CN116984596A - Full-automatic steel sample stripper - Google Patents

Abstract

The application relates to the technical field related to a stripper, and particularly discloses a full-automatic steel sample stripper which comprises a stripper frame, wherein a fixed placing plate is fixedly connected to the rear inner wall of the stripper frame, two rotary driving motors are fixedly connected to the right inner wall of the stripper frame, a rotary traction shaft is fixedly connected to the output shaft of each rotary driving motor, two rotary cams are fixedly connected to the side surfaces of each rotary traction shaft, a die placing base is movably contacted with the upper surface of the fixed placing plate, traction pulleys are fixedly connected to four corners of the lower surface of the die placing base, four limit springs are fixedly connected to the inner top surface of the stripper frame, and one die pressing plate is fixedly connected to the lower ends of the four limit springs.

Description

Full-automatic steel sample stripper

Technical Field

The application relates to the technical field of stripper machines, in particular to a full-automatic steel sample stripper machine.

Background

The casting is a metal hot processing technology, namely, the casting is formed by smelting metal into liquid and pouring the liquid into a mould, and then forming a mechanical fitting with a certain preset shape after cooling and solidification, and demoulding is needed to be carried out on the casting after the casting is completed;

some steel samples are produced in the mode, after casting is finished, the steel samples can be separated from the die by vibrating the die by using a stripper and then are collected by utilizing inertia, but the stripper is usually used for stripping larger steel samples, and when smaller steel samples are used by using the stripper, the smaller steel samples are easy to separate from the stripper due to lighter weight and smaller volume, so that unnecessary loss is caused, more manpower and material resources are increased if the smaller steel samples are stripped manually, the technical requirements on operators are higher, the smaller steel samples can be well fixed and can not be separated when being stripped, and the stripping can be automatically completed, so that the convenience of operation is improved.

Disclosure of Invention

(one) solving the technical problems

Aiming at the defects of the prior art, the application provides a full-automatic steel sample stripper, which solves the technical problem that a smaller steel sample is difficult to strip.

(II) technical scheme

In order to achieve the above purpose, the application is realized by the following technical scheme:

the full-automatic steel sample stripper comprises a stripper frame, wherein a fixed placing plate is fixedly connected to the rear inner wall of the stripper frame, sample falling grooves are formed in the middle of the upper surface of the fixed placing plate, two cam movable grooves are formed in the front surface and the rear surface of the fixed placing plate, two rotary driving motors are fixedly connected to the right inner wall of the stripper frame, a rotary traction shaft is fixedly connected to the output shaft of each rotary driving motor, two rotary cams are fixedly connected to the side surface of each rotary traction shaft, and the left end of each rotary traction shaft is rotatably connected with the left inner wall of the stripper frame;

the upper end of each rotating cam is positioned in a similar cam movable groove, the upper surface of the fixed placement plate is movably contacted with a mold placement base, traction pulleys are fixedly connected to four corners of the lower surface of the mold placement base, each traction pulley is contacted with the side surface of the similar rotating cam, the upper surface of the mold placement base is provided with a mold placement groove, the bottom surface of the mold placement groove is provided with a sample falling hole, the sample falling hole is aligned with the sample falling groove, the inner top surface of the mold stripper frame is fixedly connected with four limit springs, and the lower ends of the four limit springs are fixedly connected with the same mold pressing plate;

each limit spring is movably sleeved with a round sleeve and a round rod;

wherein each round sleeve is movably sleeved with a similar round rod.

Preferably: the upper end of each round sleeve is fixedly connected with the inner top surface of the stripper frame;

the lower end of each circular rod is fixedly connected with the upper surface of the die pressing plate;

the side surface of each circular sleeve is provided with a first rectangular chute, and the side surface of each circular rod is fixedly connected with a limit slide plate;

each limiting slide plate is movably clamped with a similar first rectangular slide groove.

Preferably: the upper surface of the fixed placement plate is fixedly connected with two limiting vertical rods, and limiting circular grooves are formed in the left end and the right end of the bottom surface of the die placement base;

wherein each limit vertical rod is movably sleeved with a similar limit round groove;

limiting through holes are formed in the side surfaces of the limiting vertical rods, and limiting round holes are formed in the left and right surfaces of the die pressing plate;

wherein, every spacing through-hole all activity has cup jointed spacing circular column.

Preferably: the inner bottom surface of the stripper frame is fixedly connected with a placing bottom plate;

wherein, the upper surface of the placing bottom plate is movably contacted with a steel sample falling-off collecting box;

a second rectangular chute is formed in the upper surface of the placement bottom plate, and a rectangular slide bar is fixedly connected to the lower surface of the steel sample falling-off collection box;

the rectangular sliding strip is movably clamped with the second rectangular sliding groove.

Preferably: the front surface of the rectangular sliding strip is fixedly connected with a square pulling plate, and two square movable holes are formed in the front surface of the square pulling plate;

the front end of each limit threaded column is fixedly connected with a limit square plate, and each limit square plate is in close contact with the front surface of the square pulling plate;

the front surface of the placement bottom plate is provided with two threaded holes;

and each threaded hole is in threaded sleeve joint with a similar limit threaded column.

(III) beneficial effects

1. When the device is used, the mould to be demoulded is placed in the mould placing groove on the mould placing base, then two rotary driving motors are started, the two rotary driving motors drive the rotary cams to rotate through the rotary traction shafts, the rotary cams drive the mould placing base to vibrate up and down through the cooperation of the rotary traction shafts, thereby driving the mould to vibrate up and down, the steel sample falls off from the mould through the effect of inertia, and falls down from the sample falling hole and the sample falling groove, in order to prevent the mould from falling off from the mould placing base during vibration and the mould placing base from shifting during vibration, the mould pressing plate is pressed above the mould, a certain limiting effect is generated on the mould under the cooperation of the limiting springs, and simultaneously, the two limiting vertical rods and the limiting circular groove cooperate to prevent the mould placing base from shifting.

2. When placing the mould on the base is placed to the mould, the mould clamp plate can influence the placing of mould, can lift up the mould clamp plate, make the spacing round hole of mould clamp plate left and right sides and the spacing through-hole alignment on two spacing montants, insert spacing round hole with spacing round post again in can fix the mould clamp plate in higher position through spacing through-hole, after the mould is placed, pull out two spacing round bars from spacing round hole, the clamp plate just can drop to the mould top, the mould carries out spacing effect, the device makes when placing the mould, through spacing round hole, spacing through-hole and spacing round post's cooperation, make the mould clamp plate can fix in higher position, avoid influencing the placing of mould, and after the mould is placed, can be convenient remove fixedly, thereby the whereabouts carries out spacingly to the mould surface.

3. The die pressing plate moves up and down, the round rod moves up and down in the round sleeve at the same time, so that the die pressing plate can only move up and down, left and right shaking cannot occur, meanwhile, the limiting slide plate slides up and down in the first rectangular slide groove, when the die pressing plate is not limited, the limiting slide plate falls to the bottom end of the first rectangular slide groove at most, the round rod cannot separate from the round sleeve, the falling distance of the die pressing plate is too large, the round rod cannot be automatically inserted into the round sleeve when the die pressing plate moves up, the die pressing plate cannot smoothly move up, the die pressing plate can be moved well along the up and down direction, left and right offset cannot occur, the limiting effect on the die is poor, the limiting slide plate is matched with the first rectangular slide groove, the die pressing plate cannot fall by too large distance, the limiting spring cannot be deformed irreversibly, and the die pressing plate cannot move up.

4. When the steel sample falling from the die falls into the steel sample falling and collecting box, when the steel sample needs to be taken out, the two limiting square plates are rotated firstly, the limiting square plates are turned into the horizontal direction from the vertical direction, then the square pulling plate is pulled to drive the rectangular sliding strip to move outwards, so that the steel sample falling and collecting box is pulled out from the device, at the moment, the steel sample can be taken out from the outer side of the device, the steel sample falling and collecting box is put back into the device, the steel sample falling and collecting box is pushed into the device through the matching of the rectangular sliding strip and the second rectangular sliding groove, the two limiting square plates are positioned on the front side of the square pulling plate, then the limiting square plates are turned into the vertical direction from the horizontal direction, and because the limiting threaded columns are sleeved with the threaded holes, the limiting square plates can move towards the square pulling plate in the rotating process, and are tightly attached to the square pulling plate, and then the steel sample falling and collecting box is fixed by matching with the front surface of the placing bottom plate.

Drawings

The foregoing description is only an overview of the present application, and is intended to provide a better understanding of the present application, as it is embodied in the following description, with reference to the preferred embodiments of the present application and the accompanying drawings.

FIG. 1 is an overall block diagram of the present application;

FIG. 2 is a block diagram of a stationary platen of the present application;

FIG. 3 is a block diagram of a mold placement base of the present application;

FIG. 4 is a block diagram of a mold platen according to the present application;

FIG. 5 is a block diagram of a stop spring of the present application;

FIG. 6 is a block diagram of the steel sample fall-off collecting box according to the present application.

Legend description: 1. a stripper frame; 2. placing a base on the mould; 3. a steel sample falling-off collecting box; 4. fixing the placement plate; 5. a sample drop tank; 6. cam movable groove; 7. a rotary drive motor; 8. rotating the traction shaft; 9. rotating the cam; 10. a die placement groove; 11. a sample drop hole; 12. a traction sheave; 13. a limit vertical rod; 14. limiting round grooves; 15. a mold pressing plate; 16. a limit spring; 17. limiting through holes; 18. limiting the round column; 19. limiting round holes; 20. a circular sleeve; 21. a circular rod; 22. a first rectangular chute; 23. a limit sliding plate; 24. placing a bottom plate; 25. a rectangular slide bar; 26. the second rectangular chute; 27. square pulling plate; 28. square movable hole; 29. a threaded hole; 30. limiting a threaded column; 31. and a limit square plate.

Detailed Description

The embodiment of the application effectively solves the technical problem that a small steel sample is difficult to demould by providing the full-automatic steel sample demould machine.

Examples

As shown in fig. 1 to 6, the technical scheme in the embodiment of the application is to effectively solve the technical problem that a small steel sample is not easy to demould, and the overall thought is as follows:

aiming at the problems existing in the prior art, the application provides a full-automatic steel sample stripper, which comprises a stripper frame 1, wherein the rear inner wall of the stripper frame 1 is fixedly connected with a fixed placement plate 4, the middle part of the upper surface of the fixed placement plate 4 is separately provided with a sample falling groove 5, the front surface and the rear surface of the fixed placement plate 4 are respectively provided with two cam movable grooves 6, the right inner wall of the stripper frame 1 is fixedly connected with two rotary driving motors 7, the output shaft of each rotary driving motor 7 is fixedly connected with a rotary traction shaft 8, the side surface of each rotary traction shaft 8 is fixedly connected with two rotary cams 9, the left end of each rotary traction shaft 8 is rotationally connected with the left inner wall of the stripper frame 1, the upper end of each rotary cam 9 is positioned in the inner part of a similar cam movable groove 6, the upper surface of the fixed placement plate 4 is movably contacted with a die placement base 2, traction pulleys 12 are fixedly connected to four corners of the lower surface of the die placement base 2, each traction pulley 12 is in contact with the side surface of a similar rotating cam 9, a die placement groove 10 is formed in the upper surface of the die placement base 2, a sample falling hole 11 is formed in the bottom surface of the die placement groove 10, the sample falling hole 11 is aligned with the sample falling groove 5, four limit springs 16 are fixedly connected to the inner top surface of the stripper frame 1, the lower ends of the four limit springs 16 are fixedly connected with the same die pressing plate 15, a die to be stripped is placed in the die placement groove 10 on the die placement base 2, then two rotating driving motors 7 are started, the two rotating driving motors 7 drive the rotating cams 9 to rotate through rotating traction shafts 8, the rotating cams 9 drive the die placement base 2 to vibrate up and down through being matched with the traction pulleys 12, thereby driving the mould to vibrate up and down, enabling the steel sample to fall off from the mould under the action of inertia and fall from the sample falling hole 11 and the sample falling groove 5, thereby achieving the demoulding effect;

each limit spring 16 is movably sleeved with a round sleeve 20 and a round rod 21, each round sleeve 20 is movably sleeved with a similar round rod 21, the upper end of each round sleeve 20 is fixedly connected with the inner top surface of the stripper frame 1, the lower end of each round rod 21 is fixedly connected with the upper surface of the die pressing plate 15, a first rectangular sliding groove 22 is formed in the side surface of each round sleeve 20, a limit sliding plate 23 is fixedly connected with the side surface of each round rod 21, each limit sliding plate 23 is movably clamped with the similar first rectangular sliding groove 22, in order to prevent the die from falling off from the die placing base 2 during vibration, the die pressing plate 15 can be pressed above the die, a certain limit effect is generated under the cooperation of the limit springs 16, the die pressing plate 15 can only move up and down due to the cooperation of the round sleeves 20 and the round rods 21, the first rectangular sliding grooves 22 and the limit sliding plates 23 can prevent the round rods 21 from falling off the round sleeves 20, and the die pressing plate 15 from being blocked when the falling down too far and moving up;

the upper surface of the fixed placement plate 4 is fixedly connected with two limiting vertical rods 13, the left end and the right end of the bottom surface of the die placement base 2 are respectively provided with a limiting circular groove 14, each limiting vertical rod 13 is movably sleeved with a similar limiting circular groove 14, the side surface of each limiting vertical rod 13 is respectively provided with a limiting through hole 17, the left surface and the right surface of the die pressing plate 15 are respectively provided with a limiting circular hole 19, each limiting through hole 17 is movably sleeved with a limiting circular column 18, when a die is placed, in order to prevent the die pressing plate 15 from interfering with the placement of the die, the die pressing plate 15 can be lifted firstly, and the limiting circular columns 18 are inserted into the limiting circular holes 19 through the limiting through holes 17, so that the die pressing plate 15 is fixed at a high position;

the inner bottom surface of the stripper frame 1 is fixedly connected with a placing bottom plate 24, the upper surface of the placing bottom plate 24 is movably contacted with a steel sample falling-off collecting box 3, the upper surface of the placing bottom plate 24 is provided with a second rectangular chute 26, the lower surface of the steel sample falling-off collecting box 3 is fixedly connected with a rectangular slide bar 25, the rectangular slide bar 25 is movably clamped with the second rectangular chute 26, the front surface of the rectangular slide bar 25 is fixedly connected with a square pulling plate 27, the front surface of the square pulling plate 27 is provided with two square movable holes 28, each square movable hole 28 is movably sleeved with a limit threaded column 30, the front end of each limit threaded column 30 is fixedly connected with a limit square plate 31, each limit square plate 31 is tightly contacted with the front surface of the square pulling plate 27, the front surface of the placing bottom plate 24 is provided with two threaded holes 29, each threaded hole 29 is in threaded sleeve joint with a similar limit threaded column 30, when the steel sample falling from the mould falls into the steel sample falling collecting box 3 and needs to be taken out, the two limit square plates 31 are rotated firstly, so that the limit square plates 31 are turned from the vertical direction to the horizontal direction, then the square pull plates 27 are pulled to drive the rectangular slide bars 25 to move outwards, so that the steel sample falling collecting box 3 is pulled out of the device, at the moment, the steel sample can be taken out from the outer side of the device, when the steel sample falling collecting box 3 is put back, the steel sample falling collecting box 3 is pushed into the device through the cooperation of the rectangular slide bars 25 and the second rectangular slide grooves 26, the two limit square plates 31 are positioned at the front side of the square pull plates 27, then the limit square plates 31 are rotated, so that the limit square plates 31 are turned from the horizontal direction to the vertical direction, and the limit square plates 31 can move towards the square pull plates 27 in the rotating process due to the fact that the limit threaded columns 30 are sleeved with the threaded holes 29, thereby clinging to the square pulling plate 27, and the square pulling plate 27 is limited by matching with the front surface of the placing bottom plate 24, so that the steel sample falling-off collecting box 3 is fixed.

Working principle:

the first step, the device is when using, the mould that will need the drawing of patterns is placed in mould standing groove 10 on the base 2 is placed to the mould, then start two rotation driving motor 7, two rotation driving motor 7 drive rotation cam 9 through rotating traction shaft 8 and rotate, rotation cam 9 is through cooperating with traction sheave 12, drive mould standing base 2 vibrations from top to bottom, thereby drive mould vibrations, make the iron and steel appearance drop from the mould through the effect of inertia, and drop from sample whereabouts hole 11 and sample whereabouts groove 5, drop from mould standing base 2 and mould standing base 2 take place the skew when vibrations in order to prevent the mould, accessible mould clamp plate 15 pressure is in the top of mould, produce certain spacing effect to the mould under the cooperation of spacing spring 16, simultaneously two spacing montants 13 and spacing circular groove 14 cooperate can prevent that mould standing base 2 from taking place the skew, when placing the mould, in order to prevent that mould clamp plate 15 from interfering with the placing of mould, can lift mould clamp plate 15 earlier, and insert spacing circular post 18 in spacing circular hole 19 through spacing through 17, make mould clamp plate 15 fix in mould falling hole 11 and sample standing base 2 take place in the mould standing base 2 when vibrations, the mould is in order to prevent that mould standing base 2 from taking place the skew in the mould, can not to take place the cooperation with mould through rotation shaft 8, simultaneously, can be pressed in order to prevent mould standing base 2 through rotation clamp plate 15, can be in order to prevent the cooperation of mould standing base 2 from rotating die running base 2, and die running plate 2 can be in order to prevent the mould standing die 2.

Secondly, when the steel sample falling from the die falls into the steel sample falling collecting box 3 and needs to be taken out, the two limiting square plates 31 are rotated firstly, so that the limiting square plates 31 are turned from the vertical direction to the horizontal direction, then the square pull plates 27 are pulled to drive the rectangular slide bars 25 to move outwards, so that the steel sample falling collecting box 3 is pulled out of the device, at the moment, the steel sample can be taken out from the outer side of the device, when the steel sample falling collecting box 3 is put back, the steel sample falling collecting box 3 is pushed into the device through the cooperation of the rectangular slide bars 25 and the second rectangular slide grooves 26, the two limiting square plates 31 are positioned on the front side of the square pull plates 27, then the limiting square plates 31 are rotated, so that the limiting square plates 31 are turned from the horizontal direction to the vertical direction, and because the limiting threaded columns 30 are in threaded sleeve connection with the threaded holes 29, the limiting square plates 31 can move towards the square pull plates 27 in the rotating process, so as to cling to the square pull plates 27, the square pull plates 27 are in a limit mode through the cooperation with the front surfaces of the placing bottom plates 24, and the steel sample falling collecting box 3 is fixed.

Finally, it should be noted that: it is apparent that the above examples are only illustrative of the present application and are not limiting of the embodiments. Other variations or modifications of the above teachings will be apparent to those of ordinary skill in the art. It is not necessary here nor is it exhaustive of all embodiments. And obvious variations or modifications thereof are contemplated as falling within the scope of the present application.

Claims (10)

1. The full-automatic steel sample stripper comprises a stripper frame (1), and is characterized in that a fixed placement plate (4) is fixedly connected to the rear inner wall of the stripper frame (1), sample falling grooves (5) are formed in the middle of the upper surface of the fixed placement plate (4), two cam movable grooves (6) are formed in the front surface and the rear surface of the fixed placement plate (4), two rotary driving motors (7) are fixedly connected to the right inner wall of the stripper frame (1), rotary traction shafts (8) are fixedly connected to the output shafts of the rotary driving motors (7), two rotary cams (9) are fixedly connected to the side surfaces of the rotary traction shafts (8), and the left end of each rotary traction shaft (8) is rotatably connected with the left inner wall of the stripper frame (1);

the upper end of each rotating cam (9) is located inside a similar cam movable groove (6), a die placing base (2) is movably contacted with the upper surface of a fixed placing plate (4), traction pulleys (12) are fixedly connected to four corners of the lower surface of the die placing base (2), each traction pulley (12) is in contact with the side surface of the similar rotating cam (9), a die placing groove (10) is formed in the upper surface of the die placing base (2), a sample falling hole (11) is formed in the bottom surface of the die placing groove (10), the sample falling hole (11) is aligned with the sample falling groove (5), four limit springs (16) are fixedly connected to the inner top surface of the stripper frame (1), and the lower ends of the four limit springs (16) are fixedly connected with the same die pressing plate (15).

2. The full-automatic steel sample stripper as defined in claim 1, wherein each of said spacing springs (16) is movably sleeved with a circular sleeve (20) and a circular rod (21);

wherein each circular sleeve (20) is movably sleeved with a similar circular rod (21).

3. The full-automatic steel-like stripper as defined in claim 2, wherein the upper end of each of said circular sleeves (20) is fixedly connected to the inner top surface of the stripper frame (1);

the lower end of each circular rod (21) is fixedly connected with the upper surface of the die pressing plate (15).

4. A fully automatic steel sample stripper as defined in claim 3, wherein a first rectangular chute (22) is formed on the side surface of each circular sleeve (20), and a limit slide plate (23) is fixedly connected to the side surface of each circular rod (21);

each limiting slide plate (23) is movably clamped with a similar first rectangular slide groove (22).

5. The full-automatic steel sample stripper as defined in claim 4, wherein the upper surface of the fixed placement plate (4) is fixedly connected with two limit vertical rods (13), and limit circular grooves (14) are formed in the left and right ends of the bottom surface of the die placement base (2);

wherein each limit vertical rod (13) is movably sleeved with a similar limit round groove (14).

6. The full-automatic steel sample stripper as defined in claim 5, wherein a limiting through hole (17) is formed in a side surface of each limiting vertical rod (13), and limiting round holes (19) are formed in left and right surfaces of the die pressing plate (15);

wherein, each spacing through hole (17) all movably sleeve a spacing circular column (18).

7. The full-automatic steel sample stripper as defined in claim 6, wherein the inner bottom surface of the stripper frame (1) is fixedly connected with a placement base plate (24);

wherein, the upper surface of the placing bottom plate (24) is movably contacted with a steel sample falling-off collecting box (3).

8. The full-automatic steel sample stripper as defined in claim 7, wherein a second rectangular chute (26) is formed on the upper surface of the placement bottom plate (24), and a rectangular slide bar (25) is fixedly connected to the lower surface of the steel sample falling-off collection box (3);

the rectangular sliding strip (25) is movably clamped with the second rectangular sliding groove (26).

9. The full-automatic steel sample stripper as defined in claim 8, wherein the front surface of the rectangular slide bar (25) is fixedly connected with a square pulling plate (27), and two square movable holes (28) are formed in the front surface of the square pulling plate (27);

wherein, every spacing screw thread post (30) has all been cup jointed in the activity of square movable hole (28), every the front end of spacing screw thread post (30) all fixedly connected with spacing square plate (31), every spacing square plate (31) all with the front surface in close contact with of square arm-tie (27).

10. The fully automatic steel sample stripper as defined in claim 9, wherein the front surface of the placement base plate (24) is provided with two threaded holes (29);

each threaded hole (29) is in threaded sleeve connection with a similar limit threaded column (30).