CN112880386A

CN112880386A - All-round aluminum alloy casting crystallizer baking equipment

Info

Publication number: CN112880386A
Application number: CN202110194566.2A
Authority: CN
Inventors: 胡军; 贾桂龙; 刘志玮; 尹建平; 张焕良; 李志坚; 黄盼盼; 黄奎; 叶西探; 伍志铭
Original assignee: Guangxi Zhengrun New Material Technology Co ltd
Current assignee: Guangxi Zhengrun New Material Technology Co ltd
Priority date: 2021-02-21
Filing date: 2021-02-21
Publication date: 2021-06-01
Anticipated expiration: 2041-02-21
Also published as: CN112880386B

Abstract

The invention discloses an all-dimensional aluminum alloy casting crystallizer baking device which comprises a rack, a sliding platform and a baking assembly, wherein a transverse rail is arranged on the rack, and a transverse driving mechanism is arranged on the rack; the sliding platform can be arranged on the transverse rail in a sliding manner; the output end of the transverse driving mechanism is connected with a sliding platform, and a longitudinal telescopic mechanism capable of lifting is arranged on the sliding platform; the baking assembly comprises a spray head and a gas transmission hose; the spray head is communicated with the air outlet end of the air hose; the position of the spray head is adjustably arranged on the output end of the longitudinal telescopic mechanism; the gas nozzle is characterized in that a gas head can be rotatably installed on the nozzle, the gas outlet end of the gas head is obliquely and outwards arranged, and the gas hose can supply pressure gas and drive the gas head to rotate. The crystallizer baking device can realize azimuth drying of the crystallizer and has strong adaptability.

Description

All-round aluminum alloy casting crystallizer baking equipment

Technical Field

The invention relates to the technical field of crystallizer drying equipment, in particular to an all-dimensional aluminum alloy casting crystallizer baking device.

Background

In modern industry, semi-continuous casting technology is mostly adopted for casting production of aluminum and aluminum alloy. In preparation prior to casting, absolute drying of the mold plays a crucial role in the safety of the entire casting process. If water drops exist on the contact surface of the crystallizer and the aluminum melt, the water drops can be contacted with the aluminum melt to explode or cause aluminum liquid to splash during casting, so that potential safety hazards are formed, and similar safety accidents happen in casting workshops of aluminum processing enterprises all over the country every year.

At present, most of aluminum alloy casting workshops at home still adopt a method of manually baking the crystallizer, namely, a flame spraying cavity is manually held, and water vapor in the crystallizer is dried by heat generated by flame sprayed by a flame spraying gun, so that the production efficiency is greatly reduced by the drying mode, and the workload of a line casting worker is increased. Meanwhile, the potential safety hazard cannot be eliminated due to incomplete manual baking or incomplete drying of the crystallizer caused by negligence of work. Some manufacturers design some fixed baking equipment to bake the crystallizer, but for the corner or the depressed area in the crystallizer, namely the crystallizer with the special-shaped curved surface, the direction of the spray head in the baking equipment is basically fixed, and the direction of the flame column sprayed by the spray head is also determined, so that the drying efficiency for the special-shaped curved surface is very low, the problem of incomplete drying exists, and the drying quality is not high.

Disclosure of Invention

The invention aims to at least solve one of the technical problems and provides an all-dimensional aluminum alloy casting crystallizer baking device which can realize the directional drying of a crystallizer and has strong adaptability.

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

an all-dimensional aluminum alloy casting crystallizer baking device comprises a rack, a sliding platform and a baking assembly, wherein a transverse rail is arranged on the rack, and a transverse driving mechanism is arranged on the rack; the sliding platform can be arranged on the transverse rail in a sliding manner; the output end of the transverse driving mechanism is connected with a sliding platform, and a longitudinal telescopic mechanism capable of lifting is arranged on the sliding platform; the baking assembly comprises a spray head and a gas transmission hose; the spray head is communicated with the air outlet end of the air hose; the position of the spray head is adjustably arranged on the output end of the longitudinal telescopic mechanism; the gas nozzle is characterized in that a gas head can be rotatably installed on the nozzle, the gas outlet end of the gas head is obliquely and outwards arranged, and the gas hose can supply pressure gas and drive the gas head to rotate.

As an improvement of the technical scheme, the gas burner comprises a rotating cylinder and a plurality of nozzles, one end of the rotating cylinder, which is outward, is closed, the nozzles are obliquely and outwardly communicated with one end of the rotating cylinder, a neck is arranged in the rotating cylinder, the diameter of the neck is smaller than that of the two ends of the rotating cylinder, the neck is movably sleeved on the outer wall of the gas outlet end of the nozzle through a rotating ring frame, and a spiral chamber line or a spiral blade is arranged on the inner wall of the non-closed end of the rotating cylinder along the axial direction of the inner wall.

As an improvement of the technical scheme, an ignition rod is coaxially arranged at one outward end of the spray head, the outward end of the ignition rod movably penetrates through one closed end of the rotating cylinder, and an igniter is arranged at the tail end of the ignition rod.

As an improvement of the technical scheme, one end of the output of the spray head is provided with an installation step, the spray head limits the rotating ring frame on the installation step through a locking nut, and the installation step is provided with a rotating bearing.

As an improvement of the technical scheme, a cone nozzle is arranged on the outer wall of one output end of the spray head, a plurality of open slots are uniformly arranged on the side wall of the cone nozzle along the axial direction of the cone nozzle, and the end part of the spray head is divided into a plurality of tongue pieces; the outer wall of one end, close to the cone nozzle, of the spray head is connected with an adjusting mechanism in a threaded mode, and the adjusting mechanism can adjust the caliber of the output end of the cone nozzle.

As an improvement of the technical scheme, the adjusting mechanism comprises an adjusting nut, a limiting ring and a connecting rod, the connecting rod is provided with a plurality of groups, two ends of the connecting rod in the groups are respectively connected with the adjusting nut and the limiting ring, the adjusting nut is in threaded connection with the outer wall of one end, close to the cone nozzle, of the spray head, and the limiting ring is movably sleeved on one end of the cone nozzle output.

As an improvement of the technical scheme, the transverse driving mechanism comprises a transverse telescopic cylinder, a fixed seat and a movable seat, the fixed seat is installed at the top of the frame and located on the area of one end of the transverse rail, the output end of the transverse telescopic cylinder is detachably connected with the sliding platform through the movable seat, and the installation end of the transverse telescopic cylinder is hinged to the fixed seat.

As the improvement of above-mentioned technical scheme, sliding platform includes carriage, elevating system and sets up the mounting bracket in the elevating system bottom, elevating system installs on the carriage, carriage slidable mounting is on the cross rail, fixing base detachably installs on the carriage, the mounting bracket is provided with a plurality of groups, every group the mounting bracket is all installed vertical telescopic machanism.

As an improvement of the technical scheme, a cylinder is arranged on the mounting frame along the longitudinal direction, and the mounting end of the longitudinal telescopic mechanism is inserted into the cylinder and fixed through a bolt.

As an improvement of the technical scheme, the baking assembly further comprises a main gas supply pipe, the gas transmission hoses on the longitudinal telescopic mechanisms in each group are communicated with the main gas supply pipe, and the gas transmission hoses are provided with control valves.

Compared with the prior art, the beneficial effects of this application are:

the all-dimensional aluminum alloy casting crystallizer baking device is provided with the transverse driving mechanism and the longitudinal telescopic mechanism, so that transverse and longitudinal actions are realized, an internal cavity of the crystallizer is conveniently baked in all directions, water drops which are not cleaned are prevented from being omitted, and the working efficiency and the baking quality are improved; in addition, the arrangement of the air hose can facilitate keeping ventilation when the sliding platform moves, meanwhile, the air hose is suitable for different working positions of the sliding platform, the working flexibility is improved, and the position of the spray head can be adjusted to adapt to crystallizers of different specifications. The gas transmission hose can supply pressure gas and drive the gas burner to rotate, so that the gas burner can provide well-stimulated flame in all directions, and the gas transmission hose is suitable for drying in a crystallizer with a complex structure.

Drawings

The following detailed description of embodiments of the invention is provided in conjunction with the appended drawings, in which:

FIG. 1 is a first schematic structural diagram according to an embodiment of the present invention;

FIG. 2 is a second schematic structural diagram according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a bake assembly in an embodiment of the present invention;

figure 4 is a cross-sectional view of a toasting assembly in accordance with an embodiment of the present invention.

In the figure: the device comprises a frame 1, a transverse rail 11, a roller way 12, a stand column 14, a base 15, a transverse driving mechanism 2, a transverse telescopic cylinder 21, a fixed seat 22, a movable seat 23, a sliding platform 3, a sliding frame 31, a mounting frame 32, a cylinder 34, a bolt 35, a lifting mechanism 36, a longitudinal telescopic mechanism 4, a baking assembly 5, a gas head 51, a rotating cylinder 511, a plurality of nozzles 512, a neck 513, a rotating ring frame 514, a spiral rifling 515, a gas delivery hose 52, a spray head 53, an ignition rod 54, an igniter 55, a mounting step 56, a locking nut 57, a cone nozzle 58, an open slot 581, a tongue 582, an adjusting mechanism 59, an adjusting nut 591, a limiting ring 592, a connecting rod 593, a main gas supply pipe 5a and a control valve 5b

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When a component is referred to as being "connected" to another component, it can be directly connected to the other component or intervening components may also be present. When a component is referred to as being "disposed on" another component, it can be directly on the other component or there can be intervening components, and when a component is referred to as being "disposed in the middle," it is not just disposed in the middle, so long as it is not disposed at both ends, but rather is within the scope of the middle. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

As shown in fig. 1 to 4, the invention provides an all-dimensional aluminum alloy casting crystallizer baking device, which comprises a frame 1, a sliding platform 3 and a baking assembly 5, wherein a transverse rail 11 is arranged on the frame 1, and a transverse driving mechanism 2 is arranged on the frame 1; the sliding platform 3 can be slidably arranged on the transverse rail 11; the output end of the transverse driving mechanism 2 is connected with a sliding platform 3, and a longitudinal telescopic mechanism 4 capable of lifting is arranged on the sliding platform 3; the baking assembly 5 comprises a spray head 53 and a gas transmission hose 52; the spray head 53 is communicated with the air outlet end of the air hose 52; the spray head 53 is arranged on the output end of the longitudinal telescopic mechanism 4 in a position-adjustable manner; the nozzle 53 is rotatably provided with a gas head 51, the gas outlet end of the gas head 51 is arranged obliquely outwards, and the gas hose 52 can supply pressure gas and drive the gas head 51 to rotate.

Wherein, the frame 1 is provided with a transverse rail 11, wherein the transverse rail 11 is arranged on the top of the frame 1, and the crystallizer is positioned below the transverse rail 11. For better mounting and fixing of the present frame 1, in the present application the frame 1 comprises two sets of uprights 14 and a base 15 arranged on the bottom of each set of uprights 14, the cross rail 11 being mounted on the top of the two sets of uprights 14. Wherein, in the in-service use of reality, can probably have a plurality ofly in the aluminum alloy casting crystallizer, be provided with a plurality of vertical telescopic machanism 4 for this application on sliding platform 3, the interval between every vertical telescopic machanism 4 equals the distance between two crystallizers, and the staff of being convenient for utilizes this baking equipment can once only toast a plurality of crystallizers like this. It should be noted that, for the convenience of understanding the technical solution of the present application, the transverse direction in the present application refers to a direction in which a plurality of crystallizers are arranged side by side, and is also a width method of a single crystallizer; and the longitudinal direction means the lengthwise direction of the mold.

Further, in order to better drive the sliding platform 3 to slide along the transverse rail 11, so as to facilitate transverse baking of the crystallizer, the present application provides a specific technical solution related to the transverse driving mechanism 2. Wherein, horizontal actuating mechanism 2 includes horizontal telescopic cylinder 21, fixing base 22 and sliding seat 23, fixing base 22 is installed at 1 top in the frame and is located on the region of horizontal rail 11 one end, the output of horizontal telescopic cylinder 21 passes through sliding seat 23 and is connected with 3 detachably of sliding platform, the installation end of horizontal telescopic cylinder 21 articulates on fixing base 22. The transverse telescopic cylinder 21 can be replaced by a telescopic electric cylinder or a telescopic mechanism, and in some improved embodiments, the transverse telescopic cylinder 21 can also be replaced by a crank-connecting rod structure. The movable seat 23 and the fixed seat 22 are provided with movable holes, so that the movable seat is fixed on a corresponding structure through screws, and the movable seat is convenient to disassemble and maintain at the later stage.

Referring to fig. 1 and 2, the sliding platform 3 includes a sliding frame 31, a lifting mechanism 36 and a mounting frame 32 disposed at the bottom of the lifting mechanism 36, the lifting mechanism 36 is installed on the sliding frame 31, the sliding frame 31 is slidably installed on the cross rail 11, the fixing base 22 is detachably installed on the sliding frame 31, the mounting frame 32 is provided with a plurality of groups, and the longitudinal telescopic mechanism 4 is installed on each group of the mounting frame 32. The gas heads 51 are arranged at the telescopic ends of each group of longitudinal telescopic mechanisms 4, and all the gas heads 51 are communicated with a gas hose 52. In addition, the sliding frame 31 can slide in a rolling friction manner and a conventional surface-to-surface friction manner with respect to the transverse rail 11, for which purpose, in order to reduce the loss and improve the fault tolerance of the work, the transverse rail 11 is provided with the roller way 12, and the sliding frame 31 is provided with the rollers 33 which are matched with the roller way 12. Furthermore, the two ends of the roller way 12 are provided with the limiting blocks 13, so that the sliding frame 31 can be limited in movement. Wherein, the lifting mechanism 36 is a lifting cylinder, which is convenient for installation and realizes the drying work of crystallizers with different depths,

further, for better installation of longitudinal telescoping mechanism 4, for simple design, and maintenance in the later stage of being convenient for simultaneously, longitudinal telescoping mechanism 4 chooses for use conventional cylinder in this application. Since the cylinder is generally of a conventional cylindrical shape, in a modified embodiment of the present application, a cylinder 34 is disposed on the mounting frame 32 along a longitudinal direction, and the mounting end of the longitudinal telescopic mechanism 4 is inserted into the cylinder 34 and fixed by a bolt 35. The cylinder 34 is perpendicular to the transverse rail 11, a threaded hole is formed in the cylinder 34, and the mounting end of the longitudinal telescopic mechanism 4 is inserted into the cylinder 34 and then locked and fixed through a bolt 35. Because the orientation of the gas head 51 is different in actual work, the gas head 51 is sleeved on the output end of the longitudinal telescopic mechanism 4 through a locking ring and is locked through a nut, and the design is convenient for workers to adjust according to actual requirements.

In addition, probably need dry the efficiency that multiunit crystallizer was toasted in order to improve simultaneously in this application, consequently can adopt multiunit to toast subassembly 5 cooperation multiunit longitudinal stretching mechanism 4 and realize corresponding stoving. In order to supply the pressure gas, the baking assembly 5 further includes a main gas supply pipe 5a, the gas transmission hose 52 of each set of longitudinal stretching mechanism 4 is communicated with the main gas supply pipe 5a, and the gas transmission hose 52 is provided with a control valve 5 b. The main gas supply pipe 5a is mounted on the frame 1 or mounted on the cross rail 11, so that gas can be supplied to the plurality of gas heads 51. The control valve 5b may be a solenoid valve for remote control.

Referring to fig. 1 to 4, in the present application, the gas head 51 can rotate when the gas hose 52 supplies the pressure gas, which is mainly for rotating the gas head 51, the gas outlet end of the gas head 51 is disposed obliquely outward in the present application, that is, the direction of the sprayed gas is not parallel to the axial direction of the nozzle 53, and for this reason, the flame formed after the combustion of the gas sprayed from the gas head 51 at the later stage is not the same as the direction of the nozzle 53, so that the gas can be sprayed all-directionally, and especially the flame can enter the corner area of the mold to be baked. In order to realize the automatic rotation or passive rotation of the gas head 51, the gas head 51 comprises a rotating cylinder 511 and a plurality of nozzles 512, the outward end of the rotating cylinder 511 is closed, the plurality of nozzles 512 are obliquely and outwards communicated with the outward end of the rotating cylinder 511, a neck 513 is arranged in the rotating cylinder 511, the diameter of the neck 513 is smaller than that of the two ends of the rotating cylinder 511, the neck 513 is movably sleeved on the outer wall of the air outlet end of the nozzle 53 through a rotating ring frame 514, and the inner wall of the non-closed end of the rotating cylinder 511 is provided with a spiral rifling 515 or a spiral blade along the axial direction. Since the air outlet end of the nozzle 53 is disposed in the neck 513, the air flow rate in the neck 513 is significantly higher than the air flow rate outside, and according to bernoulli's principle, the pressure at the neck 513 is the smallest, and the neck 513 is a negative pressure region with respect to the atmospheric pressure outside and the pressure of the pressurized gas in the nozzle 53. Therefore, after the nozzle 53 sprays the pressure gas, outside air is inevitably driven to enter the rotating cylinder 511 from the unclosed end of the rotating cylinder 511, and finally the air is mixed with the pressure gas sprayed by the nozzle 53 and then sprayed out from the nozzle 512, so that the outside ignition is facilitated. Since continuous air enters the rotary drum 511 from the unclosed end of the rotary drum 511, the flowing air flow interacts with the spiral rifling 515 or the spiral blades, so that the air flow provides a collision force to the spiral rifling 515 or the spiral blades, and when the speed of the pressure gas sprayed from the spray head 53 is high enough, that is, the negative pressure in the region of the neck 513 is low enough, the air flow pushes the rotary drum 511 to overcome the friction force between the rotary drum 511 and the spray head 53 to realize relative rotation. Due to the structural design, flame columns formed by the ignited combustible mixed gas sprayed by the nozzles 512 can rotate around the axial direction of the spray nozzle 53, or form a certain included angle with the axial direction of the spray nozzle 53, so that various special-shaped concave areas in the crystallizer can be conveniently baked, and the baking quality is improved.

As an improvement of the above technical solution, in order to reduce the trouble of manual ignition, an ignition rod 54 is coaxially arranged at the outward end of the spray head 53, the outward end of the ignition rod 54 movably penetrates through the closed end of the rotary cylinder 511, and an igniter 55 is arranged at the tail end of the ignition rod 54. The igniter 55 may be angled with respect to the ignition rod 54 so that the ignition end of the igniter 55 is adjacent the nozzle 512 for ignition. In this embodiment, a sealing structure is provided between the outer wall of the ignition rod 54 and the closed end of the rotary cylinder 511 to realize the rotary sealing. While the igniter 55 can be routed within the spray head 53 and eventually out through the spray head 53 or the side wall of the gas hose 52 to communicate with external circuitry.

Referring to fig. 3 and 4, in order to better limit the position of the rotary cylinder 511 on the spray head 53, the output end of the spray head 53 is provided with a mounting step 56, the spray head 53 limits the rotary ring bracket 514 on the mounting step 56 through a locking nut 57, and the mounting step 56 is provided with a rotary bearing.

Referring to fig. 4, in the above embodiment, the aperture of the nozzle 53 is a fixed aperture, which is not suitable for baking of crystallizers of different specifications and is not beneficial to adjusting the flow rate of the pressure gas. In a modified embodiment of the present application, a cone 58 is disposed on the outer wall of the output end of the spray nozzle 53, a plurality of open slots 581 are uniformly disposed on the side wall of the cone 58 along the axial direction thereof, and the end of the spray nozzle 53 is divided into a plurality of tongues 582; the outer wall of one end of the spray head 53 close to the cone nozzle 58 is connected with an adjusting mechanism 59 through threads, the adjusting mechanism 59 can adjust the caliber of the output end of the cone nozzle 58, and the caliber of the output end of the cone nozzle 58 adjusted by the adjusting mechanism 59 is actually the closing caliber of the cone nozzle 58 formed by all the tongues 582.

Further, in order to simplify the structure and facilitate the adjustment, the adjusting mechanism 59 includes an adjusting nut 591, a limiting ring 592 and a connecting rod 593, the connecting rod 593 is provided with a plurality of groups, two ends of the plurality of groups of connecting rods 593 are respectively connected with the adjusting nut 591 and the limiting ring 592, the adjusting nut 591 is screwed on the outer wall of one end of the spray head 53 close to the cone nozzle 58, and the limiting ring 592 is movably sleeved on one end of the output of the cone nozzle 58. When the caliber of the output end of the conical nozzle 58 needs to be adjusted to be small, the limiting ring 592 moves along the conical nozzle 58 close to one end of the spray head 53 by rotating the adjusting nut 591, so that the tongue pieces 582 can be pressed to draw close inwards, the air outlet caliber of the conical nozzle 58 formed by all the tongue pieces 582 becomes small, and the effects of closing up and adjusting the flow rate of pressure gas sprayed by the spray head 53 are achieved. In fact, in some modified embodiments, the size of the flame column sprayed out by the nozzle 512 is adjusted to adapt to the drying work of crystallizers with different specifications. The nozzle 512 may also be provided with an adjustment mechanism 59 and a cone 58 to achieve the same effect as the spray head 53, and for this reason the present application is not described in detail.

The all-dimensional aluminum alloy casting crystallizer baking device is provided with the transverse driving mechanism 2 and the longitudinal telescopic mechanism 4, so that transverse and longitudinal actions are realized, an internal cavity of the crystallizer is conveniently baked in all aspects, water drops which are not cleaned are avoided being omitted, and the working efficiency and the baking quality are improved; in addition, the arrangement of the air hose 52 can facilitate keeping ventilation when the sliding platform moves, and meanwhile, the air hose is suitable for different working positions of the sliding platform 3, so that the working flexibility is improved, and the position of the spray head 53 can be adjusted to adapt to crystallizers of different specifications. The gas hose 52 can supply pressure gas and drive the gas head 51 to rotate, so that the gas head 51 can provide well-soothed flame more comprehensively, and the crystallizer is suitable for drying in a crystallizer with a complex structure.

The above embodiments are only for illustrating the technical solutions of the present invention and are not limited thereto, and any modification or equivalent replacement without departing from the spirit and scope of the present invention should be covered within the technical solutions of the present invention.

Claims

1. An all-round aluminum alloy casting crystallizer baking device is characterized by comprising

The device comprises a rack, a driving mechanism and a driving mechanism, wherein a transverse rail is arranged on the rack;

a sliding platform which can be installed on the transverse rail in a sliding mode; the output end of the transverse driving mechanism is connected with a sliding platform, and a longitudinal telescopic mechanism capable of lifting is arranged on the sliding platform; and

the baking assembly comprises a spray head and a gas transmission hose; the spray head is communicated with the air outlet end of the air hose; the position of the spray head is adjustably arranged on the output end of the longitudinal telescopic mechanism; the gas nozzle is characterized in that a gas head can be rotatably installed on the nozzle, the gas outlet end of the gas head is obliquely and outwards arranged, and the gas hose can supply pressure gas and drive the gas head to rotate.

2. The baking device of the omnibearing aluminum alloy casting crystallizer according to claim 1, wherein the gas head comprises a rotating cylinder and a plurality of nozzles, one end of the rotating cylinder facing outwards is closed, the plurality of nozzles are obliquely and outwards communicated with one end of the rotating cylinder facing outwards, a neck is arranged in the rotating cylinder, the diameter of the neck is smaller than that of two ends of the rotating cylinder, the neck is movably sleeved on the outer wall of the air outlet end of the nozzle through a rotating ring frame, and a spiral chamber line or a spiral blade is arranged on the inner wall of the non-closed end of the rotating cylinder along the axial direction of the neck.

3. The baking device of the all-directional aluminum alloy casting crystallizer according to claim 2, wherein an outward end of the nozzle is coaxially provided with an ignition rod, the outward end of the ignition rod movably penetrates through a closed end of the rotating cylinder, and an igniter is arranged at the tail end of the ignition rod.

4. The baking apparatus of claim 2, wherein the nozzle has a mounting step at one end, the nozzle is locked to the mounting step by a locking nut, and the mounting step is provided with a rotating bearing.

5. The baking device of the omnibearing aluminum alloy casting crystallizer as claimed in claim 2, wherein a conical nozzle is arranged on the outer wall of the output end of the spray head, a plurality of open slots are uniformly arranged on the side wall of the conical nozzle along the axial direction of the conical nozzle, and the end part of the spray head is divided into a plurality of tongue pieces; the outer wall of one end, close to the cone nozzle, of the spray head is connected with an adjusting mechanism in a threaded mode, and the adjusting mechanism can adjust the caliber of the output end of the cone nozzle.

6. The baking device of the omnibearing aluminum alloy casting crystallizer as claimed in claim 5, wherein the adjusting mechanism comprises a plurality of groups of adjusting nuts, a limiting ring and a connecting rod, the connecting rod is provided with a plurality of groups, two ends of the plurality of groups of connecting rods are respectively connected with the adjusting nuts and the limiting ring, the adjusting nuts are in threaded connection with the outer wall of one end of the nozzle close to the conical nozzle, and the limiting ring is movably sleeved on one end of the output of the conical nozzle.

7. The all-round aluminum alloy casting crystallizer baking device of claim 1 or 2, wherein the lateral driving mechanism comprises a lateral telescopic cylinder, a fixed seat and a movable seat, the fixed seat is installed on the top of the frame in the region of one end of the lateral rail, the output end of the lateral telescopic cylinder is detachably connected with the sliding platform through the movable seat, and the installation end of the lateral telescopic cylinder is hinged on the fixed seat.

8. The all-round aluminum alloy casting crystallizer baking device of claim 7, wherein the sliding platform comprises a carriage, a lifting mechanism and a mounting rack disposed on the bottom of the lifting mechanism, the lifting mechanism is mounted on the carriage, the carriage is slidably mounted on the cross rail, the fixing seat is detachably mounted on the carriage, the mounting rack is provided with a plurality of groups, and the longitudinal stretching mechanism is mounted on each group of the mounting rack.

9. The baking apparatus of an all-directional aluminum alloy casting crystallizer of claim 8, wherein the mounting frame is longitudinally provided with a cylinder, and the mounting end of the longitudinal telescopic mechanism is inserted into the cylinder and fixed by bolts.

10. The baking apparatus of claim 7, wherein said baking assembly further comprises a main gas supply pipe, each set of gas hoses of said longitudinal stretching mechanism is connected to said main gas supply pipe, and said gas hoses are provided with control valves.