CN116851672A - Quick-connection type water-cooling crystallizer vibrating device - Google Patents

Abstract

The invention discloses a quick-connection type water-cooling crystallizer vibrating device which comprises a crystallizer vibrating unit, a base and a foundation frame unit, wherein the crystallizer vibrating unit is arranged on the base, the base is arranged on the foundation frame unit, and the foundation frame unit is arranged on a concrete foundation; the base frame unit includes: an outer arc support beam, a left Lian Jieliang, an inner arc support beam, and a right connecting beam; the outer arc support beam comprises a left cooling cavity and a right cooling cavity, the left cooling cavity is provided with a basic frame water inlet, the right cooling cavity is provided with a basic frame water outlet, and the left cooling cavity, the left connecting beam, the inner arc support beam, the right connecting beam and the right cooling cavity are sequentially communicated; the outer arc supporting beam is provided with a crystallizer water inlet assembly and a crystallizer water outlet assembly, and the water inlet end of the crystallizer vibrating unit is detachably connected with the crystallizer water outlet assembly. The base frame unit of the present invention is provided with a cooling structure.

Description

Quick-connection type water-cooling crystallizer vibrating device

Technical Field

The invention belongs to the technical field of crystallization equipment, and particularly relates to a quick-connection type water-cooling crystallizer vibrating device.

Background

In the prior art, a foundation slab of a crystallizer vibrating device is fixed on a concrete foundation through foundation bolts, a base is fixed on the foundation slab through bolts, and a crystallizer vibrating unit is fixed on the base through bolts. The concrete foundation is arranged among the outer arc, the inner arc and the flow and used for supporting the foundation slab, works in a high-temperature and humid environment, is extremely easy to damage, adopts a protective cover to protect in order to prolong the service life of the concrete foundation, and has limited effect, and the damage of the concrete foundation directly leads to the vibration precision of the crystallizer vibration unit. The crystallizer cooling water workshop pipeline is connected with a crystallizer cooling water interface on the base through a flange, and a cooling water connecting flange needs to be removed and installed when the base is removed and installed, so that the time consumption is long.

The present invention has been made in view of this.

Disclosure of Invention

The invention aims to solve the technical problems of overcoming the defects of the prior art and providing the quick-connection type water-cooling crystallizer vibrating device, wherein a cooling structure is arranged in a base frame unit, so that a concrete foundation between flows is canceled, the concrete foundation is prevented from being damaged due to heating and humidity, and the stability of the foundation of the crystallizer vibrating unit is ensured.

In order to solve the technical problems, the invention adopts the basic conception of the technical scheme that:

the quick-connection type water-cooling crystallizer vibrating device comprises a crystallizer vibrating unit, a base and a foundation frame unit, wherein the crystallizer vibrating unit is arranged on the base, the base is arranged on the foundation frame unit, and the foundation frame unit is arranged on a concrete foundation;

the base frame unit includes: an outer arc support beam, a left Lian Jieliang, an inner arc support beam, and a right connecting beam;

the outer arc support beam comprises a left cooling cavity and a right cooling cavity, the left cooling cavity is provided with a basic frame water inlet, the right cooling cavity is provided with a basic frame water outlet, and the left cooling cavity, the left connecting beam, the inner arc support beam, the right connecting beam and the right cooling cavity are sequentially communicated;

the outer arc supporting beam is provided with a crystallizer water inlet assembly and a crystallizer water outlet assembly, and the water inlet end of the crystallizer vibrating unit is detachably connected with the crystallizer water outlet assembly.

Furthermore, the outer arc supporting beam is provided with a crystallizer water inlet through hole and a crystallizer water outlet through hole, and the crystallizer water inlet assembly is communicated with the crystallizer water outlet assembly through the crystallizer water inlet through hole, the crystallizer cooling water pipe and the crystallizer water outlet through hole in sequence.

Furthermore, the crystallizer water outlet assembly comprises an O-shaped sealing ring, a sealing disc and a U-shaped sealing ring which are arranged at the through hole of the crystallizer water outlet from inside to outside.

Further, the crystallizer water outlet assembly further comprises a gasket set, wherein the gasket set is positioned at the periphery of the crystallizer water outlet through hole, and the gasket set is arranged between the upper surface of the outer arc supporting beam and the lower surface of the sealing disc.

In some alternative embodiments, the crystallizer water inlet assembly comprises a crystallizer water inlet interface flange, one end of the crystallizer water inlet interface flange is communicated with the crystallizer water inlet through hole, and the other end of the crystallizer water inlet interface flange is used for being detachably connected with a crystallizer cooling water pipeline of a workshop.

In some alternative embodiments, the outer arc support beam upper surface is provided with an outer arc support plate provided with a band stop that mates with the base.

Further, the outer arc supporting plate is provided with a T-shaped groove, and the base is connected with the outer arc supporting plate through bolts installed in the T-shaped groove.

Further, the inner arc supporting beam upper surface is provided with the inner arc backup pad, the inner arc backup pad is provided with the T-shaped groove, the base is in through installing the bolt in the T-shaped groove with the inner arc backup pad is connected.

In some alternative embodiments, a left cooling cavity drain pipe of the left cooling cavity is communicated with a left connecting beam water inlet pipe of the left connecting beam through a cooling water connecting pipe;

the left connecting beam water discharge pipe of the left connecting beam is communicated with the inner arc support beam water inlet pipe of the inner arc support beam through a cooling water connecting pipe;

an inner arc support beam drain pipe of the inner arc support beam is communicated with a right connecting beam water inlet pipe of the right connecting beam through a cooling water connecting pipe;

the right connecting beam water discharging pipe of the right connecting beam is communicated with the right cooling cavity water inlet pipe of the right cooling cavity through a cooling water connecting pipe.

Further, the left connecting beam water inlet pipe is lower than the left connecting beam water outlet pipe in the height direction;

the inner arc support beam water inlet pipe is lower than the inner arc support beam water outlet pipe in the height direction;

the right connecting beam water inlet pipe is lower than the right connecting beam water outlet pipe in the height direction;

the water inlet of the foundation frame is lower than the left cooling cavity drain pipe in the height direction;

the right cooling cavity water inlet pipe is lower than the water outlet of the foundation frame in the height direction.

By adopting the technical scheme, compared with the prior art, the invention has the following beneficial effects.

According to the quick-connection type water-cooling crystallizer vibration device provided by the invention, the crystallizer vibration unit is arranged on the base, the base is arranged on the foundation frame unit, the foundation frame unit is arranged on the concrete foundation, and the cooling structure is arranged in the foundation frame unit, so that the concrete foundation among flows is eliminated, the damage of the concrete foundation caused by heating and wetting is avoided, and the stability of the foundation of the crystallizer vibration unit is ensured. Meanwhile, a water-cooling protective cover of the concrete foundation between the flows is not needed, and the equipment is simpler. And the quick disassembly of the crystallizer vibration unit and a crystallizer cooling water pipeline of a workshop can be realized.

The following describes the embodiments of the present invention in further detail with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention. It is evident that the drawings in the following description are only examples, from which other drawings can be obtained by a person skilled in the art without the inventive effort. In the drawings:

FIG. 1 is a schematic diagram of the whole structure of a vibration device of a quick-connection water-cooling crystallizer;

FIG. 2 is a schematic view of a base-and-frame unit according to the present invention;

FIG. 3 is a schematic view of another view of a base-and-frame unit according to the present invention;

fig. 4 is a schematic cross-sectional structure of a water outlet assembly of a crystallizer provided by the invention.

In the figure: 100. a crystallizer vibration unit; 200. a base; 300. a base frame unit;

1. an outer arc support beam; 11. a water outlet through hole of the crystallizer; 12. a crystallizer water inlet interface flange; 13. cooling water pipe of crystallizer; 14. a base frame water inlet; 15. a water outlet of the foundation frame; 16. a left cooling cavity drain pipe; 17. a right cooling cavity water inlet pipe; 18. a bolt; 19. an outer arc support plate;

2. a right connecting beam; 21. a right connecting beam water draining pipe; 22. a right connecting beam water inlet pipe;

3. an inner arc support beam; 31. an inner arc support plate; 32. an inner arc support beam water inlet pipe; 33. an inner arc support beam drain pipe;

4. a left connecting beam; 41. a left connecting beam water draining pipe; 42. a left connecting beam water inlet pipe;

5. a cooling water connection pipe; 6. a sealing plate; 7. a U-shaped sealing ring; 8. an O-ring seal; 9. a gasket set.

It should be noted that these drawings and the written description are not intended to limit the scope of the inventive concept in any way, but to illustrate the inventive concept to those skilled in the art by referring to the specific embodiments.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions in the embodiments will be clearly and completely described with reference to the accompanying drawings in the embodiments of the present invention, and the following embodiments are used to illustrate the present invention, but are not intended to limit the scope of the present invention.

In the description of the present invention, it should be noted that the directions or positional relationships indicated by the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

As shown in fig. 1 to 4, the quick-connection type water-cooling crystallizer vibration device provided by the invention comprises a crystallizer vibration unit 100, a base 200 and a base frame unit 300, wherein the crystallizer vibration unit 100 is arranged on the base 200, the base 200 is arranged on the base frame unit 300, and the base frame unit 300 is arranged on a concrete foundation;

the base frame unit 300 includes: an outer arc supporting beam 1, a left connecting beam 4, an inner arc supporting beam 3 and a right connecting beam 2;

the outer arc support beam 1 comprises a left cooling cavity and a right cooling cavity, the left cooling cavity is provided with a basic frame water inlet 14, the right cooling cavity is provided with a basic frame water outlet 15, and the left cooling cavity, the left connecting beam 4, the inner arc support beam 3, the right connecting beam 2 and the right cooling cavity are sequentially communicated;

the outer arc support beam 1 is provided with a crystallizer water inlet assembly and a crystallizer water outlet assembly, and the water inlet end of the crystallizer vibration unit 100 is detachably connected with the crystallizer water outlet assembly.

Specifically, the foundation frame unit 300 is installed on the concrete foundation, the base 200 is installed on the foundation frame unit 300, the crystallizer vibration unit 100 is installed on the base 200, the outer arc supporting beam 1, the left connecting beam 4, the inner arc supporting beam 3 and the right connecting beam 2 of the foundation frame unit 300 are hollow, and a cooling waterway is arranged in the foundation frame unit.

Wherein the outer arc supporting beam 1 comprises a left cooling cavity and a right cooling cavity, a base frame water inlet 14 is arranged on the side wall of the left cooling cavity, and a base frame water outlet 15 is arranged on the side wall of the right cooling cavity.

Cooling water enters the left cooling chamber through the base frame water inlet 14, then flows through the left connecting beam 4, the inner arc supporting beam 3, the right connecting beam 2, and enters the right cooling chamber in this order from the left cooling chamber, and finally exits the base frame unit 300 at the base frame water outlet 15 provided on the side wall of the right cooling chamber.

According to the quick-connection type water-cooling crystallizer vibration device provided by the invention, the crystallizer vibration unit 100 is arranged on the base 200, the base 200 is arranged on the base frame unit 300, the base frame unit 300 is arranged on the concrete foundation, and the cooling structure is arranged in the base frame unit 300, so that the concrete foundation among flows is eliminated, the damage of the concrete foundation caused by heating and humidity is avoided, and the stability of the foundation of the crystallizer vibration unit 100 is ensured. Meanwhile, a water-cooling protective cover of the concrete foundation between the flows is not needed, and the equipment is simpler.

The outer arc support beam 1 is also provided with a crystallizer water inlet assembly and a crystallizer water outlet assembly, and the water inlet end of the crystallizer vibration unit 100 is detachably connected with the crystallizer water outlet assembly.

The crystallizer cooling water pipeline of the workshop is communicated with a crystallizer water inlet assembly, the crystallizer water inlet assembly is communicated with a crystallizer water outlet assembly, and the water inlet end of the crystallizer vibration unit 100 is detachably connected with the crystallizer water outlet assembly. Quick removal of the mold vibration unit 100 from the mold cooling water line of the shop can be achieved.

Further, the outer arc supporting beam 1 is provided with a crystallizer water inlet through hole and a crystallizer water outlet through hole 11, and the crystallizer water inlet assembly is communicated with the crystallizer water outlet assembly sequentially through the crystallizer water inlet through hole, the crystallizer cooling water pipe 13 and the crystallizer water outlet through hole 11.

In order to achieve compact structure and small occupied space, a crystallizer water inlet through hole is formed in the side wall of the outer arc supporting beam 1, a crystallizer water outlet through hole 11 is formed in the upper top surface of the outer arc supporting beam 1, a crystallizer cooling water pipe 13 is arranged in the outer arc supporting beam 1, one end of the crystallizer cooling water pipe is communicated with the crystallizer water inlet through hole, the other end of the crystallizer cooling water pipe is communicated with the crystallizer water outlet through hole 11, a crystallizer water inlet assembly is communicated with the crystallizer water inlet through hole, and a crystallizer water outlet assembly is communicated with the crystallizer water outlet through hole 11.

The crystallizer cooling water pipeline of the workshop is communicated with the crystallizer water inlet assembly, and the water inlet end of the crystallizer vibration unit 100 is detachably connected with the crystallizer water outlet assembly. Thereby realizing the cooling water of the crystallizer cooling water pipeline of the workshop, and sequentially passing through the crystallizer water inlet assembly, the crystallizer water inlet through hole, the crystallizer cooling water pipe 13, the crystallizer water outlet through hole 11, the crystallizer water outlet assembly, the water inlet end of the crystallizer vibration unit 100 and the crystallizer vibration unit 100.

It should be noted that the base frame unit 300 may be provided with a plurality of mold vibration units 100, and the outer arc support beam 1 is provided with a plurality of mold water inlet assemblies and a plurality of mold water outlet assemblies.

The crystallizer water inlet assembly and the crystallizer water outlet assembly are a group of water inlet units, the outer arc supporting beam 1 can be provided with a plurality of groups of water inlet units, and each crystallizer vibration unit 100 is communicated with one group of water inlet units and is used for supplying cooling water to the crystallizer vibration units 100. The specific number can be set by the person skilled in the art according to the actual need.

Further, the crystallizer water inlet assembly comprises a crystallizer water inlet interface flange 12, one end of the crystallizer water inlet interface flange 12 is communicated with a crystallizer water inlet through hole, and the other end of the crystallizer water inlet interface flange is used for being detachably connected with a crystallizer cooling water pipeline of a workshop.

In some alternative embodiments, as shown in fig. 4, the invention provides a quick-connection type water-cooling crystallizer vibration device, and a crystallizer water outlet assembly of the quick-connection type water-cooling crystallizer vibration device comprises an O-shaped sealing ring 8, a sealing disc 6 and a U-shaped sealing ring 7 which are arranged at a crystallizer water outlet through hole 11 from inside to outside.

The O-shaped sealing ring 8 is used for sealing between the sealing disc 6 and the through hole 11 of the water outlet of the crystallizer, the U-shaped sealing ring 7 is arranged on the sealing disc 6, and the U-shaped sealing ring 7 is used for sealing between the sealing disc 6 and the water inlet end of the vibration unit 100 of the crystallizer.

The structure can realize the quick butt joint of the water inlet end of the crystallizer vibration unit 100 and the water outlet assembly of the crystallizer, can be detachably connected, and can realize the sealing effect.

Further, the crystallizer water outlet assembly further comprises a gasket set 9, wherein the gasket set 9 is positioned at the periphery of the crystallizer water outlet through hole 11, and the gasket set 9 is arranged between the upper surface of the outer arc supporting beam 1 and the lower surface of the sealing disc 6.

The spacer group 9 may be increased in height or decreased in height according to actual needs. Thereby adjusting the height of the sealing disk 6 to facilitate the butt joint of the water inlet end of the crystallizer vibration unit 100 and the water outlet assembly of the crystallizer.

As shown in fig. 1 to 4, in some alternative embodiments, the invention provides a quick-connection type water-cooling crystallizer vibration device, wherein an outer arc supporting plate 19 is arranged on the upper surface of an outer arc supporting beam 1 of the quick-connection type water-cooling crystallizer vibration device, and the outer arc supporting plate 19 is provided with a belt spigot which is matched with a base 200.

The band stop is used for positioning the base 200, realizing quick installation and limiting effect.

It should be noted that the number of the outer arc supporting plates 19 may be plural, and a specific number of the outer arc supporting plates may be set by one skilled in the art according to actual needs.

Further, the outer arc support plate 19 is provided with a T-shaped groove, and the base 200 is connected to the outer arc support plate 19 by bolts 18 installed in the T-shaped groove.

The bolt 18 is installed in the T-shaped groove, so that the bolt 18 can be screwed and fixed, the position of the bolt 18 can be adjusted, and the bolt 18 can move in the T-shaped groove and is convenient to install and connect with the base 200.

Further, the upper surface of the inner arc supporting beam 3 is provided with an inner arc supporting plate 31, the inner arc supporting plate 31 is provided with a T-shaped groove, and the base 200 is connected with the inner arc supporting plate 31 through bolts 18 installed in the T-shaped groove.

The bolt 18 is installed in the T-shaped groove, so that the bolt 18 can be screwed and fixed, the position of the bolt 18 can be adjusted, and the bolt 18 can move in the T-shaped groove and is convenient to install and connect with the base 200.

It should be noted that the number of the inner arc supporting plates 31 may be plural, and a specific number of the inner arc supporting plates can be set by one skilled in the art according to actual needs.

As shown in fig. 1 to 4, in some alternative embodiments, the present invention provides a quick-connection type water-cooled crystallizer vibration device, wherein a left cooling cavity drain pipe 16 of a left cooling cavity of the quick-connection type water-cooled crystallizer vibration device is communicated with a left connecting beam water inlet pipe 42 of a left connecting beam 4 through a cooling water connecting pipe 5;

the left connecting beam water discharge pipe 41 of the left connecting beam 4 is communicated with the inner arc support beam water inlet pipe 32 of the inner arc support beam 3 through the cooling water connecting pipe 5;

an inner arc support beam drain pipe 33 of the inner arc support beam 3 is communicated with the right connecting beam water inlet pipe 22 of the right connecting beam 2 through a cooling water connecting pipe 5;

the right connecting beam water discharging pipe 21 of the right connecting beam 2 is communicated with the right cooling cavity water inlet pipe 17 of the right cooling cavity through the cooling water connecting pipe 5;

specifically, the left cooling chamber is cooled by entering the left cooling chamber through the base frame water inlet 14.

The cooling water in the left cooling cavity sequentially passes through the left cooling cavity drain pipe 16 of the left cooling cavity, the cooling water connecting pipe 5 and the left connecting beam water inlet pipe 42 of the left connecting beam 4 to enter the left connecting beam 4 so as to cool the left connecting beam 4.

The cooling water in the left connecting beam 4 sequentially passes through the left connecting beam water discharging pipe 41 of the left connecting beam 4, the cooling water connecting pipe 5 and the inner arc supporting beam water inlet pipe 32 of the inner arc supporting beam 3 to enter the inner arc supporting beam 3 so as to cool the inner arc supporting beam 3.

The cooling water in the inner arc support beam 3 sequentially passes through the inner arc support beam drain pipe 33 of the inner arc support beam 3, the cooling water connecting pipe 5 and the right connecting beam water inlet pipe 22 of the right connecting beam 2 to enter the right connecting beam 2 so as to cool the right connecting beam 2.

The cooling water in the right connecting beam 2 sequentially passes through the right connecting beam water discharging pipe 21 of the right connecting beam 2, the cooling water connecting pipe 5 and the right cooling cavity water inlet pipe 17 of the right cooling cavity to enter the right cooling cavity so as to cool the right cooling cavity.

Finally, the cooling water of the right cooling chamber is discharged out of the base frame unit 300 through the base frame water outlet 15 provided on the side wall of the right cooling chamber.

Cooling of the base-and-frame unit 300 is achieved. The cooling structure is provided in the base frame unit 300, the concrete foundation between the flows is eliminated, damage of the concrete foundation due to heat and humidity is avoided, and the stability of the foundation of the mold vibration unit 100 is ensured. Meanwhile, a water-cooling protective cover of the concrete foundation between the flows is not needed, and the equipment is simpler.

Further, the left connecting beam water inlet pipe 42 is lower than the left connecting beam water discharge pipe 41 in the height direction. The inner arc support beam water inlet pipe 32 is lower in the height direction than the inner arc support beam water outlet pipe 33. The right connecting beam water inlet pipe 22 is lower than the right connecting beam water outlet pipe 21 in the height direction. The base frame water inlet 14 is lower in height than the left cooling chamber drain 16. The right cooling chamber inlet pipe 17 is lower in height than the base frame outlet 15.

With the above arrangement, the cooling water can be filled in the left cooling cavity, the right cooling cavity, the left connecting beam 4, the inner arc supporting beam 3 and the right connecting beam 2, the cooling efficiency of each component is increased, and the cooling efficiency of the base frame unit 300 is improved.

The foregoing description is only illustrative of the preferred embodiment of the present invention, and is not to be construed as limiting the invention, but is to be construed as limiting the invention to any and all simple modifications, equivalent variations and adaptations of the embodiments described above, which are within the scope of the invention, may be made by those skilled in the art without departing from the scope of the invention.

Claims (10)

1. A quick-connection type water-cooling crystallizer vibrating device is characterized in that: the device comprises a crystallizer vibration unit, a base and a foundation frame unit, wherein the crystallizer vibration unit is arranged on the base, the base is arranged on the foundation frame unit, and the foundation frame unit is arranged on a concrete foundation;

the base frame unit includes: an outer arc support beam, a left Lian Jieliang, an inner arc support beam, and a right connecting beam;

the outer arc support beam comprises a left cooling cavity and a right cooling cavity, the left cooling cavity is provided with a basic frame water inlet, the right cooling cavity is provided with a basic frame water outlet, and the left cooling cavity, the left connecting beam, the inner arc support beam, the right connecting beam and the right cooling cavity are sequentially communicated;

the outer arc supporting beam is provided with a crystallizer water inlet assembly and a crystallizer water outlet assembly, and the water inlet end of the crystallizer vibrating unit is detachably connected with the crystallizer water outlet assembly.

2. The quick connect water cooled crystallizer vibration apparatus of claim 1 wherein: the outer arc supporting beam is provided with a crystallizer water inlet through hole and a crystallizer water outlet through hole, and the crystallizer water inlet assembly is communicated with the crystallizer water outlet assembly through the crystallizer water inlet through hole, the crystallizer cooling water pipe and the crystallizer water outlet through hole in sequence.

3. The quick connect type water cooled crystallizer vibration device as in claim 2, wherein: the crystallizer water outlet assembly comprises an O-shaped sealing ring, a sealing disc and a U-shaped sealing ring which are arranged at the through hole of the crystallizer water outlet from inside to outside.

4. A quick connect water cooled crystallizer vibration apparatus as in claim 3 wherein: the crystallizer water outlet assembly further comprises a gasket set, wherein the gasket set is positioned at the periphery of the crystallizer water outlet through hole, and the gasket set is arranged between the upper surface of the outer arc supporting beam and the lower surface of the sealing disc.

5. The quick connect type water cooled crystallizer vibration device as in claim 2, wherein: the crystallizer water inlet assembly comprises a crystallizer water inlet interface flange, one end of the crystallizer water inlet interface flange is communicated with the through hole of the crystallizer water inlet, and the other end of the crystallizer water inlet interface flange is used for being detachably connected with a crystallizer cooling water pipeline of a workshop.

6. The quick connect water cooled crystallizer vibration apparatus of claim 1 wherein: the outer arc supporting beam upper surface is provided with the outer arc backup pad, the outer arc backup pad is provided with the area tang, take the tang with the base cooperation.

7. The quick connect type water cooled crystallizer vibration apparatus as in claim 6, wherein: the outer arc supporting plate is provided with a T-shaped groove, and the base is connected with the outer arc supporting plate through bolts arranged in the T-shaped groove.

8. The quick connect type water cooled crystallizer vibration apparatus as set forth in claim 7, wherein: the inner arc supporting beam is characterized in that an inner arc supporting plate is arranged on the upper surface of the inner arc supporting beam, a T-shaped groove is formed in the inner arc supporting plate, and the base is connected with the inner arc supporting plate through bolts arranged in the T-shaped groove.

9. The quick connect water cooled crystallizer vibration apparatus of claim 1 wherein:

the left cooling cavity drain pipe of the left cooling cavity is communicated with the left connecting beam water inlet pipe of the left connecting beam through a cooling water connecting pipe;

the left connecting beam water discharge pipe of the left connecting beam is communicated with the inner arc support beam water inlet pipe of the inner arc support beam through a cooling water connecting pipe;

an inner arc support beam drain pipe of the inner arc support beam is communicated with a right connecting beam water inlet pipe of the right connecting beam through a cooling water connecting pipe;

the right connecting beam water discharging pipe of the right connecting beam is communicated with the right cooling cavity water inlet pipe of the right cooling cavity through a cooling water connecting pipe.

10. The quick connect type water cooled crystallizer vibration apparatus as set forth in claim 9, wherein:

the left connecting beam water inlet pipe is lower than the left connecting beam water outlet pipe in the height direction;

the inner arc support beam water inlet pipe is lower than the inner arc support beam water outlet pipe in the height direction;

the right connecting beam water inlet pipe is lower than the right connecting beam water outlet pipe in the height direction;

the water inlet of the foundation frame is lower than the left cooling cavity drain pipe in the height direction;

the right cooling cavity water inlet pipe is lower than the water outlet of the foundation frame in the height direction.