CN111924722B - Stacking device for flywheel housing processing production - Google Patents

Abstract

The invention relates to the technical field of flywheel housing processing production equipment, in particular to a stacking device for flywheel housing processing production. The stacking device for flywheel shell processing production is characterized in that a longitudinally-arranged supporting assembly pipe which is provided with a built-in electric control hydraulic lifter and is arranged on a main bottom supporting frame is provided with an overhead steering arm, and an electric control overturning limiting rod is arranged on the overhead steering arm to stretch, so that the stacking device can be suitable for flywheel shells of various specifications as required, and the application range is wider; the side overturning and accommodating groove can be overturned, contracted and inserted into the side overturning and accommodating groove under the non-working state, so that the durability and the safety of the side overturning and accommodating groove are improved; whole equipment adopts overhead regulating motor and side to put regulating motor control and turns to and the drive, adopts self-propelled design, makes its service environment more various, and the operation is more nimble.

Description

Stacking device for flywheel housing processing production

Technical Field

The invention relates to the technical field of flywheel housing processing production equipment, in particular to a stacking device for flywheel housing processing production.

Background

The flywheel shell is an external protective shell arranged between an engine and a gearbox of an automobile, is externally connected with a crankcase, a starter and an oil pan and is mainly used for installing a flywheel assembly, plays the roles of connecting a machine body, protecting and serving as a carrier, and has the main function of realizing the effective connection of the engine and a transmission, and the flywheel shell needs to be placed by stacking after being processed.

Among the prior art, the tradition is used for piling up of bell housing and puts mainly by manual operation transport, and handling efficiency is very low, can only use traditional crane to carry out the handling to the bell housing that the volume is great and the quality is heavier, and traditional crane is with high costs, and the position of use limitation simultaneously, the operation limitation is great, and application scope is also more relatively limited.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: in order to solve the problems existing in the background technology, the improved stacking device for flywheel housing processing production is provided, and the problems that the stacking and placing of the traditional flywheel housings are mainly manually operated, the stacking efficiency is low, the flywheel housings with large size and heavy mass can only be lifted by a traditional crane, the cost of the traditional crane is high, the using positions are limited, the operation limitation is large, and the application range is limited are solved.

The technical scheme adopted by the invention for solving the technical problems is as follows: a stacking device for flywheel housing processing production comprises a main bottom supporting frame, an electric control hydraulic lifter, a driving motor, an annular electromagnet, an upper adjusting motor and a side adjusting motor, wherein the electric control hydraulic lifter, the driving motor, the annular electromagnet, the upper adjusting motor and the side adjusting motor are arranged on the main bottom supporting frame, the upper end of the main bottom supporting frame is provided with a longitudinal supporting assembly pipe through bolt fixing, the electric control hydraulic lifter is arranged in the longitudinal supporting assembly pipe through bolt fixing, the top end of an upper lifting rod of the electric control hydraulic lifter is axially and fixedly provided with a top assembly pipe, the upper end of the top assembly pipe is movably provided with a top steering arm, the inside of the top steering arm is provided with an inner installation cavity for installing the annular electromagnet, the lower end of the outer side of the top steering arm is positioned below the annular electromagnet and is provided with a bottom assembly seat, the upper end of the bottom assembly seat is fixedly provided with a top installation box with an iron adsorption plate, iron adsorption plate and overhead steering arm outside lower extreme between through iron regulating spring elastic connection, bottom assembly seat lateral surface on set up the side direction upset of built-in upset gag lever post and accomodate the groove, bottom assembly seat inside set up the inside transmission cavity who is used for installing driving motor, driving motor through the epaxial transmission gear group of lower extreme commentaries on classics be connected with the transmission of upset gag lever post medial extremity.

Further, in order to control the lateral overturning and stretching, the overturning limiting rod comprises an internal overturning cylinder movably arranged in the lateral overturning accommodating groove through a lateral rotating shaft, an internal adjusting rod inserted in the internal overturning cylinder, an integral structure external thread screw rod axially fixed at the outer end of the internal adjusting rod and an external telescopic internal thread pipe sleeved outside the external thread screw rod.

Further, in order to cooperate with transmission, the transmission gear set comprises a spherical transmission gear movably mounted inside the lateral overturning and accommodating groove through a longitudinal rotating shaft, a lateral gear disc axially fixed on the lateral rotating shaft, a main transmission gear axially fixed on a rotating shaft at the lower end of the driving motor and a lateral linkage gear used for meshing and transmitting the lateral gear disc and the main transmission gear.

Furthermore, in order to improve the external protection performance, a flexible corrugated limiting pipe is sleeved between the lower end of the outer side of the overhead steering arm and the upper end of the outer side of the top mounting box.

Further, in order to conveniently adjust the angle, the overhead steering arm comprises an inverted L-shaped structure top supporting tube axially connected to the upper end of the top assembling tube and a lateral contraction tube movably assembled on the top supporting tube through a lateral connecting shaft.

Further, in order to facilitate manual control, a lateral control handle with a built-in control switch panel is fixed on the outer side face of the overhead steering arm through a bolt.

Furthermore, in order to facilitate bottom driving and steering adjustment, a bottom assembling through hole with a built-in bottom adjusting disk is formed in the bottom vertex angle position of the main bottom supporting frame, a bottom roller is movably assembled on the lower surface of the bottom adjusting disk and the lower surface of the main bottom supporting frame through a bottom mounting frame, the upper adjusting motor is fixedly installed above the bottom adjusting disk through a bolt, the side adjusting motor is fixedly installed on the upper surface of the main bottom supporting frame through a bolt, an upward protruding lateral transmission toothed ring with an integrated structure is arranged at the edge position of the upper surface of the bottom adjusting disk, the side adjusting motor is in meshing transmission through a first transmission gear and a lateral transmission toothed ring on the lateral transmission shaft, and the upper adjusting motor is in transmission connection with the bottom roller through a second transmission gear on the lower end rotating shaft.

The invention has the beneficial effects that:

(1) the stacking device for flywheel shell processing production is characterized in that a longitudinally-arranged supporting assembly pipe with a built-in electric control hydraulic elevator is fixedly mounted at the upper end of a main bottom supporting frame through a bolt, a top assembly pipe with an upper-arranged steering arm movably mounted at the upper end of the longitudinally-arranged supporting assembly pipe is mounted at the upper end of the longitudinally-arranged supporting assembly pipe, and a driving motor for controlling the extension and the turnover of a turnover limiting rod is mounted on the upper-arranged steering arm, so that the stacking device can be suitable for flywheel shells with various specifications as required, and can simultaneously carry and stack a plurality of flywheel shells by stretching, the processing efficiency is greatly improved, and the application range is wider;

(2) the turnover limiting rod can be synchronously controlled to turn and stretch by using a single motor, so that the turnover limiting rod can be adapted to flywheel shells of various specifications, and can be turned and contracted to be inserted into the lateral turnover accommodating groove in an inoperative state, and the durability and the safety of the turnover limiting rod are improved;

(3) the whole equipment adopts an upper adjusting motor and a side adjusting motor to control steering and driving, adopts a self-propelled design, and has more diverse use environments and more flexible operation;

(4) an iron adjusting spring is arranged between the iron adsorption plate and the overhead steering arm, and the assembly of the bottom assembly seat can be more convenient through the iron adjusting spring, so that the operation is simpler and more convenient.

Drawings

The invention is further illustrated with reference to the following figures and examples.

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is an internal cross-sectional view of the overhead pitman arm of the present invention.

Fig. 3 is an internal cross-sectional view of the bottom mount of the present invention.

In the figure, 1, a main bottom support frame, 2, an electric control hydraulic lifter, 3, a driving motor, 4, an annular electromagnet, 5, an upper adjusting motor, 6, a side adjusting motor, 7, a longitudinal support assembly pipe, 8, a top assembly pipe, 9, an overhead steering arm, 10, an internal installation chamber, 11, a bottom assembly seat, 12, an iron adsorption plate, 13, a top installation box, 14, an iron adjusting spring, 15, a turnover limiting rod, 16, a lateral turnover accommodating groove, 17, an internal transmission chamber, 18, an internal turnover cylinder, 19, an internal adjusting rod, 20, an external thread screw rod, 21, an external telescopic pipe, 22, a spherical transmission gear, 23, a lateral gear disc, 24, a main transmission gear, 25, a lateral linkage gear, 26, a flexible corrugated limiting pipe, 27, a top support pipe, 28, a lateral contraction pipe, 29, a control switch panel, 30, a lateral control handle, 31. bottom adjusting disk, 32, bottom assembly through hole, 33, bottom mounting rack, 34, bottom roller, 35, lateral transmission gear ring.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic views illustrating only the basic structure of the present invention in a schematic manner, and thus show only the constitution related to the present invention.

The stacking device for flywheel housing processing production shown in fig. 1, 2 and 3 comprises a main bottom support frame 1, an electric control hydraulic lifter 2 installed on the main bottom support frame 1, a driving motor 3, an annular electromagnet 4, an upper adjusting motor 5 and a side adjusting motor 6, wherein a longitudinal support device pipe 7 is fixedly installed at the upper end of the main bottom support frame 1 through bolts, the electric control hydraulic lifter 2 is fixedly installed inside the longitudinal support device pipe 7 through bolts, a top assembly pipe 8 is axially and fixedly installed at the top end of a lifting rod at the upper end of the electric control hydraulic lifter 2, an upper steering arm 9 is movably assembled at the upper end of the top assembly pipe 8, an internal installation chamber 10 for installing the annular electromagnet 4 is arranged inside the upper steering arm 9, a bottom assembly seat 11 is arranged at the lower end of the outer side of the upper steering arm 9 and below the annular electromagnet 4, a top installation box 13 with an iron adsorption plate 12 is fixedly installed at the upper end of the bottom assembly seat 11, iron adsorption plate 12 and overhead knuckle arm 9 outside between the lower extreme through iron regulating spring 14 elastic connection, set up the side direction upset of built-in upset gag lever post 15 on the 11 lateral surfaces of bottom assembly seat and accomodate groove 16, the inside transmission cavity 17 that is used for installing driving motor 3 that sets up of bottom assembly seat 11, driving motor 3 is connected with the transmission of upset gag lever post 15 medial extremity through the epaxial transmission gear group of lower extreme commentaries on classics.

Wherein can promote its stability and conveniently use the function in different positions through installation battery or balancing weight on the main bottom support frame 1. Bottom assembly seat 11 can insert through the bell housing through-hole, then insert inside the bell housing through-hole of lower extreme, then start the fixed lower flywheel housing of driving motor 3, it is together fixed with all bell housings to start annular electromagnet 4 at last, then 2 lifting at the automatically controlled hydraulic lift of cooperation, the lifting assembly is finally accomplished, at the adjustable camera of 11 side wall mounting angles of bottom assembly seat, then at the 30 side wall mounting displays of side direction control handle, thereby more conveniently know the inside condition.

Example (b): the electric control hydraulic lifter 2, the driving motor 3, the annular electromagnet 4, the upper adjusting motor 5 and the side adjusting motor 6 are respectively controlled by adopting market direct purchase and through a control switch panel 29 on a side control handle 30.

The driving motor 3 drives the spherical transmission gear 22 and the lateral linkage gear 25 to rotate through rotation, the spherical transmission gear 22 drives the internal adjusting rod 19 to rotate, and the lateral linkage gear 25 drives the lateral gear disc 23 to rotate, so that the internal overturning cylinder 18 and the external telescopic internal thread pipe 21 are driven to overturn outwards, and the purpose of overturning and extending at the same time is achieved.

Further, in order to control the lateral turning and the extension, the turning limiting rod 15 comprises an internal turning cylinder 18 movably mounted inside the lateral turning accommodating groove 16 through a lateral rotating shaft, an internal adjusting rod 19 inserted in the internal turning cylinder 18, an integral structure external screw thread screw rod 20 axially fixed at the outer side end of the internal adjusting rod 19 and an external extension internal screw thread pipe 21 in threaded sleeve connection with the outer side of the external screw thread screw rod 20, and further, in order to match the transmission, the transmission gear set comprises a spherical transmission gear 22 movably mounted inside the lateral turning accommodating groove 16 through a longitudinal rotating shaft, a lateral gear disc 23 axially fixed on the lateral rotating shaft, a main transmission gear 24 axially fixed on a rotating shaft at the lower end of the driving motor 3 and a lateral linkage gear 25 used for meshing and transmitting the lateral gear disc 23 and the main transmission gear 24.

Further, in order to improve the external protection performance, a flexible corrugated limiting pipe 26 is sleeved between the lower end of the outer side of the overhead steering arm 9 and the upper end of the outer side of the top mounting box 13, the flexible corrugated limiting pipe 26 is used for improving safety on one hand, and can also improve the limiting capacity of the flexible corrugated limiting pipe on the other hand, so that the spring is prevented from being stretched too long, and further, in order to adjust the angle conveniently, the overhead steering arm 9 comprises an inverted-L-shaped structure top supporting pipe 27 axially connected to the upper end of the top mounting pipe 8 and a lateral contraction pipe 28 movably assembled on the top supporting pipe 27 through a lateral connecting shaft.

Wherein the lateral and longitudinal lengths of the top support tubes 27 may be tailored as desired. The top supporting tube 27 can be changed into a structure capable of transversely stretching according to needs, and the stretching of the top supporting tube is controlled by installing a transverse adjusting motor at a non-clamping end by utilizing a lever principle, so that the application range of the top supporting tube is wider.

Furthermore, for the convenience of manual control, a lateral control handle 30 of a built-in control switch panel 29 is fixed on the outer side surface of the overhead steering arm 9 through a bolt, further, for the convenience of bottom driving and adjustment steering, a bottom assembling through hole 32 of a built-in bottom adjusting disk 31 is formed in the bottom vertex angle position of the main bottom supporting frame 1, bottom rollers 34 are movably assembled on the lower surface of the bottom adjusting disk 31 and the lower surface of the main bottom supporting frame 1 through a bottom mounting rack 33, the overhead adjusting motor 5 is fixedly installed above the bottom adjusting disk 31 through a bolt, a lateral adjusting motor 6 of the main bottom supporting frame 1 is fixedly installed on the upper surface of the main bottom supporting frame 1 through a bolt, an upward convex integral lateral transmission gear ring 35 is arranged on the edge position of the upper surface of the bottom adjusting disk 31, the lateral adjusting motor 6 is in meshing transmission through a first transmission gear and the lateral transmission gear ring 35 on the lateral transmission shaft, the upper adjusting motor 5 is in transmission connection with the bottom roller 34 through a second transmission gear on the lower end rotating shaft.

The stacking device for flywheel shell processing production is characterized in that a longitudinally-arranged supporting assembly pipe 7 with a built-in electric control hydraulic elevator 2 is fixedly installed at the upper end of a main bottom supporting frame 1 through bolts, a top assembly pipe 8 with an upper-arranged steering arm 9 movably assembled at the upper end is installed at the upper end of the longitudinally-arranged supporting assembly pipe 7, and a driving motor 3 for controlling the extension, the extension and the turnover of a turnover limiting rod 15 is installed on the upper-arranged steering arm 9, so that the stacking device can be suitable for flywheel shells with various specifications as required, and can be used for carrying and stacking a plurality of flywheel shells simultaneously by stretching, the processing efficiency is greatly improved, and the application range is wider; the overturning limiting rod 15 can be synchronously controlled to overturn and stretch by using a single motor, so that the overturning limiting rod can be adapted to flywheel shells of various specifications, and can be overturned and contracted to be inserted into the lateral overturning accommodating groove 16 in an inoperative state, so that the durability and the safety of the overturning limiting rod are improved; the whole equipment adopts the upper adjusting motor 5 and the side adjusting motor 6 to control steering and driving, adopts a self-propelled design, and has more diverse use environments and more flexible operation; an iron adjusting spring 14 is arranged between the iron adsorption plate 12 and the overhead steering arm 9, and the bottom assembling seat 11 can be more conveniently assembled through the iron adjusting spring 14, so that the operation is simpler and more convenient.

In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (7)

1. The utility model provides a pile up device for bell housing processing production, includes main bottom sprag frame (1), installs automatically controlled hydraulic lift (2), driving motor (3), annular electromagnet (4), overhead adjusting motor (5) and side on main bottom sprag frame (1) and puts adjusting motor (6), characterized by: main bottom support frame (1) upper end install through bolt fixed mounting indulge and put support assembly pipe (7), automatically controlled hydraulic lift (2) through bolt fixed mounting indulge put support assembly pipe (7) inside, automatically controlled hydraulic lift (2) upper end lifter top axial fixity install top assembly pipe (8), top assembly pipe (8) upper end activity be equipped with overhead steering arm (9), overhead steering arm (9) inside offer interior installation cavity (10) that are used for installing annular electromagnet (4), overhead steering arm (9) outside lower extreme be located annular electromagnet (4) below and be provided with bottom assembly seat (11), bottom assembly seat (11) upper end fixed mounting have top installation box (13) of built-in iron adsorption plate (12), iron adsorption plate (12) and overhead steering arm (9) outside lower extreme between through iron regulating spring (14) elastic connection The side overturning and accommodating device comprises a bottom assembly seat (11), wherein a side overturning and accommodating groove (16) with a built-in overturning limiting rod (15) is formed in the outer side surface of the bottom assembly seat (11), an internal transmission cavity (17) used for installing a driving motor (3) is formed in the bottom assembly seat (11), and the driving motor (3) is in transmission connection with the inner side end of the overturning limiting rod (15) through a transmission gear set on a lower end rotating shaft.

2. The stacking device for flywheel housing machining production as claimed in claim 1, wherein: the overturning limiting rod (15) comprises an internal overturning barrel (18) movably mounted in the lateral overturning containing groove (16) through a lateral rotating shaft, an internal adjusting rod (19) inserted in the internal overturning barrel (18), an integral-structure external thread screw rod (20) axially fixed at the outer side end of the internal adjusting rod (19) and an external telescopic internal thread pipe (21) in threaded sleeve connection with the outer side of the external thread screw rod (20).

3. The stacking device for flywheel housing machining production as claimed in claim 2, wherein: the transmission gear set comprises a spherical transmission gear (22) movably arranged in the lateral overturning and accommodating groove (16) through a longitudinal rotating shaft, a lateral gear disc (23) axially fixed on the lateral rotating shaft, a main transmission gear (24) axially fixed on a rotating shaft at the lower end of the driving motor (3) and a lateral linkage gear (25) used for meshing and transmitting the lateral gear disc (23) and the main transmission gear (24).

4. The stacking device for flywheel housing machining production as claimed in claim 1, wherein: and a flexible corrugated limiting pipe (26) is sleeved between the lower end of the outer side of the overhead steering arm (9) and the upper end of the outer side of the top mounting box (13).

5. The stacking device for flywheel housing machining production as claimed in claim 1, wherein: the overhead steering arm (9) comprises an inverted L-shaped structure top supporting tube (27) axially connected to the upper end of the top assembly tube (8) and a lateral contraction tube (28) movably assembled on the top supporting tube (27) through a lateral connecting shaft.

6. The stacking device for flywheel housing machining production as claimed in claim 1, wherein: and a lateral control handle (30) with a built-in control switch panel (29) is fixed on the outer side surface of the overhead steering arm (9) through bolts.

7. The stacking device for flywheel housing machining production as claimed in claim 1, wherein: the bottom vertex angle position of the main bottom support frame (1) is provided with a bottom assembly through hole (32) internally provided with a bottom adjusting disc (31), the lower surface of the bottom adjusting disc (31) and the lower surface of the main bottom supporting frame (1) are movably assembled with bottom rollers (34) through a bottom mounting frame (33), the upper adjusting motor (5) is fixedly arranged on the upper surface of the bottom adjusting disk (31) through a bolt, the side adjusting motor (6) is fixedly arranged above the main bottom support frame (1) through a bolt, the edge position of the upper surface of the bottom adjusting disc (31) is provided with an integral lateral transmission gear ring (35) which protrudes upwards, the side adjusting motor (6) is engaged and driven by a first transmission gear on the side transmission shaft and a side transmission gear ring (35), the upper adjusting motor (5) is in transmission connection with the bottom roller (34) through a second transmission gear on the lower rotating shaft.

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