CN114013494A

CN114013494A - Flywheel shell transfer stacking device

Info

Publication number: CN114013494A
Application number: CN202111288722.8A
Authority: CN
Inventors: 周平; 于东生; 黄健; 马金柱
Original assignee: Dongtai Jieshun Machinery Manufacturing Co ltd
Current assignee: Dongtai Jieshun Machinery Manufacturing Co ltd
Priority date: 2021-11-02
Filing date: 2021-11-02
Publication date: 2022-02-08
Anticipated expiration: 2041-11-02
Also published as: CN114013494B

Abstract

The invention relates to the technical field of transportation and stacking of flywheel shells, in particular to a stacking device for transferring flywheel shells. According to the flywheel shell transfer stacking device, the upper stacking pipe controlled by the lateral hydraulic support rod is movably assembled through the strip-shaped assembling port on the support base, the flywheel shells are stacked and placed through the upper stacking pipe, the flywheel shells can be prevented from being displaced and falling off in the stacking process, and the safety is greatly improved; the lower surface of the supporting base is provided with a lower control groove for mounting a lateral hydraulic supporting rod, and the angle of the upper stacking pipe can be changed according to needs, so that the flywheel shell is more diversified in arrangement mode and more extensive in application mode; the bottom driving wheel controlled by the driving motor is arranged at the vertex angle position of the lower surface of the supporting base, so that the whole stacking device is simpler and more convenient to transport.

Description

Flywheel shell transfer stacking device

Technical Field

The invention relates to the technical field of transportation and stacking of flywheel shells, in particular to a stacking device for transporting flywheel shells.

Background

Flywheels, disc-shaped parts with a high moment of inertia, act as an energy store. For a four-stroke engine, work is done once every four piston strokes, namely, only the working stroke does work, and the three strokes of exhaust, air intake and compression all consume work. Therefore, the torque output by the crankshaft is periodically changed, and the rotating speed of the crankshaft is unstable. To improve this situation, a flywheel is provided at the rear end of the crankshaft.

The flywheel shell is a mechanism for installing the flywheel, the safety and the stability of the flywheel in the working process are improved, the flywheel shell is generally installed between an automobile engine and a gearbox, after the flywheel shell is machined and produced, the flywheel shell needs to be transported and stacked, the traditional flywheel shell is transported to be mostly and directly placed on the surface of a transport vehicle through stacking, the stability is not enough in the transportation process, and the flywheel shell needs to be frequently bent to be placed when being placed, time and labor are wasted, and the safety is not high.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: in order to solve the problem that exists among the above-mentioned background art, provide a modified flywheel shell and transport with piling up device, solve traditional flywheel shell and transport most directly through piling up and put on the transfer car (buggy) surface, stability is not enough in the transportation, need frequently bow when putting moreover and put, not only wastes time and energy, the not high problem of security moreover.

The technical scheme adopted by the invention for solving the technical problems is as follows: the stacking device for the transfer of the flywheel shells comprises a supporting base, a driving motor, a lateral hydraulic support rod, an adjusting motor and an internal hydraulic support rod, wherein a bar-shaped assembly opening with a built-in lateral assembly blind hole is formed in the upper surface of the supporting base, an upper stacking pipe controlled by the lateral hydraulic support rod is arranged at the upper end of the supporting base, a lower control groove communicated with the bar-shaped assembly opening is formed in the lower surface of the supporting base, a top assembly frame used for installing the lateral hydraulic support rod is fixed to the upper stacking pipe at two sides of the top surface in the lower control groove through bolts, a longitudinal adjusting screw rod of a lifting supporting mechanism is sleeved with an outer thread in the upper stacking pipe in a movable mode, longitudinal lifting openings are symmetrically formed in two sides of the outer wall of the upper stacking pipe, a first supporting plate of an inverted L-shaped structure protruding towards a left longitudinal lifting opening and a plate-shaped structure protruding towards a right longitudinal lifting opening are elastically assembled on the outer side surface of the lifting supporting mechanism A structural second support plate.

The upper stacking pipe is inserted into a lateral assembly blind hole and is movably connected with a bar-shaped assembly opening through an integrated structure assembly pipe at the bottom of two sides, a lateral assembly clamping groove used for installing an electromagnet is formed in the position, corresponding to a longitudinal lifting opening, of the outer lateral surface of the lifting supporting mechanism, and the outer lateral wall of the electromagnet is respectively and elastically connected with a first supporting plate and a second supporting plate through an iron extrusion spring.

The lateral side of the lifting support mechanism is provided with an integral lateral movable assembly support with a protruding longitudinal lifting opening, and the first support plate and the second support plate penetrate through the lateral movable assembly support and the lateral movable assembly support through transverse rotating shafts on the connecting ends respectively.

The supporting base is internally provided with an internal transmission cavity with a built-in transmission gear set, and the driving motor is in transmission connection with the bottom driving wheel through the transmission gear set.

The upper surface of the supporting base is provided with a top assembling opening with an opening at the upper end, and the upper end of the supporting base is movably assembled with a movable control rod of an overhead control handle through the top assembling opening.

The adjusting motor is fixed on the inner bottom surface of the upper stacking pipe through bolts, and a rotating shaft at the upper end of the adjusting motor is coaxially fixed with the lower end of the longitudinal adjusting screw rod through a coupler.

The upper surface of the supporting base is positioned at the periphery of the strip-shaped assembling port and is provided with a strip-shaped accommodating groove with a built-in bottom extrusion elastic sheet.

The lower end of the first supporting plate is provided with an arc transition groove matched with the longitudinal adjusting screw rod.

The side direction hydraulic support rod is sleeved inside the side direction assembly ring through the top linkage support and is movably connected with the outer side of the upper stacking pipe.

Lateral assembling grooves used for improving the overturning stability are symmetrically formed in the positions, corresponding to the strip-shaped assembling holes, of the lower end of the outer side surface of the upper stacking pipe.

The invention has the beneficial effects that:

(1) according to the flywheel shell transfer stacking device, the upper stacking pipe controlled by the lateral hydraulic support rod is movably assembled through the strip-shaped assembling port on the support base, the flywheel shells are stacked and placed through the upper stacking pipe, the flywheel shells can be prevented from being displaced and falling off in the stacking process, and the safety is greatly improved;

(2) a longitudinal adjusting screw rod of which the outer side is in threaded sleeve connection with the lifting support mechanism is movably assembled in the upper stacking pipe, and the lifting support mechanism can be adjusted in height by using an adjusting motor, so that the lifting control of the flywheel shell on the outer side of the upper stacking pipe can be facilitated, and the flywheel shell can be placed and taken more stably and more labor-saving;

(3) the lower surface of the supporting base is provided with a lower control groove for mounting a lateral hydraulic supporting rod, and the angle of the upper stacking pipe can be changed according to needs, so that the flywheel shell is more diversified in arrangement mode and more extensive in application mode;

(4) the outer side surface of the lifting support mechanism is elastically provided with an inverted L-shaped structure first support plate and a plate-shaped structure second support plate which are controlled by an electromagnet, so that the inner wall of the flywheel shell can be supported and limited, meanwhile, the flywheel shell can be conveniently and quickly separated, and the elastic damping performance can be improved;

(5) the bottom driving wheel controlled by the driving motor is arranged at the vertex angle position of the lower surface of the supporting base, so that the whole stacking device is simpler and more convenient to transport.

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 present invention.

Fig. 3 is a partial cross-sectional view of the position of the elevation support mechanism in the present invention.

Fig. 4 is a partial sectional view showing the position of the elevation supporting mechanism in the second embodiment of the present invention.

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.

Fig. 1, fig. 2 and fig. 3 show a flywheel shell is transported and is used and pile up device, including supporting base 1, driving motor 2, side direction hydraulic pressure vaulting pole 3, accommodate motor 4 and inside hydraulic pressure vaulting pole 5, support base 1 upper surface and offer the bar assembly mouth 6 of built-in side direction assembly blind hole, support base 1 upper end and be provided with the overhead stack pipe 7 by side direction hydraulic pressure vaulting pole 3 control, support base 1 lower surface and offer the lower control tank 8 that is linked together with bar assembly mouth 6, the top surface lies in the equal bolt fastening in overhead stack pipe 7 both sides in lower control tank 8 and is used for installing top assembly frame 9 of side direction hydraulic pressure vaulting pole 3, the inside activity of overhead stack pipe 7 is equipped with outside screw and cup joints vertical adjusting screw 10 of lift supporting mechanism 33, the outside wall bilateral symmetry of overhead stack pipe 7 has seted up vertical lift opening 11, the first 12 of the first and the first supporting plate 12 of the protruding inverted L type structure of the vertical lift opening of left side of elastic assembly on the lateral surface of lift supporting mechanism 33 and has been equipped with bracing plate And a second support plate 13 with a plate-shaped structure and a convex opening which is raised towards the right side in the longitudinal lifting mode.

The driving motor 2, the lateral hydraulic support rod 3, the adjusting motor 4 and the internal hydraulic support rod 5 are all powered by a vehicle-mounted storage battery and then are independently controlled by a control switch.

Furthermore, in order to match with the extension and retraction of the lateral electromagnetic control, the upper stacking pipe 7 is inserted into a lateral assembly blind hole through an integrated structure assembly pipe at the bottoms of the two sides and is movably connected with the strip-shaped assembly opening, a lateral assembly clamping groove for installing the electromagnet 14 is formed in the position, corresponding to the longitudinal lifting opening 11, of the outer side surface of the lifting supporting mechanism 33, and the outer side wall of the electromagnet 14 is elastically connected with the first supporting plate 12 and the second supporting plate 13 through an iron extrusion spring 15 respectively.

The electromagnet 14 is started to control the iron extrusion spring 15 to contract, so that the first support plate 12 and the second support plate 13 are controlled to be overturned and accommodated towards the direction of the longitudinal adjusting screw 10.

Example 2: as shown in fig. 4, the electromagnet 14 and the iron pressing spring 15 may be replaced with the internal hydraulic strut 5 to control the first support plate 12 and the second support plate 13 to be turned.

Further, in order to match with lateral assembly and laterally slide and limit, the lateral side of the lifting support mechanism 33 is provided with an integral lateral movable assembly support 16 protruding towards the longitudinal lifting opening 11, and the first support plate 12 and the second support plate 13 penetrate through the lateral movable assembly support 16 and the lateral movable assembly support 16 through transverse rotating shafts on the connecting ends respectively.

Furthermore, in order to facilitate the transfer, a lateral transmission groove 18 with a built-in bottom transmission wheel 17 is formed in the vertex angle position of the lower surface of the support base 1, a lateral assembly clamping groove 19 for mounting the driving motor 2 is formed in the inner side surface of the lower control groove 8, an internal transmission cavity with a built-in transmission gear set 20 is formed in the support base 1, and the driving motor 2 is in transmission connection with the bottom transmission wheel 17 through the transmission gear set 20.

The supporting base 1 is controlled in a transferring way in an electric control mode, and the driving motor 2 drives the bottom driving wheel 17 at the right end to rotate through the driving gear set 20.

The transmission gear set 20 is composed of a conical transmission gear which is coaxially sleeved on the connecting shaft of the right bottom transmission wheel 17 and a conical driving gear which is coaxially fixed on the rotating shaft on the right side of the driving motor 2, and the conical transmission gear and the conical driving gear are in meshed transmission.

Further, for the cooperation control, the upper surface of the support base 1 is provided with a top assembly opening 21 with an open upper end, and the upper end of the support base 1 is movably assembled with a movable control rod 23 of an overhead control handle 22 through the top assembly opening 21.

The movable control rod 23 is assembled in a movable assembly mode, so that the control mode can be greatly improved, and the device is suitable for people with different heights.

Meanwhile, the movable control rod 23 can also control the bottom driving wheel 17 at the left end to rotate.

Further, in order to match with internal adjustment, the adjusting motor 4 is fixed on the inner bottom surface of the upper stacking pipe 7 through bolts, and a rotating shaft at the upper end of the adjusting motor 4 is coaxially fixed with the lower end of the longitudinal adjusting screw rod 10 through a coupler.

The adjusting motor 4 is controlled to rotate, so that the longitudinal adjusting screw 10 is driven to rotate, and the longitudinal adjusting screw 10 drives the lifting support mechanism 33 to lift.

Further, in order to improve the elastic shock absorption capacity of the bottom, a strip-shaped accommodating groove 25 with a built-in bottom extrusion elastic sheet 24 is formed in the periphery of the strip-shaped assembly opening 6 on the upper surface of the supporting base 1.

The bottom pressing spring plate 24 is composed of an inner support plate and a pressing spring installed between the lower surface of the inner support plate and the inner bottom surface of the strip-shaped receiving groove 25.

Further, in order to increase the turning angle and facilitate turning and storage, the lower end of the first support plate 12 is provided with an arc transition groove 26 matched with the longitudinal adjusting screw 10.

Furthermore, in order to match with the bottom movable assembly, lateral assembly rings 27 of an integrated structure are arranged on two sides of the bottom end of the upper stacked pipe 7, a top linkage support 28 matched with the lateral assembly rings 27 is coaxially fixed at the top end of a telescopic rod of the lateral hydraulic support rod 3, and the lateral hydraulic support rod 3 is sleeved inside the lateral assembly rings 27 through the top linkage support 28 and is movably connected with the outer side of the upper stacked pipe 7.

Further, in order to improve the fitting performance of the assembly surface and improve the turnover stability, lateral assembly grooves 29 for improving the turnover stability are symmetrically arranged at the lower end of the outer side surface of the upper stacking pipe 7 corresponding to the strip-shaped assembly openings 6.

According to the flywheel shell transfer stacking device, the upper stacking pipe 7 controlled by the lateral hydraulic support rod 3 is movably assembled through the strip-shaped assembling port 6 in the support base 1, the flywheel shells are stacked and placed through the upper stacking pipe 7, the flywheel shells can be prevented from being displaced and falling off in the stacking process, and the safety is greatly improved; a longitudinal adjusting screw 10 of which the outer side is in threaded sleeve connection with a lifting support mechanism is movably assembled in the upper stacking tube 7, and the lifting support mechanism can be adjusted in height by using the adjusting motor 4, so that the lifting control of the flywheel shell on the outer side of the upper stacking tube 7 can be facilitated, and the flywheel shell can be placed and taken more stably and more labor-saving; the lower surface of the supporting base 1 is provided with a lower control groove 8 for mounting the lateral hydraulic supporting rod 3, and the angle of the upper stacking pipe 7 can be changed according to the requirement, so that the flywheel shell can be placed in more various ways and can be applied more widely; the outer side surface of the lifting support mechanism is elastically provided with an inverted L-shaped structure first support plate 12 and a plate-shaped structure second support plate 13 which are controlled by an electromagnet 14, so that the inner wall of the flywheel shell can be supported and limited, meanwhile, the flywheel shell can be conveniently and quickly separated, and the elastic shock absorption performance can be improved; the bottom driving wheel 17 controlled by the driving motor 2 is arranged at the vertex angle position of the lower surface of the supporting base 1, so that the whole stacking device is simpler and more convenient to transport.

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

1. The utility model provides a flywheel shell transfer uses and piles up device, is including supporting base (1), driving motor (2), side direction hydraulic pressure vaulting pole (3), accommodate motor (4) and inside hydraulic pressure vaulting pole (5), characterized by: the upper surface of the supporting base (1) is provided with a bar-shaped assembly opening (6) with a built-in lateral assembly blind hole, the upper end of the supporting base (1) is provided with an upper stacked tube (7) controlled by a lateral hydraulic supporting rod (3), the lower surface of the supporting base (1) is provided with a lower control groove (8) communicated with the bar-shaped assembly opening (6), the inner top surface of the lower control groove (8) is positioned at the two sides of the upper stacked tube (7) and is fixedly provided with a top assembly frame (9) used for installing the lateral hydraulic supporting rod (3), the inner part of the upper stacked tube (7) is movably provided with a longitudinal adjusting screw rod (10) of which the outer side is in threaded sleeve connection with a lifting supporting mechanism (33), the two sides of the outer wall of the upper stacked tube (7) are symmetrically provided with longitudinal lifting notches (11), and the outer side of the lifting supporting mechanism (33) is elastically provided with a first supporting plate (12) of an inverted L-shaped structure protruding towards the left longitudinal lifting notch and a first supporting plate (12) of which protrudes towards the right side And a second support plate (13) with a plate-shaped structure and a raised longitudinal lifting gap.

2. The flywheel housing transfer stacking apparatus of claim 1, wherein: overhead pile pipe (7) insert side direction assembly blind hole and bar assembly mouth (6) swing joint through the body structure assembly pipe of both sides bottom, lift supporting mechanism (33) lateral surface correspond vertical lift opening (11) position and offer the side direction assembly draw-in groove that is used for installing electro-magnet (14), electro-magnet (14) lateral wall through iron extrusion spring (15) respectively with first backup pad (12) and second backup pad (13) elastic connection.

3. The flywheel housing transfer stacking apparatus of claim 1, wherein: the outer side face of the lifting supporting mechanism (33) is provided with an integral lateral movable assembly support (16) with a longitudinal lifting notch (11) protruding, and the first supporting plate (12) and the second supporting plate (13) penetrate through the lateral movable assembly support (16) and the lateral movable assembly support (16) through transverse rotating shafts on the connecting ends respectively.

4. The flywheel housing transfer stacking apparatus of claim 1, wherein: the support base is characterized in that a lateral transmission groove (18) with a built-in bottom transmission wheel (17) is formed in the vertex angle position of the lower surface of the support base (1), a lateral assembly clamping groove (19) used for mounting a driving motor (2) is formed in the inner side surface of the lower control groove (8), an internal transmission cavity with a built-in transmission gear set (20) is formed in the support base (1), and the driving motor (2) is in transmission connection with the bottom transmission wheel (17) through the transmission gear set (20).

5. The flywheel housing transfer stacking apparatus of claim 1, wherein: the upper surface of the supporting base (1) is provided with a top assembling opening (21) with an opening at the upper end, and the upper end of the supporting base (1) is movably provided with a movable control rod (23) of an overhead control handle (22) through the top assembling opening (21).

6. The flywheel housing transfer stacking apparatus of claim 1, wherein: the adjusting motor (4) is fixed on the inner bottom surface of the upper stacking pipe (7) through bolts, and a rotating shaft at the upper end of the adjusting motor (4) is coaxially fixed with the lower end of the longitudinal adjusting screw rod (10) through a coupler.

7. The flywheel housing transfer stacking apparatus of claim 1, wherein: the upper surface of the supporting base (1) is positioned at the periphery of the strip-shaped assembling port (6) and is provided with a strip-shaped accommodating groove (25) internally provided with a bottom extrusion elastic sheet (24).

8. The flywheel housing transfer stacking apparatus of claim 1, wherein: the lower end of the first supporting plate (12) is provided with an arc transition groove (26) matched with the longitudinal adjusting screw rod (10).

9. The flywheel housing transfer stacking apparatus of claim 1, wherein: the side direction hydraulic support rod is characterized in that two sides of the bottom end of the upper stacking pipe (7) are provided with side direction assembling rings (27) of an integral structure, a top linkage support (28) matched with the side direction assembling rings (27) is coaxially fixed at the top end of a telescopic rod of the side direction hydraulic support rod (3), and the side direction hydraulic support rod (3) is sleeved inside the side direction assembling rings (27) through the top linkage support (28) and is movably connected with the outer side of the upper stacking pipe (7).

10. The flywheel housing transfer stacking apparatus of claim 1, wherein: lateral assembling grooves (29) used for improving the overturning stability are symmetrically formed in the lower end of the outer side surface of the upper stacking pipe (7) corresponding to the strip-shaped assembling ports (6).