushes the forge piece to move, and the forge piece is transported to the tail end of the lifting channel.

The present invention may be further configured in a preferred embodiment as: the moving plate rotates on the chain.

By adopting the technical scheme, the purpose of setting the movable plate to rotate is that the movable plate is in a vertical state initially, so that the forge piece enters the transition passage from the slideway, and then the movable plate is rotated to be in a horizontal state, so that the movable plate can push the forge piece to move.

The present invention may be further configured in a preferred embodiment as: the chain is vertically fixed with the mounting panel, it has the gear to rotate on the mounting panel, the coaxial fixed connection of movable plate and gear, the vertical pneumatic cylinder that slides that is fixed with on the mounting panel, the vertical rack that is fixed with of piston rod of the pneumatic cylinder that slides, rack and gear engagement.

Through adopting above-mentioned technical scheme, start the pneumatic cylinder that slides, the pneumatic cylinder that slides stretches to drive sliding of rack, the rack drives the rotation of gear, thereby makes the gear drive push pedal be vertical state, the forging slides from the slide to the transition way on, then starts the pneumatic cylinder that slides, the pneumatic cylinder shrink that slides, makes the rack drive the rotation of gear, thereby makes the gear drive push pedal be the horizontality.

The present invention may be further configured in a preferred embodiment as: slag falling holes are formed in the transition passage and the lifting passage.

Through adopting above-mentioned technical scheme, set up the purpose that falls the slag hole for waste residue on the forging can fall out from falling the slag hole, can not deposit on the transition way.

The present invention may be further configured in a preferred embodiment as: a chute is fixed on the lower surface of the lifting channel, one end of the chute is fixedly connected with the lifting channel, and the other end of the chute is fixedly connected with the slag removing groove.

By adopting the technical scheme, the chute is arranged, so that the waste residues can be concentrated at the tail end of the transition passage, and the waste residues are conveniently concentrated.

The present invention may be further configured in a preferred embodiment as: the utility model discloses a clear slag groove, including the motor, the motor is arranged in the transition way in the clear slag groove, and the sprocket of keeping away from the motor is fixed with first belt pulley, the lateral wall in clear slag groove rotates has the horizontally dwang, and the dwang coaxial fixation has the second belt pulley, the second belt pulley passes through belt drive with first belt pulley and is connected, the dwang coaxial fixation has first bevel gear, clear slag groove lateral wall rotates there is the lead screw parallel with its length direction, threaded connection has clear slag plate on the lead screw, clear slag plate and clear slag groove bottom wall butt, the coaxial second bevel gear that is fixed with of lead screw one end, first bevel gear and second bevel gear meshing.

Through adopting above-mentioned technical scheme, when the motor started, when the movable plate promoted the forging and removed, first belt pulley drove the rotation of second belt pulley to make first bevel gear drive the rotation of second bevel gear, thereby make the lead screw rotate, thereby the removal of drive clear slag plate, clear slag plate piles up the waste residue in the transition way end.

The present invention may be further configured in a preferred embodiment as: and a pushing hydraulic cylinder vertical to the length of the slag removing groove is fixed on the side wall of one end of the slag removing groove in the length direction, an auxiliary plate is fixed on a piston rod of the pushing hydraulic cylinder, and the auxiliary plate is abutted against the bottom wall of the slag removing groove.

By adopting the technical scheme, after the waste residues are completely accumulated at the tail end of the transition channel, the pushing hydraulic cylinder is started to stretch, and the movable plate is driven to push the waste residues to the sliding groove.

To sum up, the utility model discloses a beneficial technological effect does:

firstly, the transport piece and the slide way are arranged, so that a worker dials the forge piece to the bearing table, then the forge piece enters the slide way, slides to the transition way under the inclination action of the slide way, and then starts the transport piece to transport the forge piece to the tail end of the lifting way;

secondly, the purpose of arranging the moving plate and the chain is that, initially, after the forge piece is placed on the transition path, the motor is started, and drives the chain wheel to rotate so as to drive the chain to transmit, so that the moving plate pushes the forge piece to move, and the forge piece is conveyed to the tail end of the lifting path;

and thirdly, the purpose of rotating the movable plate is that initially, the movable plate is in a vertical state, so that the forged piece enters the transition passage from the slide way, and then, the movable plate is rotated to be in a horizontal state, so that the movable plate can push the forged piece to move.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the prior art;

FIG. 2 is a schematic view of the overall structure of the present embodiment;

FIG. 3 is an enlarged view of a portion A of FIG. 2;

fig. 4 is a partially enlarged view of a portion B in fig. 2.

Reference numerals: 100. a furnace body; 110. a furnace door; 120. a winch; 140. a frame; 150. a feeding hydraulic cylinder; 160. pushing the plate; 170. a bearing plate; 200. a receiving table; 300. a transport assembly; 310. a slideway; 320. a transition passage; 330. lifting a road; 340. a transport member; 342. moving the plate; 344. a chain; 345. mounting a plate; 346. a gear; 347. a sliding hydraulic cylinder; 348. a rack; 349. a slag falling hole; 350. a slag removal tank; 360. a first pulley; 361. a second pulley; 363. a lead screw; 364. a first bevel gear; 365. a second bevel gear; 366. a slag removal plate; 367. a chute; 368. pushing the hydraulic cylinder; 369. an auxiliary plate.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 2, for the utility model discloses a supplementary conveyor of unloading of heating furnace, including receiving platform 200 and transportation subassembly 300, receiving platform 200 level is fixed in the heating furnace exit. The transportation assembly 300 comprises a slide way 310 and a transition channel 320, wherein the slide way 310 is obliquely arranged, one end of the slide way 310 is fixedly connected with the receiving platform 200, the other end of the slide way is fixedly connected with the transition channel 320, and the transition channel 320 is horizontally fixed on the ground. The end of the transition passage 320 is fixed with a lifting passage 330, and the end of the lifting passage 330 is as high as the workbench of the next process. Transport pieces 340 are disposed on the transition way 320 and the lifting way 330 for transporting the forging pieces to the end of the lifting way 330. The staff dials the forging to the receiving platform 200, then, makes the forging enter the slideway 310, and slides to the transition channel 320 under the inclined action of the slideway 310, and then starts the transportation piece 340, makes the transportation piece 340 transport the forging to the end of the lifting channel 330, and makes the staff move the forging to the next working platform.

The transport member 340 includes a motor (not shown) fixed to a sidewall of the transition duct 320 and a moving plate 342. A plurality of chain wheels (not shown) are respectively arranged on the upper side walls of the transition passage 320 and the lifting passage 330 in a rotating manner, the chain wheels are in transmission connection through a chain 344, a shaft on the chain 344 is connected with the side walls of the transition passage 320 and the lifting passage 330 in a sliding manner, and the sliding path is the same as the path formed by the transition passage 320 and the lifting passage 330. The output shaft of the motor is coaxially and fixedly connected with one of the chain wheels, and the moving plate 342 is arranged on the chain 344. Initially, the moving plate 342 is placed at the beginning of the transition path 320, and after the forging is placed on the transition path 320, the motor is started, and the motor drives the sprocket to rotate, so as to drive the chain 344 to transmit, so that the moving plate 342 pushes the forging to move, and the forging is transported to the end of the lifting path 330.

As shown in FIG. 3, in order to prevent the movable plate 342 from affecting the sliding of the forged piece from the slideway 310 to the transition passage 320, a mounting plate 345 is vertically fixed on the chain 344, a gear 346 rotates on the mounting plate 345, and the movable plate 342 is coaxially and fixedly connected with the gear 346. A sliding hydraulic cylinder 347 is vertically fixed on the mounting plate 345, a rack 348 is vertically fixed on a piston rod of the sliding hydraulic cylinder 347, the rack 348 is meshed with the gear 346, and the sliding hydraulic cylinder 347 is powered by a hydraulic pump. When the sliding hydraulic cylinder 347 is started, the sliding hydraulic cylinder 347 is expanded to drive the rack 348 to slide, the rack 348 drives the gear 346 to rotate, so that the gear 346 drives the moving plate 342 to be in a vertical state, the forge piece slides to the transition passage 320 from the slide rail 310, then the sliding hydraulic cylinder 347 is started, the sliding hydraulic cylinder 347 is contracted, the rack 348 drives the gear 346 to rotate, and the gear 346 drives the moving plate 342 to be in a horizontal state.

As shown in fig. 2, in order to prevent the slag on the forging from remaining on the transition passage 320 and the lifting passage 330 during the transportation of the forging, slag falling holes 349 are formed in both the transition passage 320 and the lifting passage 330, and a slag removing groove 350 is formed below the transition passage 320 along the length thereof.

As shown in fig. 4, in order to accumulate the waste slag in the slag removing groove 350 at the end of the transition passage 320, a first pulley 360 is coaxially fixed on a sprocket far away from the motor, a second pulley 361 is rotated on the side wall of the slag removing groove 350, a horizontal rotating rod (not shown in the figure) is coaxially fixed on the second pulley 361, and a first bevel gear 364 is coaxially fixed on the rotating rod. The side wall of the slag removing groove 350 is rotatably provided with a screw rod 363 parallel to the length direction of the slag removing groove, the screw rod 363 is in threaded connection with a slag removing plate 366, and the slag removing plate 366 is abutted to the bottom wall of the slag removing groove 350. One end of the screw 363 is coaxially fixed with a second bevel gear 365, and the first bevel gear 364 is engaged with the second bevel gear 365. When the motor is started, the moving plate 342 pushes the forging to move, and simultaneously, the first belt pulley 360 drives the second belt pulley 361 to rotate, so that the first bevel gear 364 drives the second bevel gear 365 to rotate, the lead screw 363 rotates, the movement of the slag removing plate 366 is driven, and the slag removing plate 366 deposits the slag at the tail end of the transition channel 320.

A chute 367 is fixed on the lower surface of the lifting channel 330, one end of the chute 367 is fixedly connected with the tail end of the lifting channel 330, the other end of the chute 367 is fixedly connected with the slag cleaning groove 350, and waste slag in the lifting channel 330 can be concentrated at the tail end of the transition channel 320 under the inclination action of the chute 367, so that the waste slag can be conveniently and intensively treated.

In order to push the waste slag at the tail end of the transition passage 320 out of the slag removing groove 350, a pushing hydraulic cylinder 368 perpendicular to the length of the slag removing groove 350 is fixed on the side wall of one end of the slag removing groove 350 in the length direction, an auxiliary plate 369 is fixed on a piston rod of the pushing hydraulic cylinder 368, and the auxiliary plate 369 is abutted against the bottom wall of the slag removing groove 350. After the waste slag is completely accumulated at the tail end of the transition passage 320, the pushing hydraulic cylinder 368 is started, the pushing hydraulic cylinder 368 stretches, and the auxiliary plate 369 is driven to push the waste slag out of the slag cleaning groove 350.

The specific working principle of this embodiment is as follows: after the forge piece is hooked out of the heating furnace, the forge piece slides to the transition channel 320 under the inclination action of the slide channel 310, then the sliding hydraulic cylinder 347 is started, the sliding hydraulic cylinder 347 contracts, the rack 348 drives the gear 346 to rotate, the gear 346 drives the moving plate 342 to be in a horizontal state, then the motor is started, the motor drives the chain wheel 343 to rotate, the chain 344 drives the mounting plate 345 to move, the moving plate 342 pushes the forge piece to be arranged at the tail end of the lifting channel 330, and therefore a worker moves the forge piece to the next working table; when the motor starts, first belt pulley 360 drives the rotation of second belt pulley 361, second belt pulley 361 drives the rotation of dwang, the dwang drives the rotation of first bevel gear 364, first bevel gear 364 drives the rotation of second bevel gear 365, thereby drive the rotation of lead screw 363, thereby drive the removal of movable plate 342, make the waste residue concentrate on the end of transition 320, then start and promote pneumatic cylinder 368, it stretches to promote pneumatic cylinder 368, thereby make accessory plate 369 push out slag removing groove 350 with the waste residue.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications to the present embodiment without inventive contribution as required after reading the present specification, but all of them are protected by patent laws within the scope of the claims of the present invention.

Claims (8)

1. The utility model provides a conveyor is assisted in unloading of heating furnace which characterized in that: including bearing platform (200) and transportation subassembly (300), bearing platform (200) level is fixed in the heating furnace exit, transportation subassembly (300) include slide (310) and transportation piece (340), slide (310) slope sets up to its one end and bearing platform (200) fixed connection, and the other end is fixed with horizontal transition way (320), transition way (320) end is fixed with lifting way (330), the terminal workstation of lifting way (330) is the same height with the workstation of next process, transportation piece (340) set up on transition way (320) and lifting way (330), are used for transporting the forging.

2. The auxiliary feeding device for the heating furnace of claim 1, wherein: the transportation piece (340) is including movable plate (342) and motor, and the motor is fixed in on the lateral wall of transition way (320), the lateral wall all rotates and has a plurality of sprockets on transition way (320) and lifting way (330), connects through chain (344) transmission between a plurality of sprockets, chain (344) and the lateral wall of transition way (320) and lifting way (330) slide and be connected, the output shaft and one of them sprocket coaxial fixed connection of motor, movable plate (342) set up on chain (344).

3. The auxiliary feeding device for the heating furnace of claim 2, wherein: the moving plate (342) rotates on the chain (344).

4. The auxiliary feeding device for the heating furnace of claim 3, wherein: an installation plate (345) is vertically fixed on the chain (344), a gear (346) is rotated on the installation plate (345), the moving plate (342) is coaxially and fixedly connected with the gear (346), a sliding hydraulic cylinder (347) is vertically fixed on the installation plate (345), a rack (348) is vertically fixed on a piston rod of the sliding hydraulic cylinder (347), and the rack (348) is meshed with the gear (346).

5. The auxiliary feeding device for the heating furnace of claim 4, wherein: slag falling holes (349) are formed in the transition channel (320) and the lifting channel (330).

6. The auxiliary feeding device for the heating furnace of claim 5, wherein: a chute (367) is fixed on the lower surface of the lifting channel (330), one end of the chute (367) is fixedly connected with the lifting channel (330), and the other end of the chute is fixedly connected with the slag cleaning groove (350).

7. The auxiliary feeding device for the heating furnace of claim 6, wherein: the slag removing groove (350) is formed in the ground, the slag removing groove (350) is arranged under the transition channel (320), a first belt pulley (360) is coaxially fixed on a chain wheel far away from a motor, a horizontal rotating rod is rotated on the side wall of the slag removing groove (350), a second belt pulley (361) is coaxially fixed on the rotating rod, the second belt pulley (361) is connected with the first belt pulley (360) through belt transmission, a first bevel gear (364) is coaxially fixed on the rotating rod, a lead screw (363) parallel to the length direction of the slag removing groove (350) is rotated on the side wall of the slag removing groove (350), a slag removing plate (366) is connected with the lead screw (363) through thread threads, the slag removing plate (366) is abutted to the bottom wall of the slag removing groove (350), a second bevel gear (365) is coaxially fixed on one end of the lead screw (363), and the first bevel gear (364) is meshed with the second bevel gear.

8. The auxiliary feeding device for the heating furnace of claim 7, wherein: a pushing hydraulic cylinder (368) vertical to the length of the slag removing groove (350) is fixed on the side wall of one end of the slag removing groove in the length direction, an auxiliary plate (369) is fixed on a piston rod of the pushing hydraulic cylinder (368), and the auxiliary plate (369) is abutted to the bottom wall of the slag removing groove (350).

Images