CN215845568U - Automatic change rotation system shell machine - Google Patents

Abstract

The utility model discloses an automatic rotary shell making machine which comprises a damping base, wherein four corners of the bottom of the damping base are respectively provided with a fixed groove, top wall bodies of inner cavities of the four fixed grooves are respectively and fixedly connected with a fourth connecting block, bottom wall bodies of the four fourth connecting blocks are respectively and fixedly connected with telescopic support columns, bottom wall bodies of the four telescopic support columns are respectively and fixedly connected with a fifth connecting block, the outsides of the four telescopic support columns are respectively sleeved with a third damping spring, bottom wall bodies of the four fifth connecting blocks are respectively and fixedly connected with a fixed base, the lower ends of the four fixed bases are respectively and movably connected with idler wheels through rivets, and the top of the damping base is provided with a damping groove. This automatic change rotation system shell machine can make things convenient for the device's removal through the swing joint of the fixing base that sets up and gyro wheel, through the spacing compression piece that sets up, slide bar, the mutually supporting of second damping spring, can cushion the vertical vibrations that the device during operation produced.

Description

Automatic change rotation system shell machine

Technical Field

The utility model relates to the field of production and manufacturing, in particular to an automatic rotary shell making machine.

Background

In the precision casting trade, the system shell is from mould shell car or drying line take off the module, is stained with the thick liquid at first in being stained with the thick liquid built-in, waits to drench sand machine after thick liquid scribbles to hang evenly and hangs husky, after hanging husky operation, puts back the module dolly or drying line again and carries out the drying, so in automatic system shell operation, need divide into five processes according to the order: the method is characterized in that a workpiece manufacturing cycle is completed after five processes, namely a shell hanging process, a slurry dipping process, a slurry dripping process, a sand spraying process and a shell taking process, are finished, and the defects that an automatic rotary shell manufacturing machine used in the shell manufacturing operation is inconvenient to move, poor in anti-vibration effect and the like are overcome.

SUMMERY OF THE UTILITY MODEL

The utility model mainly aims to provide an automatic rotary shell making machine which can effectively solve the problems in the background technology.

In order to achieve the purpose, the utility model adopts the technical scheme that:

an automatic rotary shell making machine comprises a damping base, four corners of the bottom of the damping base are respectively provided with a fixed groove, top wall bodies of inner cavities of the four fixed grooves are respectively and fixedly connected with a fourth connecting block, bottom wall bodies of the four fourth connecting blocks are respectively and fixedly connected with a telescopic supporting column, bottom wall bodies of the four telescopic supporting columns are respectively and fixedly connected with a fifth connecting block, the outsides of the four telescopic supporting columns are respectively sleeved with a third damping spring, bottom wall bodies of the four fifth connecting blocks are respectively and fixedly connected with a fixed seat, the lower ends of the four fixed seats are respectively and movably connected with a roller through rivets, the top of the damping base is provided with a damping groove, four corners of the bottom of an inner cavity of the damping groove are respectively and fixedly connected with second movable connecting seats, the upper ends of the four second movable connecting seats are respectively and movably connected with a first movable rod through rivets, the other ends of the four first movable rods are respectively and movably connected with third movable connecting seats through rivets, the other side wall bodies of the four third movable connecting seats are respectively and fixedly connected with first connecting blocks, the opposite side wall bodies of the four first connecting blocks are respectively and fixedly connected with first damping springs, the upper ends of the inner cavities of the damping grooves are movably connected with a telescopic base, the top wall body of the telescopic base is fixedly connected with a rotary shell making machine device body, the four corners of the bottom of the telescopic base are respectively and fixedly connected with the first movable connecting seats, the lower ends of the four first movable connecting seats are respectively and movably connected with second movable rods through rivets, the side wall of the inner cavity of the damping groove is provided with a compression groove, the inner wall of the compression groove is fixedly connected with a slide rod, the outer part of the slide rod is movably sleeved with a second damping spring, and the four corners of the top of the damping base are respectively and fixedly connected with second connecting blocks, four the top wall body of second connecting block is fixedly connected with buffer spring respectively, four buffer spring's top is fixedly connected with third connecting block respectively, four the top wall body of third connecting block is fixedly connected with buffering kicking block respectively, the spacing compression piece of lateral wall fixedly connected with of flexible base.

Preferably, the lower end of the second movable rod is movably connected with the third movable connecting seat through a rivet.

Preferably, the number of the limiting compression blocks is four, the four limiting compression blocks are respectively and fixedly connected to the front end and the rear end of the left side wall and the right side wall of the telescopic base, and the other ends of the limiting compression blocks are movably sleeved outside the upper end of the sliding rod.

Preferably, the number of the compression grooves is four, and the four compression grooves are respectively arranged at the front end and the rear end of the left side wall and the right side wall of the inner cavity of the damping groove.

Preferably, the number of the sliding rods is four, and the four sliding rods are vertically and fixedly connected to the inner walls of the four compression grooves respectively.

Preferably, the number of the second damping springs is four, and the four second damping springs are movably sleeved outside the lower ends of the four sliding rods respectively.

Compared with the prior art, the utility model has the following beneficial effects:

the automatic rotary shell making machine can facilitate the movement of the device through the movable connection of the arranged fixed seat and the idler wheel, the fixed groove is formed, the fourth connecting block, the third damping spring, the telescopic supporting column and the fifth connecting block are matched with each other to buffer the vibration generated by jolting in the moving process of the device, so that the fixed seat and the idler wheel are prevented from being damaged by vibration, the transverse vibration generated when the device works and operates can be buffered through the mutual matching of the arranged first movable connecting seat, the second movable connecting seat, the first movable rod, the second movable rod, the first connecting block, the third movable connecting seat and the first damping spring, the vertical vibration generated when the device works and operates can be buffered through the mutual matching of the arranged limiting compression block, the sliding rod and the second damping spring, the vertical vibration generated when the device works and operates can be buffered through the arranged second connecting block, the buffering top block, The third connecting block and the buffer spring are matched with each other, so that the rotary shell making machine body can be protected in a buffering mode, and the rotary shell making machine body is prevented from being damaged due to the fact that the bottom of the rotary shell making machine body collides with the top of the damping base.

Drawings

FIG. 1 is a schematic cross-sectional view of a vibration damping mount according to the present invention;

FIG. 2 is an enlarged view taken at A of FIG. 1 in accordance with the present invention;

FIG. 3 is an enlarged view of the soil 1 of the present invention at B;

fig. 4 is a perspective view of the joint of the first connecting block and the third movable connecting seat of the present invention.

In the figure: 1. a first damping spring; 2. a rotary shell making machine device body; 3. a telescopic base; 4. a first movable connecting seat; 5. a damping groove; 6. a second movable connecting seat; 7. a damping mount; 8. a fixed seat; 9. a roller; 10. a first connection block; 11. a third movable connecting seat; 12. a first movable bar; 13. a second damping spring; 14. a slide bar; 15. a second connecting block; 16. buffering the top block; 17. a third connecting block; 18. a buffer spring; 19. a compression groove; 20. a limiting compression block; 21. fixing grooves; 22. a fourth connecting block; 23. a third damping spring; 24. a telescopic support column; 25. a fifth connecting block; 26. a second movable bar.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the utility model easy to understand, the utility model is further described with the specific embodiments.

As shown in fig. 1-4, an automatic rotary shell making machine comprises a damping base 7, four corners of the bottom of the damping base 7 are respectively provided with a fixing groove 21, top wall bodies of inner cavities of the four fixing grooves 21 are respectively and fixedly connected with a fourth connecting block 22, bottom wall bodies of the four fourth connecting blocks 22 are respectively and fixedly connected with a telescopic supporting column 24, bottom wall bodies of the four telescopic supporting columns 24 are respectively and fixedly connected with a fifth connecting block 25, the outer parts of the four telescopic supporting columns 24 are respectively sleeved with a third damping spring 23, bottom wall bodies of the four fifth connecting blocks 25 are respectively and fixedly connected with a fixing base 8, and vibrations generated by jolts in the moving process of the device can be buffered through the mutual matching of the fixing grooves 21, the fourth connecting blocks 22, the third damping springs 23, the telescopic supporting columns 24 and the fifth connecting blocks 25, so that the fixing base 8 and the roller 9 are prevented from being damaged by vibrations, the lower ends of the four fixed seats 8 are respectively movably connected with a roller 9 through rivets, the movement of the device can be facilitated through the movable connection of the arranged fixed seats 8 and the rollers 9, the top of a shock absorption base 7 is provided with a shock absorption groove 5, the four corners of the bottom of the inner cavity of the shock absorption groove 5 are respectively and fixedly connected with second movable connecting seats 6, the upper ends of the four second movable connecting seats 6 are respectively and movably connected with first movable rods 12 through rivets, the other ends of the four first movable rods 12 are respectively and movably connected with third movable connecting seats 11 through rivets, the other side wall bodies of the four third movable connecting seats 11 are respectively and fixedly connected with first connecting blocks 10, one side wall bodies of the four first connecting blocks 10 opposite to each other are fixedly connected with first shock absorption springs 1, the upper ends of the inner cavity of the shock absorption groove 5 are movably connected with a telescopic base 3, and the top wall body of the telescopic base 3 is fixedly connected with a rotary shell making machine body 2, four corners of the bottom of the telescopic base 3 are respectively fixedly connected with first movable connecting seats 4, the lower ends of the four first movable connecting seats 4 are respectively movably connected with second movable rods 26 through rivets, the lower ends of the second movable rods 26 are movably connected with a third movable connecting seat 11 through rivets, transverse vibration generated when the device works and operates can be buffered through the mutual matching of the arranged first movable connecting seats 4, the second movable connecting seats 6, the first movable rods 12, the second movable rods 26, the first connecting blocks 10, the third movable connecting seats 11 and the first damping springs 1, the number of the compression grooves 19 is four, the number of the compression grooves 19 is arranged on the side wall of the inner cavity of the damping groove 5, the four compression grooves 19 are respectively arranged at the front end and the rear end of the left side wall and the right side wall of the inner cavity of the damping groove 5, the inner walls of the compression grooves 19 are fixedly connected with four sliding rods 14, the number of the four sliding rods 14 are respectively vertically and fixedly connected with the inner walls of the four compression grooves 19, the outer part of the sliding rod 14 is movably sleeved with four second damping springs 13, the four second damping springs 13 are respectively movably sleeved outside the lower ends of the four sliding rods 14, vertical vibration generated during the working and running of the device can be buffered through the mutual matching of the arranged limiting compression blocks 20, the sliding rods 14 and the second damping springs 13, four corners of the top of the damping base 7 are respectively and fixedly connected with second connecting blocks 15, top wall bodies of the four second connecting blocks 15 are respectively and fixedly connected with buffer springs 18, the tops of the four buffer springs 18 are respectively and fixedly connected with third connecting blocks 17, top wall bodies of the four third connecting blocks 17 are respectively and fixedly connected with buffer jacking blocks 16, and the buffer protection effect on the rotary shell making machine body 2 can be achieved through the mutual matching of the arranged second connecting blocks 15, the buffer jacking blocks 16, the third connecting blocks 17 and the buffer springs 18, in order to prevent the bottom of the rotary shell making machine device body 2 from colliding with the top of the damping base 7 to cause damage, the side walls of the telescopic base 3 are fixedly connected with four limiting compression blocks 20, the four limiting compression blocks 20 are fixedly connected to the front end and the rear end of the left side wall and the rear end of the right side wall of the telescopic base 3 respectively, and the other ends of the limiting compression blocks 20 are movably sleeved on the outer portion of the upper end of the sliding rod 14.

It should be noted that, the present invention is an automatic rotary shell making machine, when in use, the fixed seat 8 and the roller 9 are arranged to facilitate the movement of the rotary shell making machine device body 2, the vibration generated during the movement of the rotary shell making machine device can be buffered under the mutual cooperation of the fixed groove 21, the fourth connecting block 22, the third damping spring 23, the telescopic support column 24 and the fifth connecting block 25, so as to avoid the damage of the vibration to the fixed seat 8 and the roller 9, specifically, the fourth connecting block 22 and the fifth connecting block 25 extrude the third damping spring 23, the third damping spring 23 generates a longitudinal acting force to achieve the effect of buffering and damping, the transverse vibration generated during the operation of the rotary shell making machine device body 2 can be buffered under the mutual cooperation of the first movable connecting seat 4, the second movable connecting seat 6, the first damping spring 1, the second movable rod 26, the first connecting block 10, the third movable connecting seat 11 and the first movable rod 12, concretely, the first movable connecting seat 4 and the second movable connecting seat 6 drive the first movable rod 12 and the second movable rod 26 to extrude the third movable connecting seat 11, the third movable connecting seat 11 drives the first connecting block 10 to extrude the first damping spring 1, the first damping spring 1 generates a transverse acting force, and an effect of buffering transverse vibration is achieved, the vertical vibration generated by the rotary shell making machine can be buffered under the mutual matching of the rotary shell making machine body 2, the second damping spring 13 and the sliding rod 14, specifically, the limiting compression block 20 extrudes the second damping spring 13, the second damping spring 13 generates a longitudinal acting force, and an effect of buffering longitudinal vibration is achieved, and the effects of buffering and protecting the rotary shell making machine body 2 can be achieved under the mutual matching of the second connecting block 15, the buffering top block 16, the third connecting block 17 and the damping spring 18, so that the bottom of the rotary shell making machine body 2 is prevented from colliding with the top of the damping base 7 and the rotary shell making machine is prevented from impacting with the top of the rotary shell making machine body 7 The device body 2 is damaged, specifically, the buffer ejecting block 16 drives the third connecting block 17 to extrude the buffer spring 18, and the buffer spring 18 generates a longitudinal acting force, so that the buffer protection effect for the rotary shell making machine device body 2 is achieved.

The foregoing shows and describes the general principles and broad features of the present invention and advantages thereof. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides an automatic change rotation system shell machine, includes vibration damping mount (7), its characterized in that: fixing grooves (21) are respectively formed in four corners of the bottom of the damping base (7), four top wall bodies of inner cavities of the fixing grooves (21) are respectively and fixedly connected with a fourth connecting block (22), four bottom wall bodies of the fourth connecting block (22) are respectively and fixedly connected with a telescopic supporting column (24), four bottom wall bodies of the telescopic supporting columns (24) are respectively and fixedly connected with a fifth connecting block (25), a third damping spring (23) is respectively sleeved outside the four telescopic supporting columns (24), the bottom wall bodies of the four fifth connecting blocks (25) are respectively and fixedly connected with fixing seats (8), the lower ends of the four fixing seats (8) are respectively and movably connected with rollers (9) through rivets, a damping groove (5) is formed in the top of the damping base (7), and the four corners of the bottom of the inner cavity of the damping groove (5) are respectively and fixedly connected with second movable connecting seats (6), the upper ends of the four second movable connecting seats (6) are respectively and movably connected with first movable rods (12) through rivets, the other ends of the four first movable rods (12) are respectively and movably connected with third movable connecting seats (11) through rivets, the other side wall bodies of the four third movable connecting seats (11) are respectively and fixedly connected with first connecting blocks (10), the opposite side wall bodies of the four first connecting blocks (10) are respectively and fixedly connected with first damping springs (1), the upper end of the inner cavity of the damping groove (5) is movably connected with a telescopic base (3), the top wall body of the telescopic base (3) is fixedly connected with a shell making machine device body (2), the four corners of the bottom of the telescopic base (3) are respectively and fixedly connected with first movable connecting seats (4), and the lower ends of the four first movable connecting seats (4) are respectively and movably connected with second movable rods (26) through rivets, compression groove (19) have been seted up to the lateral wall of shock attenuation groove (5) inner chamber, the inner wall fixedly connected with slide bar (14) of compression groove (19), the outside movable sleeve of slide bar (14) is equipped with second damping spring (13), the top four corners difference fixedly connected with second connecting block (15) of vibration damping mount (7), four the top wall body difference fixedly connected with buffer spring (18), four of second connecting block (15) the top difference fixedly connected with third connecting block (17), four of buffer spring (18) the top wall body difference fixedly connected with buffering kicking block (16) of third connecting block (17), the spacing compression piece (20) of lateral wall fixedly connected with of expansion base (3).

2. An automated rotary shell making machine according to claim 1, wherein: the lower end of the second movable rod (26) is movably connected with the third movable connecting seat (11) through a rivet.

3. An automated rotary shell making machine according to claim 1, wherein: the number of the limiting compression blocks (20) is four, the four limiting compression blocks (20) are respectively and fixedly connected to the front end and the rear end of the left side wall and the right side wall of the telescopic base (3), and the other ends of the limiting compression blocks (20) are movably sleeved on the outer portion of the upper end of the sliding rod (14).

4. An automated rotary shell making machine according to claim 1, wherein: the number of the compression grooves (19) is four, and the four compression grooves (19) are respectively arranged at the front end and the rear end of the left side wall and the right side wall of the inner cavity of the damping groove (5).

5. An automated rotary shell making machine according to claim 1, wherein: the number of the sliding rods (14) is four, and the four sliding rods (14) are respectively and vertically and fixedly connected to the inner walls of the four compression grooves (19).

6. An automated rotary shell making machine according to claim 1, wherein: the number of the second damping springs (13) is four, and the four second damping springs (13) are respectively movably sleeved outside the lower ends of the four sliding rods (14).

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