CN111998609A - Mechanical cooling device capable of changing cooling speed in real time - Google Patents

Abstract

The invention discloses a mechanical cooling device capable of changing cooling speed in real time, which comprises a box body, wherein a processing cavity is arranged in the box body, a real-time rotating device is arranged in the processing cavity, the real-time rotating device comprises an adjusting rod rotatably connected with the inner wall of the lower side of the processing cavity, the mechanical cooling device can cool high-temperature objects according to mechanical transmission, the cooling capacity of equipment is controlled according to the quantity of the placed high-temperature objects, the rotating speed of a high-temperature turntable is controlled to improve heat dissipation, the high-temperature objects are carried by controlling a manipulator, high-temperature scalding of operators is prevented, all components are clearly divided, the cooling efficiency of the equipment is exerted to the greatest extent, and unnecessary resource waste is reduced by real-time cooling.

Description

Mechanical cooling device capable of changing cooling speed in real time

Technical Field

The invention relates to the field of mechanical cooling, in particular to a mechanical cooling device capable of changing the cooling speed in real time.

Background

The invention relates to a mechanical cooling device capable of changing the cooling speed in real time, which solves the problems that the temperature of a hot object is reduced and phase change does not occur, a high-temperature object needs to be cooled in the mechanical manufacturing process, the existing physical cooling only needs to pour a large amount of water to the high-temperature object, so that the resource waste is caused, and the cooling capacity cannot be controlled according to the quantity of the high-temperature object.

Disclosure of Invention

In order to solve the problems, the embodiment designs a mechanical cooling device capable of changing the cooling speed in real time, the mechanical cooling device capable of changing the cooling speed in real time comprises a box body, a treatment cavity is arranged in the box body, a real-time rotating device is arranged in the treatment cavity and comprises an adjusting rod which is rotatably connected with the inner wall of the lower side of the treatment cavity, a disc is fixedly arranged on the adjusting rod, a sliding cavity is fixedly arranged on the disc, two hydraulic cavities which are bilaterally symmetrical are fixedly arranged on the inner wall of the lower side of the treatment cavity, a vertical moving plate is slidably arranged in the hydraulic cavities and is connected with the inner wall of the lower side of the hydraulic cavities through a spring, a clamping plate which is slidably connected with the sliding cavity is fixedly arranged on the vertical moving plate, and a telescopic rod which extends into the treatment cavity is fixedly arranged on the vertical moving plate on, a fixed shaft is fixedly arranged on the telescopic rod, a sintering gear is rotatably arranged on the fixed shaft, a fixed rod fixedly connected with the inner wall of the front side of the treatment cavity is arranged on the right side of the cylinder, a forging gear meshed with the sintering gear is rotatably arranged on the fixed rod, a horizontal fixed rod fixedly connected with the vertical movable plate is arranged on one side of the right side of the vertical movable plate on the right side, an iron gear is fixedly arranged on the horizontal fixed rod, a transmission rod rotatably connected with the inner wall of the rear side of the treatment cavity and capable of being connected with the horizontal fixed rod is arranged on the rear side of the horizontal fixed rod, the vertical movable plate moves downwards to realize the rotation speed of the adjusting rod, a carrying device is arranged on the right side of the treatment cavity and comprises two horizontal fixed plates which are fixedly connected with the inner wall of the right side of the treatment cavity and are symmetrical front and back, the movable plate is characterized in that a horizontal limiting groove is formed in the horizontal fixing plate on the rear side, a transmission shaft fixedly connected with the inner wall of the rear side of the treatment cavity is arranged on the lower side of the horizontal fixing plate, a rotating plate is arranged on the transmission shaft in a rotating mode, a moving shaft slidably connected with the horizontal limiting groove is fixedly arranged on the rotating plate, a movable plate extending to the outer side of the treatment cavity is arranged on the moving shaft in a rotating mode, a sliding shaft slidably connected with the V-shaped limiting groove is arranged on the movable plate in a rotating mode, the movable plate slides in the horizontal limiting groove according to the moving shaft, the sliding shaft slides in the V-shaped limiting groove to achieve carrying work, a grabbing device is arranged on the movable plate, and a transmission device is arranged in.

The inner wall of the upper side of the treatment cavity is fixedly provided with a water storage cavity, the inner wall of the left side of the treatment cavity is internally provided with a transmission cavity, the inner wall of the left side of the treatment cavity rotates to be provided with a rotating shaft extending into the transmission cavity, and a sintering bevel gear is fixedly arranged on the rotating shaft.

The carrying device comprises a sliding block in sliding connection with the rotating plate, a transmission shaft is fixedly arranged on the inner wall of the rear side of the processing cavity, and the transmission shaft is connected with the sliding block through a rotating rod.

Wherein, grabbing device include with movable plate fixed connection's magnet chamber, the fixed electro-magnet that is equipped with on the inner wall of magnet chamber left side, it extends to slide on the inner wall of magnet chamber right side the T section iron bar in the magnet chamber outside, T section iron bar with through spring coupling between the magnet chamber, two of the symmetry about being equipped with on the fixed magnet chamber right side end face fall L template, it is equipped with first hinge rod to rotate on the fall L template, the magnet chamber be close to symmetry center one side be equipped with the third hinge rod of falling L template rotation connection, it is equipped with the second hinge rod to rotate on the third hinge rod, the second hinge rod the third hinge rod simultaneously with T section iron bar is articulated through the fourth hinge rod, first hinge rod with it is articulated through anti-L section bar between the second hinge rod.

Wherein the real-time rotating device comprises a casting bevel gear fixedly connected with the adjusting rod, a first bevel gear is fixedly arranged on the inner wall of the rear side of the treatment cavity, a third bevel gear meshed with the casting bevel gear is rotatably arranged on the first bevel gear, the first bevel gear is connected with the fixed shaft through belt transmission, a connecting rod rotatably connected with the inner wall of the rear side of the treatment cavity is arranged on the right side of the fixed shaft, a turbine is fixedly arranged on the connecting rod, the connecting rod is connected with the fixed rod through belt transmission, a second bevel gear fixedly connected with the adjusting rod is arranged on the lower side of the casting bevel gear, a transmission rod is rotatably arranged on the inner wall of the front side of the treatment cavity, a fourth bevel gear meshed with the second bevel gear is fixedly arranged on the transmission rod, and the transmission rod is connected with the transmission rod through belt transmission, the transmission rod is characterized in that a cylindrical worm which is rotatably connected with the inner wall of the lower side of the processing cavity and extends into the transmission cavity is arranged on the front side of the transmission rod, and a cylindrical helical gear which is positioned in the transmission cavity is fixedly arranged on the cylindrical worm.

Wherein, the transmission device comprises a motor fixedly connected with the inner wall of the lower side of the processing cavity, a worm meshed with the turbine is fixedly arranged on the upper side of the motor, an output shaft extending into the transmission cavity is fixedly arranged on the lower side of the motor, a casting gear positioned in the transmission cavity is fixedly arranged on the output shaft, a hydraulic cavity is arranged in the transmission cavity, a piston rod extending into the transmission cavity is slidably arranged on the hydraulic cavity, a rack box meshed with the casting gear is fixedly arranged on the piston rod, a helical gear plate meshed with the cylindrical helical gear is fixedly arranged on the rack box, a hydraulic rod slidingly connected with the hydraulic cavity is arranged on the left side of the piston rod, a cylinder with a surface provided with a limit groove is rotatably arranged on the inner wall of the rear side of the transmission cavity, and a horizontal moving pin capable of being inserted into the limit groove on the surface of the cylinder is fixedly arranged on the hydraulic rod, and a forging bevel gear in meshed connection with the sintering bevel gear is fixedly arranged on the cylinder, and a placing plate capable of placing high-temperature objects is fixedly arranged on the end face of the right side of the treatment cavity.

The invention has the beneficial effects that: the high-temperature rotary table can cool high-temperature objects according to mechanical transmission, the cooling capacity of the equipment is controlled according to the number of the placed high-temperature objects, the rotating speed of the placed high-temperature rotary table is controlled to improve heat dissipation, the high-temperature objects are carried by controlling the manipulator, high-temperature scalding of operators is prevented, each component is clearly divided into multiple parts, the cooling efficiency of the equipment is exerted to the greatest extent, and the components are cooled in real time, so that unnecessary resource waste is reduced.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the structure A-A of FIG. 1;

FIG. 3 is a schematic diagram of B-B of FIG. 1;

FIG. 4 is a schematic diagram of the structure of C-C in FIG. 1;

fig. 5 is a schematic diagram of the structure of D-D in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to a mechanical cooling device capable of changing cooling speed in real time, which comprises a box body 11, wherein a processing cavity 12 is arranged in the box body 11, a real-time rotating device 901 is arranged in the processing cavity 12, the real-time rotating device 901 comprises an adjusting rod 40 which is rotatably connected with the inner wall of the lower side of the processing cavity 12, a disc 25 is fixedly arranged on the adjusting rod 40, a sliding cavity 23 is fixedly arranged on the disc 25, two hydraulic cavities 21 which are bilaterally symmetrical are fixedly arranged on the inner wall of the lower side of the processing cavity 12, a vertical moving plate 22 is slidably arranged in the hydraulic cavity 21, the vertical moving plate 22 is connected with the inner wall of the lower side of the hydraulic cavity 21 through a spring, a clamping plate 24 which is slidably connected with the sliding cavity 23 is fixedly arranged on the vertical moving plate 22 on the left side, a telescopic rod 26 which extends into the processing, a fixed shaft 27 is fixedly arranged on the telescopic rod 26, a sintering gear 29 is rotatably arranged on the fixed shaft 27, a fixed rod 30 fixedly connected with the inner wall of the front side of the treatment cavity 12 is arranged on the right side of the cylinder 17, a forging gear 31 meshed with the sintering gear 29 is rotatably arranged on the fixed rod 30, a horizontal fixed rod 52 fixedly connected with the vertical movable plate 22 is arranged on one side of the right side of the vertical movable plate 22, an iron gear 53 is fixedly arranged on the horizontal fixed rod 52, a transmission rod 54 rotatably connected with the inner wall of the rear side of the treatment cavity 12 and capable of being connected with the horizontal fixed rod 52 is arranged on the rear side of the horizontal fixed rod 52, the vertical movable plate 22 moves downwards to realize the rotation speed and speed of the adjusting rod 40, a carrying device 902 is arranged on the right side in the treatment cavity 12, the carrying device 902 comprises two horizontal fixed plates 63 fixedly connected with the inner wall of the right side of the, a V-shaped limiting groove 62 is arranged in the horizontal fixing plate 63 at the front side, a horizontal limiting groove 64 is arranged in the horizontal fixing plate 63 at the rear side, a transmission shaft 55 fixedly connected with the inner wall of the rear side of the processing cavity 12 is arranged at the lower side of the horizontal fixing plate 63, a rotating plate 56 is rotatably arranged on the transmission shaft 55, a moving shaft 65 which is slidably connected with the horizontal limiting groove 64 is fixedly arranged on the rotating plate 56, the moving shaft 65 is rotatably provided with a moving plate 77 extending to the outside of the treatment chamber 12, a sliding shaft 66 which is connected with the V-shaped limiting groove 62 in a sliding way is arranged on the moving plate 77 in a rotating way, the moving plate 77 slides in the horizontal limiting groove 64 according to the moving shaft 65, the sliding shaft 66 slides in the V-shaped limiting groove 62 to realize the carrying work, a gripping device 903 is arranged on the moving plate 77, and a transfer device 904 is arranged in the inner wall of the lower side of the processing cavity 12.

Beneficially, a water storage cavity 76 is fixedly arranged on the inner wall of the upper side of the treatment cavity 12, a transfer cavity 19 is arranged in the inner wall of the left side of the treatment cavity 12, a rotating shaft 14 extending into the transfer cavity 19 is rotatably arranged on the inner wall of the left side of the treatment cavity 12, and a sintering bevel gear 13 is fixedly arranged on the rotating shaft 14.

According to an embodiment, the carrying device 902 is described in detail below, the carrying device 902 includes a slider 57 slidably connected to the rotating plate 56, a transmission shaft 58 is fixedly provided on the inner wall of the rear side of the processing chamber 12, the transmission shaft 58 is connected to the slider 57 by a rotating rod 59, and the rotating plate 56 moves left and right according to the sliding connection of the slider 57 to the rotating plate 56.

According to an embodiment, the details of the grabbing device 903 are described below, the grabbing device 903 includes a magnet cavity 60 fixedly connected to the moving plate 77, an electromagnet 67 is fixedly disposed on an inner wall of a left side of the magnet cavity 60, a T-shaped iron rod 68 extending to an outer side of the magnet cavity 60 is slidably disposed on an inner wall of a right side of the magnet cavity 60, the T-shaped iron rod 68 is connected to the magnet cavity 60 through a spring, two inverted L-shaped plates 69 are fixedly disposed on a right end face of the magnet cavity 60, the inverted L-shaped plates 69 are rotatably disposed with a first hinge rod 70, a third hinge rod 74 rotatably connected to the inverted L-shaped plates 69 is disposed on a side of the magnet cavity 60 close to a symmetry center, a second hinge rod 73 is rotatably disposed on the third hinge rod 74, and the second hinge rod 73 and the third hinge rod 74 are simultaneously hinged to the T-shaped iron rod 68 through a fourth hinge rod 75, the first hinge rod 70 is hinged to the second hinge rod 73 through a reverse L-shaped rod 71, and the reverse L-shaped rod 71 clamps the high-temperature object through the T-shaped iron bar 68, the second hinge rod 73 and the third hinge rod 74.

According to the embodiment, the real-time rotating device 901 is described in detail below, the real-time rotating device 901 includes a cast bevel gear 41 fixedly connected to the adjusting rod 40, a first bevel gear 43 is fixedly disposed on the inner wall of the rear side of the processing chamber 12, a third bevel gear 45 engaged with the cast bevel gear 41 is rotatably disposed on the first bevel gear 43, the first bevel gear 43 is connected to the fixed shaft 27 through a belt transmission, a connecting rod 32 rotatably connected to the inner wall of the rear side of the processing chamber 12 is disposed on the right side of the fixed shaft 27, a turbine 33 is fixedly disposed on the connecting rod 32, the connecting rod 32 is connected to the fixed rod 30 through a belt transmission, a second bevel gear 44 fixedly connected to the adjusting rod 40 is disposed on the lower side of the cast bevel gear 41, a transmitting rod 46 is rotatably disposed on the inner wall of the front side of the processing chamber 12, a fourth bevel gear 48 engaged with the transmitting gear 44 is fixedly disposed on the transmitting rod 46, the transmission rod 46 is connected with the transmission rod 54 through belt transmission, a cylindrical worm 51 which is rotatably connected with the inner wall of the lower side of the treatment cavity 12 and extends into the transmission cavity 19 is arranged on the front side of the transmission rod 54, a cylindrical helical gear 50 which is positioned in the transmission cavity 19 is fixedly arranged on the cylindrical worm 51, the fixed shaft 27 is meshed with the forging gear 31 in the downward moving process to realize the low-speed rotation of the adjustment rod 40, and the iron gear 53 is connected with the transmission rod 54 in the downward moving process to realize the high-speed rotation of the adjustment rod 40.

According to the embodiment, the details of the transmission device 904 will be described in the following, the transmission device 904 includes a motor 39 fixedly connected to the inner wall of the lower side of the processing chamber 12, a worm 38 engaged with the worm wheel 33 is fixedly disposed on the upper side of the motor 39, an output shaft 37 extending into the transmission chamber 19 is fixedly disposed on the lower side of the motor 39, a cast gear 36 located in the transmission chamber 19 is fixedly disposed on the output shaft 37, a hydraulic chamber 21 is disposed in the transmission chamber 19, a piston rod 34 extending into the transmission chamber 19 is slidably disposed on the hydraulic chamber 21, a rack box 35 engaged with the cast gear 36 is fixedly disposed on the piston rod 34, a helical gear plate 49 engaged with the cylindrical helical gear 50 is fixedly disposed on the rack box 35, a hydraulic rod 20 slidably connected with the hydraulic chamber 21 is disposed on the left side of the piston rod 34, a cylinder 17 with a surface provided with a limit groove is rotatably arranged on the inner wall of the rear side of the transfer cavity 19, a horizontal moving pin 18 capable of being inserted into the limit groove on the surface of the cylinder 17 is fixedly arranged on the hydraulic rod 20, a forging bevel gear 16 meshed and connected with the sintering bevel gear 13 is fixedly arranged on the cylinder 17, and a placing plate 61 capable of placing high-temperature objects is fixedly arranged on the end face of the right side of the processing cavity 12.

The following detailed description of the steps of the mechanical cooling device capable of changing the cooling rate in real time will be provided with reference to fig. 1 to 5: initially, the motor 39 controls the rotation of the transmission shaft 58, the motor 39 stops working, the magnet chamber 60 is at the rightmost position, the sintered gear 29 and the fixed rod 30 are in a non-meshed state for a short time, and no high-temperature object exists on the surface of the disc 25.

When the mechanical cooling is performed, the electromagnet switch is opened to enable the electromagnet 67 to have magnetism, the electromagnet 67 attracts the T-shaped iron rod 68 to move to the left, the T-shaped iron rod 68 moves to the left to drive the fourth hinge rod 75 to move to the left, the fourth hinge rod 75 moves to the left to drive the third hinge rod 74 and the second hinge rod 73 to move to the lower left, the second hinge rod 73 drives the reverse L-shaped rod 71, the reverse L-shaped rod 71 drives the first hinge rod 70 to move close to one side of the symmetry center to clamp the high-temperature object, then the motor 39 controls the rotation of the rotating rod 59 through the PLC, the rotating rod 59 rotates to drive the sliding block 57 to rotate in the rotating plate 56, the rotating plate 56 rotates to drive the sliding connection of the moving shaft 65 in the horizontal limiting groove 64, the moving shaft 65 drives the moving plate 77 to move to the left, the moving plate 77 drives the sliding connection of the sliding shaft 66 in the V-shaped limiting groove 62 to realize the overturning work, the electromagnet switch is turned off, the T-shaped iron bar 68 is restored through the spring, the reverse L-shaped rod 71 does not clamp the high-temperature object, the high-temperature object falls on the disc 25, the disc 25 bears the high-temperature object, the position moves downwards, the disc 25 moves downwards to drive the clamping plate 24 to move downwards, the clamping plate 24 moves downwards to drive the vertical moving plate 22 to move downwards, the motor 39 starts to work, the motor 39 rotates to drive the worm 38 to rotate, the worm 38 rotates to drive the worm wheel 33 to rotate, the worm wheel 33 rotates to drive the connecting rod 32 to rotate, the connecting rod 32 rotates to drive the forging gear 31 to rotate, the motor 39 also works to drive the output shaft 37 to rotate, the output shaft 37 rotates to drive the casting gear 36 to rotate, the casting gear 36 rotates to drive the rack box 35 to rotate, the rack box 35 rotates to drive the piston rod 34 to move left and right, the helical gear, the cylindrical helical gear 50 rotates to drive the cylindrical worm 51 to rotate, the piston rod 34 moves left and right to drive the hydraulic rod 20 to move up and down, the hydraulic rod 20 moves up and down to drive the horizontal moving pin 18 to slide in the limiting groove on the surface of the cylinder 17, so that the cylinder 17 rotates, the cylinder 17 rotates to drive the forging bevel gear 16 to rotate, the forging bevel gear 16 rotates to drive the sintering bevel gear 13 to rotate, the sintering bevel gear 13 rotates to drive the rotating shaft 14 to rotate, the rotating shaft 14 rotates to drive the fan 15 to rotate, the fan 15 rotates to cool a high-temperature object, and the water storage cavity 76 sprays low-temperature fog water.

When the disc 25 bears a small number of high-temperature objects, the sintering gear 29 is meshed with the forging gear 31, the forging gear 31 rotates to drive the sintering gear 29 to rotate, the sintering gear 29 rotates to drive the third bevel gear 45 to rotate, the third bevel gear 45 rotates to drive the casting bevel gear 41 to rotate, the casting bevel gear 41 rotates to drive the adjusting rod 40 to rotate at a low speed, the adjusting rod 40 rotates at a low speed to drive the disc 25 to rotate at a low speed, and the upward moving range of the fixed shaft 27 is within the toughness bearing range of the belt.

When the disc 25 bears more high-temperature objects, the right vertical moving plate 22 moves downwards to enable the iron gear 53 to be meshed with the cylindrical worm 51, the cylindrical worm 51 rotates to drive the iron gear 53 to rotate, the iron gear 53 rotates to drive the horizontal fixing rod 52 to rotate, the horizontal fixing rod 52 rotates to drive the transmission rod 54 to rotate, the transmission rod 54 rotates to drive the transmission rod 46 to rotate, the transmission rod 46 rotates to drive the fourth bevel gear 48 to rotate, the fourth bevel gear 48 rotates to drive the second bevel gear 44 to rotate, the second bevel gear 44 rotates to drive the adjusting rod 40 to rotate at a high speed, and the adjusting rod 40 rotates at a high speed to drive the disc 25 to rotate at a high speed.

The invention has the beneficial effects that: the high-temperature rotary table can cool high-temperature objects according to mechanical transmission, the cooling capacity of the equipment is controlled according to the number of the placed high-temperature objects, the rotating speed of the placed high-temperature rotary table is controlled to improve heat dissipation, the high-temperature objects are carried by controlling the manipulator, high-temperature scalding of operators is prevented, each component is clearly divided into multiple parts, the cooling efficiency of the equipment is exerted to the greatest extent, and the components are cooled in real time, so that unnecessary resource waste is reduced.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (6)

1. The utility model provides a can change mechanical cooling device of cooling rate in real time, includes the box, be equipped with the processing chamber in the box, its characterized in that: the treatment cavity is internally provided with a real-time rotating device, the real-time rotating device comprises an adjusting rod rotatably connected with the inner wall of the lower side of the treatment cavity, a disc is fixedly arranged on the adjusting rod, a sliding cavity is fixedly arranged on the disc, two hydraulic cavities which are bilaterally symmetrical are fixedly arranged on the inner wall of the lower side of the treatment cavity, a vertical moving plate is slidably arranged in the hydraulic cavity, the vertical moving plate is connected with the inner wall of the lower side of the hydraulic cavity through a spring, a clamping plate which is slidably connected with the sliding cavity is fixedly arranged on the vertical moving plate, a telescopic rod which extends into the treatment cavity is fixedly arranged on the vertical moving plate at the left side of the vertical moving plate, a fixed shaft is fixedly arranged on the telescopic rod, a sintering gear is rotatably arranged on the fixed shaft, a fixed rod which is fixedly connected with the inner wall of the front side of, a horizontal fixed rod with one side fixedly connected with the vertical movable plate is arranged on the right side of the vertical movable plate on the right side, an iron gear is fixedly arranged on the horizontal fixed rod, a transmission rod which is rotatably connected with the inner wall of the rear side of the treatment cavity and can be connected with the horizontal fixed rod is arranged on the rear side of the horizontal fixed rod, the vertical movable plate moves downwards to realize the rotation speed of the adjustment rod, a carrying device is arranged on the right side in the treatment cavity and comprises two horizontal fixed plates which are fixedly connected with the inner wall of the right side of the treatment cavity and are symmetrical front and back, a V-shaped limiting groove is arranged in the horizontal fixed plate on the front side, a horizontal limiting groove is arranged in the horizontal fixed plate on the rear side, a transmission shaft fixedly connected with the inner wall of the rear side of the treatment cavity is arranged on the lower side of the horizontal fixed plate, a rotating plate is rotatably arranged on, the movable shaft is provided with a movable plate extending to the outer side of the treatment cavity in a rotating mode, a sliding shaft in sliding connection with a V-shaped limiting groove is arranged on the movable plate in a rotating mode, the movable plate is used for sliding in the horizontal limiting groove according to the movable shaft, the sliding shaft slides in the V-shaped limiting groove to achieve carrying work, a grabbing device is arranged on the movable plate, and a transmission device is arranged in the inner wall of the lower side of the treatment cavity.

2. A mechanical cooling device capable of varying the cooling rate in real time as claimed in claim 1, wherein: the fixed water storage chamber that is equipped with of process chamber upside inner wall, be equipped with the transmission chamber in the process chamber left side inner wall, process chamber left side inner wall rotates and is equipped with and extends to the rotation axis in the transmission chamber, the fixed sintering bevel gear that is equipped with on the rotation axis.

3. A mechanical cooling device capable of varying the cooling rate in real time as claimed in claim 2, wherein: the carrying device comprises a sliding block which is in sliding connection with the rotating plate, a transmission shaft is fixedly arranged on the inner wall of the rear side of the processing cavity, and the transmission shaft is connected with the sliding block through a rotating rod.

4. A mechanical cooling device capable of varying the cooling rate in real time according to claim 3, wherein: grabbing device include with movable plate fixed connection's magnet chamber, the fixed electro-magnet that is equipped with on the inner wall of magnet chamber left side, it extends to slide on the inner wall of magnet chamber right side the T section iron bar in the magnet chamber outside, T section iron bar with through spring coupling between the magnet chamber, two of the symmetry about fixed being equipped with on the magnet chamber right side terminal surface fall the L template, it is equipped with first hinge rod to rotate on the L template to fall, the magnet chamber be close to symmetry center one side be equipped with it rotates the third hinge pole of connecting to fall the L template, it is equipped with the second hinge rod to rotate on the third hinge pole, the second hinge rod the third hinge pole simultaneously with T section iron bar is articulated through the fourth hinge rod, first hinge rod with it is articulated through anti-L section bar between the second hinge rod.

5. A mechanical cooling device capable of varying the cooling rate in real time according to claim 4, wherein: the real-time rotating device comprises a casting bevel gear fixedly connected with the adjusting rod, a first bevel gear is fixedly arranged on the inner wall of the rear side of the treatment cavity, a third bevel gear meshed with the casting bevel gear is rotatably arranged on the first bevel gear, the first bevel gear is connected with the fixing shaft through belt transmission, a connecting rod rotatably connected with the inner wall of the rear side of the treatment cavity is arranged on the right side of the fixing shaft, a turbine is fixedly arranged on the connecting rod, the connecting rod is connected with the fixing rod through belt transmission, a second bevel gear fixedly connected with the adjusting rod is arranged on the lower side of the casting bevel gear, a transmission rod is rotatably arranged on the inner wall of the front side of the treatment cavity, a fourth bevel gear meshed with the second bevel gear is fixedly arranged on the transmission rod, and the transmission rod is connected with the transmission rod through belt transmission, the transmission rod is characterized in that a cylindrical worm which is rotatably connected with the inner wall of the lower side of the processing cavity and extends into the transmission cavity is arranged on the front side of the transmission rod, and a cylindrical helical gear which is positioned in the transmission cavity is fixedly arranged on the cylindrical worm.

6. A mechanical cooling device capable of varying the cooling rate in real time according to claim 4, wherein: the transmission device comprises a motor fixedly connected with the inner wall of the lower side of the processing cavity, a worm meshed with the turbine is fixedly arranged on the upper side of the motor, an output shaft extending into the transmission cavity is fixedly arranged on the lower side of the motor, a casting gear positioned in the transmission cavity is fixedly arranged on the output shaft, a hydraulic cavity is arranged in the transmission cavity, a piston rod extending into the transmission cavity is slidably arranged on the hydraulic cavity, a rack box meshed with the casting gear is fixedly arranged on the piston rod, a helical gear plate meshed with the cylindrical helical gear is fixedly arranged on the rack box, a hydraulic rod slidably connected with the hydraulic cavity is arranged on the left side of the piston rod, a cylinder with a limiting groove formed in the surface is rotatably arranged on the inner wall of the rear side of the transmission cavity, and a horizontal moving pin capable of being inserted into the limiting groove on the surface of the cylinder is fixedly arranged on the hydraulic rod, and a forging bevel gear in meshed connection with the sintering bevel gear is fixedly arranged on the cylinder, and a placing plate capable of placing high-temperature objects is fixedly arranged on the end face of the right side of the treatment cavity.

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