CN112706994B

CN112706994B - Aluminium liquid filling platform

Info

Publication number: CN112706994B
Application number: CN202011411899.8A
Authority: CN
Inventors: 李建明
Original assignee: Shuaiyichi New Material Group Co ltd; Shuaiyichi Aluminum Alloy New Material Chongqing Co ltd
Current assignee: Shuaiyichi New Material Group Co ltd; Shuaiyichi Aluminum Alloy New Material Chongqing Co ltd
Priority date: 2020-12-04
Filing date: 2020-12-04
Publication date: 2022-10-04
Anticipated expiration: 2040-12-04
Also published as: CN112706994A

Abstract

The invention relates to the technical field of aluminum liquid transportation, and provides an aluminum liquid filling platform; the aluminum liquid filling platform of the invention comprises: the device comprises a foundation pit, a connecting slide block, two groups of scissor-type lifting platforms arranged in the foundation pit, a rotary mounting seat, a filling groove, a linkage mechanism and a driver; the connecting sliding block slides to enable one scissor-type lifting platform to rise and enable the other scissor-type lifting platform to descend; the rotary mounting seat is mounted on the side wall of the foundation pit, and one end of the rotary mounting seat extends upwards out of the foundation pit; one end of the filling groove is arranged at one end of the rotary mounting seat extending out of the foundation pit; the linkage mechanism is connected with the rotary mounting seat and the connecting sliding block; the driver can drive the connecting slide block to slide in a reciprocating manner, and the other end of the filling groove can rotate to the upper part of a descending scissor-type lifting platform through the linkage mechanism and the rotating mounting seat; the aluminum liquid filling platform can be used for continuously filling the heat-preservation transport package.

Description

Aluminium liquid filling platform

Technical Field

The invention relates to the technical field of aluminum liquid transportation, in particular to an aluminum liquid filling platform.

Background

The aluminum and the aluminum alloy have good casting performance and plastic processing performance, and are widely applied to the industries of aerospace, aviation, transportation, construction, electromechanics, lightening, daily necessities and the like. It is especially used for casting various automobile parts. Generally, aluminum and aluminum alloy raw materials are mostly supplied in the form of aluminum ingots. The parts producer carries out casting production after remelting the received aluminum ingot, thereby needing to invest huge capital to build a melting furnace, and the aluminum ingot remelting also needs investment of fuel, manpower and the like, and has poor economical efficiency.

In order to solve the problems, a method for supplying aluminum and aluminum alloy raw materials directly supplied by aluminum liquid is provided. And the original material producer fills the aluminum liquid into the heat-preservation transport package, and the aluminum liquid is transported to the part manufacturer along with the heat-preservation transport package for casting production. The remelting process and equipment investment of the aluminum ingot are reduced. Because the height of the heat-preservation transport package is higher than that of the traditional aluminum liquid casting package, and the distance between the driven aluminum liquid launder and the filling platform is too small, the heat-preservation transport package filling can not be carried out. The installation height of the aluminum liquid launder is limited by the installation height of the smelting furnace, and the aluminum liquid launder cannot be lifted, so that only an aluminum liquid filling platform can be improved. The existing aluminum liquid filling platform is provided with a lifting platform and a runner with one end capable of being lifted upwards. When the thermal insulation transport bag is used, the runner is lifted, the thermal insulation transport bag is placed on the lifting platform, and the lifting platform enables the thermal insulation transport bag to sink to the ground; then putting down the launder again and filling the aluminum liquid; after the molten aluminum is filled, the launder is lifted up again, then the heat-preservation transport package is lifted up, and the heat-preservation transport package is transferred by a forklift. This aluminium liquid filling platform use is very complicated, must wait to keep warm to transport and can put into next heat preservation transportation package and carry out the filling after the package shifts out the elevating platform, can not fill in succession, and the availability factor is low. Moreover, after the launder is lifted up and placed down each time, whether the transfer joint of the launder is reliable or not needs to be checked, so that the leakage of aluminum liquid is avoided, and the filling efficiency is further limited; meanwhile, if the inspection is neglected, safety accidents are easily caused.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides an aluminum liquid filling platform. The aluminum liquid filling platform can continuously fill the heat-preservation transport package.

In order to achieve the purpose, the aluminum liquid filling platform comprises:

the device comprises a foundation pit, a connecting slide block and two groups of scissor-type lifting platforms which are arranged in the foundation pit; the scissor type lifting platform comprises a scissor pair; the connecting sliding block is slidably arranged in the foundation pit, and two ends of the connecting sliding block are respectively connected with the scissor pairs of the scissor type lifting platforms; the connecting sliding block can enable one scissor type lifting platform to be lifted and the other scissor type lifting platform to be lowered simultaneously by sliding; and the number of the first and second groups,

the device comprises a rotary mounting seat, a filling groove, a linkage mechanism and a driver, wherein the rotary mounting seat is mounted on the side wall of the foundation pit, and one end of the rotary mounting seat extends upwards out of the foundation pit; one end of the filling groove is arranged at one end of the rotary mounting seat extending out of the foundation pit; the linkage mechanism is connected with the rotary mounting seat and the connecting sliding block; the driver can drive the connecting sliding block to slide in a reciprocating mode, and the other end of the filling groove can rotate to the position above the descending scissor-type lifting platform through the linkage mechanism and the rotating mounting seat.

When the aluminum liquid filling platform is used, the heat-preservation transport package is firstly placed on the raised scissor-type lifting platform and is connected with the sliding block in a sliding manner, so that the scissor-type lifting platform descends, the heat-preservation transport package is sunk into a foundation pit, and the filling groove synchronously turns to the scissor-type lifting platform; simultaneously, the connecting slide block slides to enable the other scissor type lifting platform to be lifted. And the aluminum liquid flows into the filling tank from the smelting furnace through the runner to fill the aluminum liquid. When aluminum liquid is filled, a second heat-preservation transport package is placed on the other scissor-type lifting table; after the aluminum liquid is filled, the aluminum liquid is connected with the sliding block in a reverse sliding mode, the lifting states of the two scissor-type lifting tables are exchanged, the position of the filling groove is correspondingly changed, and a second heat-preservation transport bag is filled; and simultaneously transferring the previous heat-preservation transport bag on the lifted high-shear lifting platform and placing the next heat-preservation transport bag. Therefore, the aluminum liquid filling platform is used for continuously filling the heat-preservation transport package.

In one embodiment, the two scissor type lifting platforms are symmetrically arranged in the foundation pit; the scissor type lifting platform further comprises a bedplate, the scissor pair is provided with two scissor arms, and the middle parts of the two scissor arms are rotatably connected with each other; one end of one of the shearing fork arms is hinged with the bottom of the foundation pit, and the other end of the shearing fork arm is hinged with the bedplate in a sliding manner; and two ends of the other scissor arm are respectively hinged with the bedplate and the connecting slide block.

The connecting slide block slides to enable the scissor pairs of one scissor type lifting platform to be folded, and the scissor type lifting platform is lifted; the scissor fork pair of the other scissor fork type lifting platform is opened, and the scissor fork type lifting platform descends.

In one embodiment, a supporting chute is arranged on the bedplate, and a slidable supporting sliding block is arranged in the supporting chute; and the shearing fork arm hinged with the bottom of the foundation pit is hinged to the bedplate through the supporting sliding block. The supporting slide block slides to enable the scissor fork pair to be folded or unfolded.

In one embodiment, the rotary mounting seat comprises a seat body and a supporting shaft; the base body is arranged on the side wall of the foundation pit; the supporting shaft is rotatably arranged on the seat body, and one end of the supporting shaft extends out of the foundation pit and is used for installing the filling groove; the linkage mechanism is in transmission connection with the other end of the supporting shaft.

The linkage mechanism drives the supporting shaft to rotate, so that the filling groove rotates towards the corresponding direction.

In one embodiment, the linkage mechanism comprises a transmission gear, a transmission swing rod and a swing rod supporting seat; the transmission gear is fixedly arranged on the supporting shaft; the swing rod supporting seat is fixedly arranged in the foundation pit; the transmission swing rod is rotatably arranged on the swing rod supporting seat, one end of the transmission swing rod is provided with a sector gear meshed with the transmission gear, and the other end of the transmission swing rod is connected with the connecting slide block in a sliding hinged mode.

The connecting slide block slides to drive the transmission swing rod to rotate, and the sector gear drives the transmission gear to enable the supporting shaft to drive the filling groove to rotate.

In one embodiment, one end of the transmission swing rod, which is far away from the sector gear, is provided with a long round hole which extends along the axial direction of the transmission swing rod; the connecting sliding block is provided with a connecting shaft pin, and the connecting shaft pin can be slidably inserted into the long round hole.

When the connecting slide block slides, the connecting shaft pin is matched with the long round hole to enable the transmission swing rod to rotate.

In one embodiment, the bottom of the foundation pit is provided with a sliding groove extending along the arrangement direction of the scissor type lifting platforms, and the connecting sliding block is slidably arranged in the sliding groove.

In one embodiment, the driver is a hydraulic cylinder, a cylinder body of the hydraulic cylinder is hinged to the bottom of the foundation pit, and a piston rod of the hydraulic cylinder is hinged to the connecting slide block.

The hydraulic cylinder extends or contracts to drive the connecting slide block to slide and drive the scissor-type lifting platform to rise or fall.

Drawings

In order to more clearly illustrate the embodiments of the present invention, the drawings, which are required to be used in the embodiments, will be briefly described below. In all the drawings, the elements or parts are not necessarily drawn to actual scale.

Fig. 1 is a front view of an aluminum liquid filling table provided in an embodiment of the present invention;

FIG. 2 isbase:Sub>A sectional view A-A of the aluminum liquid filling station shown in FIG. 1;

FIG. 3 is a B-B sectional view of the aluminum liquid filling station shown in FIG. 2;

FIG. 4 is a front view of the drive pendulum of FIG. 1;

FIG. 5 is a top view of the aluminum liquid filling station shown in FIG. 1;

reference numerals:

1-foundation pit, 11-chute, 2-connecting slide block, 21-connecting shaft pin, 3-scissor type lifting platform, 31-scissor fork pair, 311-scissor fork arm, 32-platen, 321-supporting chute, 33-supporting slide block, 4-rotating mounting seat, 41-seat body, 42-supporting shaft, 5-linkage mechanism, 51-transmission gear, 52-transmission swing rod, 521-sector gear, 522-slotted hole, 53-swing rod supporting seat, 6-filling groove and 7-driver.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and therefore are only examples, and the protection scope of the present invention is not limited thereby.

In this application, unless expressly stated or limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can include, for example, fixed connections, removable connections, or integral parts; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or may be connected through the use of two elements or the interaction of two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Referring to fig. 1 to 5, the present invention provides an aluminum liquid filling platform, including: foundation ditch 1, connect slider 2 and two sets of scissors fork elevating platform 3 of installing in foundation ditch 1 to and rotate mount pad 4, filling groove 6, link gear 5 and driver 7. The heat-insulating transport bag 8 can be continuously filled through the aluminum liquid filling platform.

Referring to fig. 1 to 3, in particular, the foundation pit 1 is used for installing each component, so that the heat-insulating transport bag 8 can be sunk into the ground to be matched with a smelting furnace and an aluminum liquid launder for filling. In one embodiment, the main body of the foundation pit 1 is a rectangular foundation pit disposed on the ground.

Two sets of scissor lift tables 3 are installed in the foundation pit 1. Scissor lift 3 comprises a pair of scissor forks 31. The connecting slide block 2 is slidably arranged in the foundation pit 1. Two ends of the connecting slide block 2 are respectively connected with the scissor pairs 31 of the two scissor-type lifting platforms 3. The sliding of the connecting slide 2 enables one scissor lift 3 to be raised and simultaneously the other scissor lift 3 to be lowered. Specifically, the bottom of foundation ditch 1 is equipped with the spout 11 that extends along the 3 array directions of scissor lift platform, and link block 2 slidable installs in spout 11. In one embodiment, two scissor lift platforms 3 are symmetrically mounted within the foundation pit 1. Scissor lift 3 also includes a bedplate 32. The pair of scissors 31 has two scissors arms 311, and the middle portions of the two scissors arms 311 are rotatably connected to each other. One end of one of the scissor arms 311 is hinged to the bottom of the foundation pit 1, and the other end is slidably hinged to the bedplate 32. The other scissor arm 311 is hinged with the bedplate 32 and the connecting slide block 2 at two ends respectively. Specifically, the platen 32 is provided with a support chute 321, and a slidable support slider 33 is mounted in the support chute 321. A scissor arm 311 articulated to the bottom of the excavation 1 is connected to the bedplate 32 by articulation with the support slide 33. The scissors 31 can be folded or unfolded to enable the supporting sliding block 33 to slide correspondingly. In one embodiment, the connecting slider 2 has a strip-shaped structure. The connecting slide block 2 is arranged between the two scissor-type lifting platforms 3. One end of the other scissor arm 311 close to the symmetrical mounting surfaces of the two scissor type lifting tables 3 is hinged with the connecting slide block 2. When the connecting slide block 2 slides, the scissor fork pair 31 on one side of the sliding direction of the connecting slide block 2 is folded, the corresponding scissor fork type lifting platform 3 is lifted, and the bedplate 32 is lifted to be flush with the ground. In one embodiment, the supporting sliding slot 321 is a T-shaped slot, and the supporting sliding block 33 is a T-shaped block matching with the T-shaped slot. The T-block supports the platen 32 while sliding, while preventing the platen 32 from tipping over when unevenly loaded. The connecting slide block 2 slides to fold the scissor pair 31 of one scissor type lifting platform 3, and the scissor type lifting platform 3 rises; and the scissor pairs 31 of the other scissor lift 3 are opened and the scissor lift 3 is lowered. It will be appreciated that the pairs of scissors 31 of the scissors lift 3 may be arranged in a plurality of groups, and each group of pairs of scissors 31 can be closed or opened synchronously to provide stable support for the platform 32.

The rotary mounting seat 4 is installed on the side wall of the foundation pit 1, and one end of the rotary mounting seat 4 extends upwards out of the foundation pit 1. One end of the filling groove 6 is mounted on the end of the rotary mounting base 4 extending out of the foundation pit 1. Specifically, the rotation mount 4 includes a mount body 41 and a support shaft 42. The base body 41 is mounted on the side wall of the foundation pit 1. The supporting shaft 42 is rotatably installed on the base body 41, and one end of the supporting shaft 42 extends out of the foundation pit 1 for installing the filling groove 6. 1. In the embodiment, the base 41 has a cylindrical structure. The base body 41 is vertically installed on the embedded member on the side wall of the foundation pit 1. The supporting shaft 42 is inserted into the cylindrical structure of the base body 41. The lower end of the support shaft 42 extends out of the seat body 41 and abuts against the bottom of the foundation pit 1. The upper end of the support shaft 42 extends out of the foundation pit 1. It will be appreciated that a thrust bearing may be provided at the lower end of the support shaft 42 to bear against the support shaft 42. The filling tank 6 is made of temperature-resistant materials and can bear the high temperature of the aluminum liquid. In one embodiment, one end of the filling trough 6 is fixedly mounted on the upper end of the support shaft 42 for receiving the molten aluminum of the launder of the smelting furnace. The other end of the filling groove 6 extends to the scissor type lifting platform 3 and is used for guiding the aluminum liquid into a heat preservation transportation bag 8 placed on the scissor type lifting platform 3.

Referring to fig. 4, the linkage mechanism 5 rotates the mounting base 4 and the connecting slider 2. The driver 7 can drive the connecting slide block 2 to slide back and forth, and can rotate the other end of the filling groove 6 to the upper part of the descending scissor-type lifting platform 3 through the linkage mechanism 5 and the rotating mounting seat 4. The filling groove 6 rotates to avoid the raised heat-preservation transport package 8, so that the heat-preservation transport package 8 is convenient to replace; at the same time, a filled and lowered insulated transport package 8 is prepared. Specifically, the linkage mechanism 5 is in transmission connection with the other end of the support shaft 42. The linkage mechanism 5 drives the supporting shaft 42 to rotate, so that the filling tank 6 rotates towards the corresponding direction. In one embodiment, the linkage mechanism 5 includes a transmission gear 51, a transmission swing link 52 and a swing link supporting seat 53. The transmission gear 51 is fixed to the support shaft 42. Specifically, the transmission gear 51 is fixedly mounted on the lower end of the support shaft 42. The swing rod supporting seat 53 is fixedly arranged in the foundation pit 1. The transmission swing rod 52 is rotatably mounted on the swing rod support seat 53, one end of the transmission swing rod 52 is provided with a sector gear 521 meshed with the transmission gear 51, and the other end of the transmission swing rod 52 is slidably hinged with the connecting slide block 2. Specifically, the swing rod supporting seat 53 is installed on an embedded part at the bottom of the foundation pit 1. The swing link supporting seat 53 is provided with a rotating shaft for mounting the transmission swing link 52. The rotating axis of the transmission swing link 52 is coincident with the central line of the sector gear 521. The sector gear 521 is externally engaged with the transmission gear 51, and the transmission swing rod 52 rotates in the direction opposite to the rotation direction of the support shaft 42. One end of the transmission swing rod 52 far away from the sector gear 521 is provided with an oblong hole 522 extending along the axial direction of the transmission swing rod 52. The connecting slide block 2 is provided with a connecting shaft pin 21, and the connecting shaft pin 21 is slidably inserted into the long round hole 522. When the connecting slide block 2 slides, the transmission swing rod 52 rotates through the matching of the connecting shaft pin 21 and the long round hole 522. The connecting slide block 2 slides to drive the transmission swing rod 52 to rotate, and the sector gear 521 drives the transmission gear 51 to drive the supporting shaft 42 to drive the filling tank 6 to rotate. It can be understood that when the sector gear 521 swings with the transmission swing link 52, the direction of the movement component of the sector gear 521 along the axial direction of the connecting slider 2 is opposite to the sliding direction of the connecting slider 2. The direction of rotation of the driving oscillating bar 52 is opposite to the direction of rotation of the support shaft 42, and the filling groove 6 faces the side of the driving gear 51 meshing with the sector gear 521, so that the direction of the movement component of the filling groove 6 in the axial direction of the coupling slider 2 is opposite to the sliding direction of the coupling slider 2. Since the scissor lift table 3 on the side of the connecting slide 2 facing the sliding direction is raised, the scissor lift table 3 on the side of the filling groove 6 facing away is lowered.

In one embodiment, the driver 7 is a hydraulic cylinder, a cylinder body of the hydraulic cylinder is hinged to the bottom of the foundation pit 1, and a piston rod of the hydraulic cylinder is hinged to the connecting slide block 2. The hydraulic cylinder extends or contracts to drive the connecting slide block 2 to slide and drive the scissor-type lifting platform 3 to ascend or descend. It will be appreciated that the drive 7 may also be a linear stepper motor or a crank-slider mechanism with motor drive.

Referring to fig. 5, when the aluminum liquid filling platform of the present invention is used, the heat preservation transport bag 8 is first placed on the elevated scissor type lifting platform 3. The sliding block 2 is connected in a sliding way, so that the scissor type lifting platform 3 descends to enable the heat preservation transportation bag 8 to sink into the foundation pit 1. The filling trough 6 is turned synchronously to the scissor lift 3. At the same time, the connecting slide 2 slides to raise the other scissor lift 3. And the aluminum liquid flows into the filling tank 6 from the smelting furnace through the runner to fill the aluminum liquid. When aluminum liquid is filled, a second heat preservation transportation bag 8 is placed on the other scissor type lifting platform 3. After the aluminum liquid is filled, the sliding block 2 is connected in a reverse sliding mode, and the lifting states of the two scissor-type lifting tables 3 are interchanged. The position of the filling tank 6 is changed accordingly, and the second insulated transport package 8 is filled. Meanwhile, the previous heat preservation transport bag 8 is transferred on the lifted high-shear type lifting platform 3, and the next heat preservation transport bag 8 is placed. Therefore, the aluminum liquid filling platform is used for continuously filling the heat-preservation transportation bag 8, and the using efficiency is high.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may be modified, or some or all of the technical features may be equivalently replaced; the modifications or substitutions do not depart from the spirit of the technical solutions of the embodiments of the present invention, and the technical solutions of the embodiments of the present invention are intended to be covered by the claims and the specification.

Claims

1. The utility model provides an aluminium liquid filling platform which characterized in that includes:

the device comprises a foundation pit, a connecting slide block and two groups of scissor-type lifting platforms which are arranged in the foundation pit; the scissor type lifting platform comprises a scissor pair; the connecting sliding block is slidably arranged in the foundation pit, and two ends of the connecting sliding block are respectively connected with the scissor pairs of the scissor type lifting platforms; the connecting sliding block can enable one scissor type lifting platform to be lifted and enable the other scissor type lifting platform to be lowered at the same time in a sliding mode; and the number of the first and second groups,

the device comprises a rotating installation seat, a filling groove, a linkage mechanism and a driver, wherein the rotating installation seat is installed on the side wall of the foundation pit, and one end of the rotating installation seat extends upwards out of the foundation pit; one end of the filling groove is arranged at one end of the rotary mounting seat extending out of the foundation pit; the linkage mechanism is connected with the rotary mounting seat and the connecting sliding block; the driver can drive the connecting slide block to slide in a reciprocating manner, and the other end of the filling groove can rotate to the position above a descending scissor type lifting platform through the linkage mechanism and the rotating mounting seat;

the linkage mechanism comprises a transmission gear, a transmission swing rod and a swing rod supporting seat; the transmission gear is fixedly arranged on the rotary mounting seat; the swing rod supporting seat is fixedly arranged in the foundation pit; the transmission swing rod is rotatably arranged on the swing rod supporting seat, a sector gear is arranged at one end of the transmission swing rod and meshed with the transmission gear, and the other end of the transmission swing rod is slidably hinged with the connecting slide block;

one end of the transmission swing rod, which is far away from the sector gear, is provided with a long round hole which extends along the axial direction of the transmission swing rod; and the connecting slide block is provided with a connecting shaft pin, and the connecting shaft pin can be slidably inserted into the long round hole.

2. The aluminum liquid filling platform according to claim 1, wherein the two scissor-type lifting platforms are symmetrically installed in the foundation pit; the scissor fork type lifting platform further comprises a platform plate, the scissor fork pair is provided with two scissor fork arms, and the middle parts of the two scissor fork arms are rotatably connected with each other; one end of the scissor arm is hinged with the bottom of the foundation pit, and the other end of the scissor arm is hinged with the bedplate in a sliding manner; and two ends of the other scissor arm are respectively hinged with the bedplate and the connecting slide block.

3. The aluminum liquid filling table as claimed in claim 2, wherein a supporting chute is arranged on the platen, and a slidable supporting slide block is arranged in the supporting chute; and the shearing fork arm hinged with the bottom of the foundation pit is hinged to the bedplate through the supporting sliding block.

4. The aluminum liquid filling table as claimed in claim 1, wherein the rotary mounting seat comprises a seat body and a support shaft; the base body is arranged on the side wall of the foundation pit; the supporting shaft is rotatably arranged on the seat body, and one end of the supporting shaft extends out of the foundation pit and is used for installing the filling groove; the linkage mechanism is in transmission connection with the other end of the supporting shaft.

5. The aluminum liquid filling platform as claimed in claim 1, wherein a sliding groove extending along the arrangement direction of the scissor lift platforms is formed at the bottom of the foundation pit, and the connecting sliding block is slidably mounted in the sliding groove.

6. The aluminum liquid filling table as claimed in claim 1, wherein the driver is a hydraulic cylinder, a cylinder body of the hydraulic cylinder is hinged to the bottom of the foundation pit, and a piston rod of the hydraulic cylinder is hinged to the connecting slide block.