CN116371668A

CN116371668A - Oil seal framework machining device

Info

Publication number: CN116371668A
Application number: CN202310451849.XA
Authority: CN
Inventors: 黄顺道; 黄惠坤; 丁飞霞; 陆建新; 任伟杰
Original assignee: Zhejiang Shangyu Oil Seal Manufacture Co ltd
Current assignee: Zhejiang Shangyu Oil Seal Manufacture Co ltd
Priority date: 2023-04-21
Filing date: 2023-04-21
Publication date: 2023-07-04
Anticipated expiration: 2043-04-21
Also published as: CN116371668B

Abstract

The utility model relates to an oil blanket skeleton processingequipment, it includes shot-blasting machine, ultrasonic cleaning pond, frame, gluey pond and stoving subassembly, the shot-blasting machine the ultrasonic cleaning pond with glue the pond and arrange in proper order, glue the pond connect in the frame bottom, stoving subassembly connect in the frame top, the frame is connected with the transport piece, the transport piece is connected with first loading frame, stoving subassembly below is equipped with the second loading frame, the transport piece be used for with skeleton in the first loading frame is carried to in the second loading frame, the second loading frame is connected with rotating assembly. The application has the following effects: the method can avoid the mutual adhesion of the frameworks during drying as much as possible, so as to improve the processing efficiency.

Description

Oil seal framework machining device

Technical Field

The application relates to the field of skeleton manufacturing equipment, in particular to an oil seal skeleton processing device.

Background

Oil seals are a common convention designation for seals, and are lubricating oil seals. The mechanical element is used for sealing grease, and isolates the parts which need to be lubricated from the output parts in the transmission parts, so that the leakage of lubricating oil can be avoided. Generally, the oil seal is divided into a single body type and an assembled type, and the assembled type framework and the lip material can be freely combined.

After the framework is manufactured, glue needs to be soaked for one time, and then drying is carried out, so that a layer of glue film can be formed on the surface of the framework. However, when dipping, an operator typically dips a plurality of frames into glue at a time, and when drying, the frames are easily glued together, and subsequently the glued frames need to be separated, resulting in lower processing efficiency.

Disclosure of Invention

In order to avoid the mutual gluing of the frameworks to the greatest extent when drying to improve machining efficiency, the application provides an oil seal framework machining device.

The application provides an oil blanket skeleton processingequipment adopts following technical scheme:

the utility model provides an oil blanket skeleton processingequipment, includes shot-blasting machine, ultrasonic cleaning pond, frame, gluey pond and stoving subassembly, the shot-blasting machine the ultrasonic cleaning pond with glue the pond and arrange in proper order, glue the pond connect in frame bottom, stoving subassembly connect in the frame top, the frame is connected with the transport piece, the transport piece is connected with first loading frame, stoving subassembly below is equipped with the second and loads the frame, the transport piece be used for with the skeleton in the first loading frame is carried to in the second loading frame, the second is loaded the frame and is connected with rotating assembly.

Through adopting above-mentioned technical scheme, the skeleton gets into the ultrasonic cleaning pond after through shot-blasting machine processing and washs, and after the skeleton that washs was loaded into first loading frame, first loading frame takes the skeleton to carry to the second after gluing in the gluey pond and loads the frame, rotates the second and loads the frame, and the second loads the frame and drives the skeleton and rotate together when rotating, and unnecessary glue drops from the second loading frame, simultaneously, and stoving subassembly is to the skeleton stoving, and the skeleton is difficult for adhesion each other when rotating to this can avoid the skeleton to glue when the stoving each other as far as possible and be in the same place, and then improves machining efficiency.

Preferably, the second loading frame includes a second frame and a plurality of ventilation nets, and each ventilation net is connected to the second frame.

Through adopting above-mentioned technical scheme, the heat that stoving subassembly produced accessible ventilation net gets into in the second load frame to skeleton in this can dry the second load frame, simultaneously, unnecessary glue accessible ventilation net on the skeleton falls out from the second load frame.

Preferably, the ventilation net comprises a plurality of iron strips, each iron strip is interwoven to form a plurality of protruding parts, and each protruding part is uniformly distributed at intervals on the inner side of the ventilation net.

Through adopting above-mentioned technical scheme, the second loads the frame and rotates when rotating, drives the skeleton and rotates, and the skeleton bumps with the bulge to this can break up a plurality of skeletons that are located the second and load the frame, can avoid the skeleton to glue together after the stoving as far as possible.

Preferably, the second loading frame is in a polygonal column shape, at least three circumferential side walls of the second loading frame are arranged, and the rotating assembly is connected with the end part of the second loading frame.

Through adopting above-mentioned technical scheme, the rotation piece drives the second and loads the frame rotation, and the second loads the frame when rotating, and the skeleton in the second loads the frame can be turned over to the lateral wall of second and loads the frame to this can break up a plurality of skeletons.

Preferably, the conveying member is connected with the first loading frame through the lifting member, the first loading frame is rotationally connected with the lifting member, the first loading frame is columnar, the length direction of the first loading frame is distributed along the horizontal direction, a rotating rod is arranged in the glue pool, the length direction of the rotating rod is consistent with the length direction of the first loading frame, the end part of the rotating rod is rotationally connected with the side wall of the glue pool, the rotating rod is connected with a plurality of first poking plates, and the first poking plates are circumferentially distributed at equal angular intervals along the rotating rod.

Through adopting above-mentioned technical scheme, the lifter can be with first loading frame immersion gum pond in, and when the dwang rotated, drive first stirring board rotation, each first stirring board can stir first loading frame in proper order and rotate in the gum pond, and glue gets into first loading frame back and adheres to on the skeleton to this can make the skeleton fully rubberize, simultaneously, but first stirring board stirring glue when rotating, can avoid glue to solidify as far as possible.

Preferably, the first loading frame comprises a first rotating door and a first frame, the first rotating door is connected with a first rotating member, a first protecting cover is arranged on the first rotating member cover, the first rotating door is rotationally connected with the first frame to open or close the first loading frame, the second loading frame further comprises a second rotating door, the second rotating door is rotationally connected with the second frame to open or close the second loading frame, the second rotating door is connected with a second rotating member, and the second rotating member cover is provided with a second protecting cover.

Through adopting above-mentioned technical scheme, first rotation piece drives first rotation door and rotates in order to switch first loading frame to this skeleton output that can be with the interior glue of finishing of first loading frame, second rotation piece drives the second rotation door and rotates in order to switch second loading frame, so can export the skeleton that the stoving was finished from the second loading frame.

Preferably, the rotating assembly comprises a rotating shaft and a first motor, an output shaft of the first motor is connected with one end of the rotating shaft, a plurality of second stirring plates are connected with the other end of the rotating shaft, the second stirring plates are distributed at equal angular intervals along the circumferential direction of the rotating shaft, a sleeve is connected with the end part of the second loading frame, a star-shaped groove is formed in the sleeve, the depth direction of the star-shaped groove is consistent with the length direction of the second loading frame, one end, far away from the first motor, of the rotating shaft is spliced with the star-shaped groove, and gaps are formed between the second stirring plates and the inner wall of the star-shaped groove.

Through adopting above-mentioned technical scheme, when the axis of rotation was driven to first motor in star type inslot internal rotation, the axis of rotation drove a plurality of second and stir the board and rotate together, each second stirs the board and rotates the time, the second loads the frame and drives the sleeve and drop down owing to gravity effect, each second stirs the board and can contact with each star type inslot wall respectively, so can shake the second when rotating the second and load the frame, with this can disperse the skeleton in the second and load the frame, can avoid the skeleton adhesion each other as far as possible, simultaneously, can shake the skeleton that falls to adhere to on the ventilation net, can avoid the ventilation net to be blockked up by the skeleton as far as possible, can improve drying component's heat transfer efficiency, with this drying efficiency to the skeleton that can further improve.

Preferably, a vibration plate is arranged below the second loading frame, the vibration plate is connected with a pushing piece, and the pushing piece moves along the vertical direction.

Through adopting above-mentioned technical scheme, the second loads the frame when exporting the skeleton, and the impeller promotes the vibrations board to the second and loads on the frame perisporium to this can vibrate the second and load the frame, can improve the ejection of compact efficiency that the second loaded the frame.

Preferably, a base is arranged below the vibration plate, the vibration plate is connected with the base through a spring, the pushing piece is an air cylinder, the air cylinder shell is connected with the base, and the piston rod of the air cylinder faces to the bottom of the vibration plate.

By adopting the technical scheme, the cylinder stretches the piston rod, so that the vibration plate can be pushed to the peripheral wall of the second loading frame, the piston rod of the cylinder is retracted, the vibration plate can be reset to the lower part of the second loading frame through the spring, the piston rod of the cylinder reciprocates, and the second loading frame can be vibrated through the vibration plate.

Preferably, the drying assembly comprises a plurality of drying lamps, and each drying lamp is uniformly distributed at intervals along the length direction of the second loading frame.

Through adopting above-mentioned technical scheme, each stoving lamp is along second loading frame length direction range, can make heat evenly distributed load on the frame at the second, and the stoving lamp sends heat with this glue on skeleton surface of can drying to this can improve the stoving effect.

In summary, the present application includes at least one of the following beneficial technical effects:

1. after the framework is arranged in the first loading frame, the first loading frame is provided with the framework, the framework is glued in the glue pool and then is conveyed into the second loading frame, the rotating piece rotates the second loading frame, the second loading frame drives the framework to rotate together when rotating, redundant glue drops from the second loading frame, meanwhile, the drying assembly dries the framework, the frameworks are not easy to adhere to each other when rotating, and therefore the frameworks can be prevented from being glued together when being dried as much as possible, and further the processing efficiency is improved;

2. the lifting piece can immerse the first loading frame in the glue pool, when the rotating rod rotates, the first stirring plates are driven to rotate, each first stirring plate can sequentially stir the first loading frame to rotate in the glue pool, glue enters the first loading frame and then is attached to the framework, so that the framework can be fully glued, and meanwhile, the first stirring plates can stir the glue when rotating, and the glue can be prevented from being solidified as much as possible;

3. when the first motor drives the rotation shaft to rotate in the star-shaped groove, the rotation shaft drives the plurality of second stirring plates to rotate together, when each second stirring plate rotates, the second loading frame drives the sleeve to drop downwards due to the action of gravity, each second stirring plate can be respectively contacted with the inner wall of each star-shaped groove, so that the second loading frame can be vibrated when the second loading frame rotates, the frameworks in the second loading frame can be dispersed, mutual adhesion of the frameworks can be avoided as much as possible, meanwhile, the frameworks attached to the ventilation net can be vibrated, the ventilation net can be prevented from being blocked by the frameworks as much as possible, the heat transfer efficiency of the drying assembly can be improved, and the drying efficiency of the frameworks can be further improved.

Drawings

Fig. 1 is a schematic diagram of an overall structure of an oil seal skeleton processing device according to an embodiment of the application.

Fig. 2 is a cross-sectional view of an oil seal skeleton processing device according to an embodiment of the present application.

Fig. 3 is an exploded view of a part of a structure of an oil seal skeleton processing device according to an embodiment of the present application, for showing a first rotating member and a second rotating member.

Fig. 4 is a schematic view of a part of a processing device for an oil seal framework in an embodiment of the application, which is used for showing a pushing member.

Fig. 5 is a schematic view of a part of a processing device for an oil seal framework in an embodiment of the application, which is used for showing a ventilation net.

Reference numerals illustrate:

100. a frame; 101. a conveying member; 102. a lifting member; 103. a vibration plate; 104. a pushing member; 105. a base; 106. a spring;

200. a glue pool; 201. a rotating lever; 202. a first toggle plate;

300. a drying assembly; 301. a drying lamp;

400. a first loading frame; 401. a first frame; 402. a first rotary door; 403. a first rotating member; 404. a first protective cover;

500. a second loading frame; 501. a second frame; 502. a ventilation screen; 503. iron bars; 504. a protruding portion; 505. a second rotary door; 506. a second rotating member; 507. a second protective cover; 508. a sleeve; 509. a star-shaped groove;

600. a rotating assembly; 601. a rotating shaft; 602. a first motor; 603. and a second toggle plate.

Detailed Description

The present application is described in further detail below with reference to the accompanying drawings.

The embodiment of the application discloses an oil blanket skeleton processingequipment. Referring to fig. 1 and 2, the oil seal skeleton processing device includes a shot blasting machine, an ultrasonic cleaning tank, a frame 100, a glue tank 200, a first loading frame 400, a second loading frame 500 and a drying assembly 300, wherein the shot blasting machine, the ultrasonic cleaning tank and the glue tank 200 are sequentially arranged, the glue tank 200 is positioned at the bottom of the frame 100, the drying assembly 300 is positioned at the top of the frame 100, the first loading frame 400 is used for loading a skeleton and gluing the skeleton through the glue tank 200, the first loading frame 400 conveys the skeleton into the second loading frame 500, and the drying assembly 300 is used for drying the skeleton in the second loading frame 500.

The top of the frame 100 is connected with a conveying member 101, the conveying member 101 adopts a screw rod, and the length direction of the screw rod is distributed along the horizontal direction. The conveying piece 101 is connected with the first loading frame 400 through the lifting piece 102, the lifting piece 102 adopts an air cylinder, the shell of the air cylinder is connected with the sliding block of the screw rod, the piston rod of the air cylinder is connected with the end part of the first loading frame 400 through a connecting block, and the length direction of the piston rod of the air cylinder is distributed along the vertical direction.

Referring to fig. 2 and 3, the first loading frame 400 has a hexagonal prism shape, the length direction of which is distributed in the horizontal direction, and the end of the first loading frame 400 is rotatably connected to the connection block. The first loading frame 400 comprises a first frame 401 and a first rotating door 402, the first rotating door 402 is formed by two continuous side walls of the first loading frame 400, the first rotating door 402 is rotationally connected with the first frame 401 to open or close the first loading frame 400, the first rotating door 402 is connected with a first rotating piece 403, the first rotating piece 403 adopts a motor, an output shaft of the motor is connected with the first rotating door 402, a first protective cover 404 is sleeved on a shell of the motor, the first protective cover 404 is connected with the first frame 401, and the motor can be prevented from being polluted by glue as much as possible.

The second loading frame 500 has a hexagonal prism shape, and a length direction thereof is identical to a length direction of the first loading frame 400. The second loading frame 500 includes a second frame 501 and a second rotating door 505, the second rotating door 505 is formed by two continuous side walls of the second loading frame 500, the second rotating door 505 is rotatably connected with the second frame 501 to open or close the second loading frame 500, the second rotating door 505 is connected with a second rotating member 506, the second rotating member 506 adopts a motor, an output shaft of the motor is connected with the second rotating door 505, a housing of the motor is sleeved with a second protection cover 507, and the second protection cover 507 is connected with the second frame 501.

Referring to fig. 4 and 5, the second loading frame 500 further includes a plurality of ventilation nets 502, each ventilation net 502 is connected to the second frame 501, the ventilation net 502 includes a plurality of iron bars 503, the plurality of iron bars 503 are interwoven to form a plurality of protrusions 504 and a plurality of openings, and each protrusion 504 and each opening are uniformly spaced on the inner side and the outer side of the ventilation net 502. In the present embodiment, the first loading frame 400 has the same structure as the second loading frame 500.

Referring to fig. 1 and 2, glue is contained in the glue pool 200, the top opening is provided, a rotating rod 201 is arranged in the glue pool 200, the length direction of the rotating rod 201 is consistent with the length direction of the first loading frame 400, and the end part of the rotating rod 201 is rotationally connected with the side wall of the glue pool 200. A plurality of first stirring plates 202 are connected to the peripheral wall of the rotating rod 201, the length direction of the first stirring plates 202 is consistent with that of the rotating rod 201, the plurality of first stirring plates 202 are distributed at equal angular intervals along the circumferential direction of the rotating rod 201, the first loading frame 400 is immersed in the glue pool 200, the rotating rod 201 drives the first stirring plates 202 to rotate, and the first stirring plates 202 stir the first loading frame 400 to rotate.

Referring to fig. 1 and 4, a sleeve 508 is connected to an end of the second loading frame 500, a central axis of the sleeve 508 is collinear with a central axis of the second loading frame 500, a star-shaped groove 509 is formed in the sleeve 508, and a depth direction of the star-shaped groove 509 is consistent with a length direction of the second loading frame 500. In this embodiment, the star-shaped groove 509 has a five-pointed star-shaped cross section.

The second loading frame 500 is connected with a rotating assembly 600, the rotating assembly 600 comprises a rotating shaft 601 and a first motor 602, the rotating shaft 601 is connected with an output shaft of the first motor 602, and a first motor 602 shell is connected with the frame 100. The rotation shaft 601 is connected with a plurality of second toggle plates 603, and the length direction of the second toggle plates 603 is consistent with the length direction of the rotation shaft 601. The second toggle plates 603 are circumferentially and equiangularly spaced along the rotation shaft 601. In this embodiment, the second toggle plate 603 has five toggle plates. The rotating shaft 601 is inserted into the star-shaped groove 509, the five second toggle plates 603 are respectively located in five corners of the star-shaped groove 509, and gaps are formed between the second toggle plates 603 and the inner wall of the star-shaped groove 509 at intervals.

Referring to fig. 1, the drying assembly 300 is located above one side of the second loading frame 500 away from the glue pool 200, and the drying assembly 300 includes a plurality of drying lamps 301, each drying lamp 301 being connected with the rack 100 and being uniformly spaced apart along the length direction of the second loading frame 500.

Referring to fig. 2 and 4, a vibration plate 103 is disposed below the second loading frame 500, the vibration plate 103 is connected with a base 105 through a pushing member 104, the base 105 is located at the bottom of the frame 100 and below the vibration plate 103, the pushing member 104 adopts a cylinder, a cylinder housing is connected with the base 105, a piston rod of the cylinder is disposed along a vertical direction and faces the vibration plate 103, the cylinder reciprocally pushes the vibration plate 103, and the vibration plate 103 can vibrate the second loading frame 500. The base 105 is connected with a plurality of springs 106, and the both ends of spring 106 are connected with vibrations board 103, base 105 respectively. In fig. 2 and 4, the vibration plate 103 is pushed to the bottom of the second loading frame 500 by the air cylinder, and when the piston rod of the air cylinder is retracted, the vibration plate 103 is pulled to be reset to the position below the second loading frame 500 by the spring 106.

The implementation principle of the oil seal framework processing device provided by the embodiment of the application is as follows: the framework enters an ultrasonic cleaning tank for cleaning after being processed by a shot blasting machine, the cleaned framework is placed in a first loading frame 400, the framework is immersed in a glue tank 200 through a lifting piece 102, a plurality of first stirring plates 202 sequentially stir the first loading frame 400, and the first loading frame 400 rotates, so that the framework is fully glued. After the framework is glued, the lifting member 102 lifts the first loading frame 400 from the glue pool 200, the conveying member 101 conveys the first loading frame 400 to above the second loading frame 500, the first rotating member 403 rotates the first rotating door 402 to open the first loading frame 400, the framework falls into the second loading frame 500 from the first loading frame 400, and the second rotating member 506 rotates the second rotating door 505 to close the second loading frame 500. The first motor 602 rotates the second loading frame 500 through the rotation shaft 601, the second loading frame 500 dries the backbone by the drying lamp 301 while rotating, and the vibration plate 103 vibrates the second loading frame 500 through the pushing member 104. The frameworks are not easy to adhere to each other during drying, so that the frameworks can be prevented from being glued together during drying as much as possible, and further the processing efficiency is improved.

Each second toggle plate 603 has a gap with each corner of the star-shaped groove 509, due to the action of gravity, the sleeve 508 contacts with one end of the second toggle plate 603 at the highest position far away from the rotating shaft 601, when the first motor 602 drives the rotating shaft 601 to rotate, the second toggle plate 603 at the highest position rotates towards the lower position, the second toggle plates 603 at the lower position rotate towards the highest position, the sleeve 508 can drop in sequence, so that the sleeve 508 can contact with each second toggle plate 603 rotating towards the highest position, and the second loading frame 500 can be vibrated when the second loading frame 500 rotates.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims

1. An oil blanket skeleton processingequipment, its characterized in that: including shot-blasting machine, ultrasonic cleaning pond, frame (100), gluey pond (200) and stoving subassembly (300), the shot-blasting machine the ultrasonic cleaning pond with glue pond (200) and arrange in proper order, glue pond (200) connect in frame (100) bottom, stoving subassembly (300) connect in frame (100) top, frame (100) are connected with transport piece (101), transport piece (101) are connected with first loading frame (400), stoving subassembly (300) below is equipped with second loading frame (500), transport piece (101) are used for with skeleton in first loading frame (400) is carried to in second loading frame (500), second loading frame (500) are connected with rotating assembly (600).

2. The oil seal skeleton processing apparatus according to claim 1, wherein: the second loading frame (500) comprises a second frame (501) and a plurality of ventilation nets (502), and each ventilation net (502) is connected to the second frame (501).

3. The oil seal skeleton processing apparatus according to claim 2, wherein: the ventilation net (502) comprises a plurality of iron strips (503), the iron strips (503) are interwoven to form a plurality of protruding parts (504), and the protruding parts (504) are uniformly distributed at intervals on the inner side of the ventilation net (502).

4. The oil seal skeleton processing apparatus according to claim 1, wherein: the second loading frame (500) is in a polygonal column shape, at least three circumferential side walls of the second loading frame are arranged, and the rotating assembly (600) is connected with the end part of the second loading frame (500).

5. The oil seal skeleton processing apparatus according to claim 1, wherein: the conveying part (101) is connected with the first loading frame (400) through the lifting part (102), the first loading frame (400) is rotationally connected with the lifting part (102), the first loading frame (400) is columnar and distributed along the horizontal direction in the length direction, a rotating rod (201) is arranged in the glue pool (200), the length direction of the rotating rod (201) is consistent with that of the first loading frame (400), the end part of the rotating rod (201) is rotationally connected with the side wall of the glue pool (200), a plurality of first stirring plates (202) are connected with the rotating rod (201), and the first stirring plates (202) are distributed along the circumference of the rotating rod (201) at equal angle intervals.

6. The oil seal skeleton processing apparatus according to claim 2, wherein: the first loading frame (400) comprises a first rotating door (402) and a first frame (401), the first rotating door (402) is connected with a first rotating piece (403), the first rotating piece (403) is covered with a first protection cover (404), the first rotating door (402) is rotationally connected with the first frame (401) to realize opening or closing of the first loading frame (400), the second loading frame (500) further comprises a second rotating door (505), the second rotating door (505) is rotationally connected with the second frame (501) to realize opening or closing of the second loading frame (500), the second rotating door (505) is connected with a second rotating piece (506), and the second rotating piece (506) is covered with a second protection cover (507).

7. The oil seal skeleton processing apparatus according to claim 1, wherein: the rotating assembly (600) comprises a rotating shaft (601) and a first motor (602), an output shaft of the first motor (602) is connected with one end of the rotating shaft (601), a plurality of second stirring plates (603) are connected with the other end of the rotating shaft (601), the second stirring plates (603) are distributed at equal angular intervals along the circumference of the rotating shaft (601), a sleeve (508) is connected with the end portion of the second loading frame (500), a star-shaped groove (509) is formed in the sleeve (508), the depth direction of the star-shaped groove (509) is consistent with the length direction of the second loading frame (500), one end, away from the first motor (602), of the rotating shaft (601) is spliced with the star-shaped groove (509), and gaps are formed between the second stirring plates (603) and the inner wall of the star-shaped groove (509).

8. The oil seal skeleton processing apparatus according to claim 7, wherein: a vibrating plate (103) is arranged below the second loading frame (500), the vibrating plate (103) is connected with a pushing piece (104), and the pushing piece (104) moves along the vertical direction.

9. The oil seal skeleton processing apparatus according to claim 8, wherein: the vibration plate (103) is provided with a base (105) below, the vibration plate (103) is connected with the base (105) through a spring (106), the pushing piece (104) is an air cylinder, the air cylinder shell is connected with the base (105), and the piston rod of the air cylinder faces to the bottom of the vibration plate (103).

10. The oil seal skeleton processing apparatus according to claim 1, wherein: the drying assembly (300) comprises a plurality of drying lamps (301), and each drying lamp (301) is uniformly distributed at intervals along the length direction of the second loading frame (500).