CN113509887A

CN113509887A - Rotary energy-saving type hydrothermal reaction kettle

Info

Publication number: CN113509887A
Application number: CN202110830384.XA
Authority: CN
Inventors: 韩丽旭
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-07-22
Filing date: 2021-07-22
Publication date: 2021-10-19

Abstract

The invention relates to a hydrothermal reaction kettle, in particular to a rotary type energy-saving hydrothermal reaction kettle, which comprises a supporting underframe, a stirring assembly, a pouring control assembly, a pouring assembly and the like, wherein the stirring assembly is arranged on the supporting underframe; the stirring assembly is arranged on the supporting bottom frame, the pouring control assembly is arranged on the supporting bottom frame, and the pouring assembly is arranged on the supporting bottom frame. The cold water in the supporting bottom frame can flow into the other collecting frame, and the hot water in one collecting frame can flow into the supporting bottom frame, so that the time required by heating can be shortened, the improvement of the working efficiency is facilitated, the energy can be saved, and the effect of effectively shortening the heating time and saving the energy can be achieved.

Description

Rotary energy-saving type hydrothermal reaction kettle

Technical Field

The invention relates to a hydrothermal reaction kettle, in particular to a rotary type energy-saving hydrothermal reaction kettle.

Background

The hydrothermal reaction kettle is a closed container capable of decomposing insoluble substances, can be used for sample dissolving pretreatment in atomic absorption spectroscopy, plasma emission and other analyses, can also achieve the purpose of quickly digesting the insoluble substances by utilizing a strong acid or strong base in a tank body and a high-temperature and high-pressure closed environment, and is widely applied to research and production in the departments of petrochemical industry, biomedicine, material science and the like.

The hydrothermal reaction kettle needs to be arranged in a heater, the temperature in the heater is raised to the required reaction temperature according to the requirement, and the temperature of the hydrothermal reaction kettle needs to be reduced according to the requirement after the reaction is finished.

Disclosure of Invention

In view of the above, it is necessary to provide a rotary energy-saving hydrothermal reaction kettle with high work efficiency, which can effectively increase the cooling speed of the reactants in the reaction kettle, effectively shorten the heating time to save energy, so as to solve the problems of consuming a large amount of time and energy and having low work efficiency in the background art.

The technical implementation scheme of the invention is as follows: the utility model provides a rotary type energy-saving hydrothermal reaction kettle, is including supporting the chassis, stirring the subassembly, pouring the subassembly, empting the control assembly, pouring subassembly and airtight subassembly into, on the stirring subassembly was located and is supported the chassis, on the subassembly that pours was located and is supported the chassis, toppled the control assembly and locate and support the chassis, pour the subassembly and locate and support on the chassis, airtight subassembly is located and is poured the subassembly into on.

Optionally, mix the subassembly including the motor, the straight-teeth gear, first stirring frame, the ring gear, reation kettle, second stirring frame and connecting rod, the motor is located on the support chassis, motor output shaft one end hookup has the straight-teeth gear, the last rotation type of support chassis is connected with first stirring frame, first stirring frame top hookup has the ring gear, ring gear and straight-teeth gear meshing, the rotary type is connected with reation kettle on the first stirring frame, reation kettle with support chassis rigid coupling, the last rotation type of reation kettle is connected with second stirring frame, the last rotation type of second stirring frame is connected with the connecting rod, the connecting rod other end is connected with the straight-teeth gear rotary type.

Optionally, the pouring assembly comprises a clamping column, a collecting frame, a first support frame, a first pushing frame, a first spring, a grooving plate, a first sliding frame, a first connecting frame, a second spring and a heat insulation plate, the clamping column is connected with the top of the gear ring, a pair of collecting frames are slidably connected with the support chassis, the first support frame is arranged on the support chassis, the first pushing frame is slidably connected with the first supporting frame, the first spring is connected between the first pushing frame and the first support frame, the grooving plate is welded on the first pushing frame and is in contact with the first support frame, the first sliding frame is slidably connected with the support chassis, the first sliding frame is in limit fit with the grooving plate, a pair of first connecting frames is fixedly connected with the first sliding frame, the first connecting frame is in sliding fit with the collecting frame, the second spring is connected between the collecting frame and the first connecting frame, the heat insulation plate is connected with the support chassis, the insulation board is contacted with one of the collection frames.

Optionally, empty the control assembly including the swinging arms, spacing carriage, the third spring, fixed stopper and spacing slotting bracket, the rotation type is connected with a pair of swinging arms on the support chassis, the rotation type is connected with spacing carriage on the swinging arms, be connected with the third spring between swinging arms and the spacing carriage, a pair of fixed stopper of fixedly connected with on the support chassis, fixed stopper is connected with the swinging arms rotary type, fixed stopper with spacing carriage contact, the rotation type is connected with a pair of spacing slotting bracket on the support chassis, spacing slotting bracket contacts with the collection frame, spacing slotting bracket is with spacing cooperation of swinging arms.

Optionally, the pouring assembly comprises a second support frame, a slotting push frame, a limiting frame, a second connecting frame, a third connecting frame, a second sliding frame, a sliding block, a fourth spring, a supporting block, a slotting push frame, a fifth spring, a second push frame and a push frame, the top of the supporting underframe is connected with the pair of second support frames, the second support frame is connected with the slotting push frame in a sliding way, the limiting frame is in limit fit with the slotting push frame, one of the limiting slotting frames is connected with the second connecting frame, the other limiting slotting frame is connected with the third connecting frame, the supporting underframe is connected with the pair of second sliding frames in a sliding way, the second sliding frames are in sliding fit with the limiting frame, the supporting underframe is connected with the pair of sliding blocks in a sliding way, the sliding blocks are in sliding fit with the second sliding frames, and the fourth spring is connected between the sliding blocks and the second sliding frames, the top of the supporting underframe is connected with a supporting block, the supporting block is connected with a slotting pushing frame in a sliding mode, a fifth spring is connected between the slotting pushing frame and the supporting block, the supporting underframe is connected with a second pushing frame in a sliding mode, the second pushing frame is in limit fit with the slotting pushing frame, and the collecting frame is connected with the pushing frame in a sliding mode.

Optionally, the sealing assembly comprises a wedge-shaped pushing frame, a swinging plate and a torsion spring, the top of the pushing frame is connected with the wedge-shaped pushing frame, the supporting bottom frame is rotatably connected with a pair of swinging plates, the swinging plates are in contact with the wedge-shaped pushing frame, and the torsion spring is connected between the swinging plates and the supporting bottom frame.

The invention has the following advantages:

one of the push-out frames can push cold water on the push-out frame to flow upwards to the supporting bottom frame, so that the cooling speed of reactants in the reaction kettle can be increased, the working efficiency can be improved, and the effect of effectively increasing the cooling speed of the reactants in the reaction kettle is achieved.

The cold water in the supporting bottom frame can flow into the other collecting frame, and the hot water in one collecting frame can flow into the supporting bottom frame, so that the time required by heating can be shortened, the improvement of the working efficiency is facilitated, the energy can be saved, and the effect of effectively shortening the heating time and saving the energy can be achieved.

Drawings

Fig. 1 is a schematic perspective view of a first embodiment of the present invention.

Fig. 2 is a schematic perspective view of a second embodiment of the present invention.

FIG. 3 is a schematic view of a first partial body configuration of an agitated assembly according to the invention.

FIG. 4 is a schematic view of a second partially assembled body construction of an agitated assembly according to the invention.

Fig. 5 is a perspective view of the pouring assembly of the present invention.

Fig. 6 is a perspective view of the pour control assembly of the present invention.

FIG. 7 is a schematic view of a first partially assembled component of the pouring assembly of the present invention.

Fig. 8 is a schematic view of a second partially assembled body of the pouring assembly of the present invention.

Fig. 9 is a perspective view of the sealing assembly of the present invention.

The meaning of the reference symbols in the figures: 1: support chassis, 2: agitating assembly, 21: motor, 22: spur gear, 23: first agitator frame, 24: ring gear, 25: reaction kettle, 26: second agitator frame, 27: connecting rod, 3: pour out assembly, 31: a jamming column, 32: collection frame, 33: first support bracket, 34: first push frame, 35: first spring, 36: grooved plate, 37: first carriage, 38: first link frame, 39: second spring, 310: insulation board, 4: pour control assembly, 41: swing frame, 42: spacing carriage, 43: third spring, 44: fixed stopper, 45: spacing slotted frame, 5: pouring assembly, 51: second support, 52: slotting and pushing frame, 53: spacing, 54: second link, 55: third link, 56: second carriage, 561: slider, 562: fourth spring, 57: support block, 58: slotted push frame, 59: fifth spring, 510: second pushing frame, 5101: push-out frame, 6: sealing module, 61: wedge-shaped pushing frame, 62: swing plate, 63: a torsion spring.

Detailed Description

The standard parts used in the invention can be purchased from the market, the special-shaped parts can be customized according to the description and the description of the attached drawings, and the specific connection mode of each part adopts the conventional means of mature bolts, rivets, welding, sticking and the like in the prior art, and the detailed description is not repeated.

Example (b): the utility model provides a rotary type energy-saving hydrothermal reaction kettle, as shown in fig. 1-9, including supporting chassis 1, stir subassembly 2, pour subassembly 3, empty control assembly 4, pour subassembly 5 and airtight subassembly 6 into, stir subassembly 2 and locate on supporting chassis 1, stir subassembly 2 and be used for improving the reaction rate of the reactant in reation kettle 25, pour subassembly 3 and locate on supporting chassis 1, pour subassembly 3 and be arranged in pouring out the hot water in supporting chassis 1 and pour to one of them collection frame 32, empty control assembly 4 and locate on supporting chassis 1, pour subassembly 5 and be arranged in pouring into chassis 1 with cold water into, airtight subassembly 6 is located and is poured on subassembly 5.

The stirring component 2 comprises a motor 21, a straight gear 22, a first stirring frame 23, a gear ring 24, a reaction kettle 25, a second stirring frame 26 and a connecting rod 27, the motor 21 is arranged on the supporting base frame 1, the motor 21 is used for driving the straight gear 22 and the device on the straight gear 22 to slowly rotate reversely, one end of an output shaft of the motor 21 is connected with the straight gear 22, the straight gear 22 is used for driving the gear ring 24 and the device on the gear ring to slowly rotate reversely, the supporting base frame 1 is rotatably connected with the first stirring frame 23, the first stirring frame 23 is used for stirring hot water in the supporting base frame 1, the top of the first stirring frame 23 is connected with the gear ring 24, the gear ring 24 is meshed with the straight gear 22, the first stirring frame 23 is rotatably connected with the reaction kettle 25, the reaction kettle 25 is fixedly connected with the supporting base frame 1, the reaction kettle 25 is rotatably connected with the second stirring frame 26, the second stirring frame 26 is used for stirring reaction materials in the reaction kettle 25, the second stirring frame 26 is rotatably connected with a connecting rod 27, the second stirring frame 26 and the upper device thereof can be rotated by matching the straight gear 22 with the connecting rod 27, and the other end of the connecting rod 27 is rotatably connected with the straight gear 22.

The pouring assembly 3 comprises a clamping column 31, a collecting frame 32, a first supporting frame 33, a first pushing frame 34, a first spring 35, a slotted plate 36, a first sliding frame 37, a first connecting frame 38, a second spring 39 and an insulation board 310, the clamping column 31 is connected with the top of the gear ring 24, the clamping column 31 is used for pushing the first pushing frame 34 and the devices thereon to move, the supporting underframe 1 is slidably connected with a pair of collecting frames 32, the supporting underframe 1 is provided with a first supporting frame 33, the first supporting frame 33 is slidably connected with the first pushing frame 34, the first spring 35 is connected between the first pushing frame 34 and the first supporting frame 33, the first spring 35 is used for driving the first pushing frame 34 and the devices thereon to reset, the slotted plate 36 is welded on the first pushing frame 34, the slotted plate 36 is used for driving the first sliding frame 37 and the devices thereon to move downwards, the slotted plate 36 is in contact with the first supporting frame 33, the supporting underframe 1 is slidably connected with the first sliding frame 37, first carriage 37 and the spacing cooperation of fluting board 36, a pair of first link 38 of fixedly connected with on the first carriage 37, first link 38 is used for driving one of them collection frame 32 and the device downstream that goes up, first link 38 and collection frame 32 sliding type cooperation collect and be connected with second spring 39 between frame 32 and the first link 38, the hookup has heated board 310 on the support chassis 1, through heated board 310, can keep warm to the hot water that arrives in one of them collection frame 32, heated board 310 and one of them collection frame 32 contact.

The dumping control assembly 4 comprises a swing frame 41, a limiting sliding frame 42, a third spring 43, a fixed limiting block 44 and a limiting slotting frame 45, a pair of swing frames 41 are connected to the support underframe 1 in a rotating mode, the limiting sliding frame 42 is connected to the swing frame 41 in a sliding mode, the third spring 43 is connected between the swing frame 41 and the limiting sliding frame 42, a pair of fixed limiting blocks 44 are fixedly connected to the support underframe 1, the fixed limiting blocks 44 are used for clamping the limiting sliding frame 42, the fixed limiting blocks 44 are connected with the swing frame 41 in a rotating mode, the fixed limiting blocks 44 are in contact with the limiting sliding frame 42, a pair of limiting slotting frames 45 are connected to the support underframe 1 in a sliding mode, the limiting slotting frames 45 are used for blocking the collection frame 32, the limiting slotting frames 45 are in contact with the collection frame 32, and the limiting slotting frames 45 are in limiting fit with the swing frames 41.

The pouring component 5 comprises a second support frame 51, a slotted push frame 52, a limiting frame 53, a second connecting frame 54, a third connecting frame 55, a second sliding frame 56, a sliding block 561, a fourth spring 562, a supporting block 57, a slotted push frame 58, a fifth spring 59, a second push frame 510 and a push frame 5101, the top of the support chassis 1 is connected with a pair of second support frames 51, the slotted push frame 52 is connected on the second support frames 51 in a sliding manner, the slotted push frame 52 is used for driving the limiting frame 53 and the upper device thereof to move, the limiting frame 53 is connected on the second support frames 51 in a sliding manner, the limiting frame 53 is matched with the slotted push frame 52 in a limiting manner, one limiting slotted frame 45 is connected with the second connecting frame 54 in a connecting manner, the second connecting frame 54 is used for supporting the slotted push frame 52, the other limiting slotted frame 45 is connected with the third connecting frame 55 in a connecting manner, the support chassis 1 is connected with a pair of second sliding frames 56, the second sliding frame 56 is used for driving the pushing frame 5101 and the upper device thereof to move upwards, the second sliding frame 56 is in sliding fit with the limiting frame 53, the supporting chassis 1 is connected with a pair of sliding blocks 561 in sliding fit, the sliding blocks 561 are in sliding fit with the second sliding frame 56, a fourth spring 562 is connected between the sliding blocks 561 and the second sliding frame 56 and is used for driving the second sliding frame 56 to reset, the top of the supporting chassis 1 is connected with a supporting block 57, the supporting block 57 is connected with a slotted pushing frame 58 in sliding fit, the slotted pushing frame 58 is used for driving the second pushing frame 510 to move upwards, a fifth spring 59 is connected between the slotted pushing frame 58 and the supporting block 57 and is used for driving the slotted pushing frame 58 to reset, the supporting chassis 1 is connected with the second pushing frame 510 in sliding fit, the second pushing frame 510 is used for pushing one of the second sliding frames 56 to move upwards, and the second pushing frame 510 is in limiting fit with the slotted pushing frame 58, a push-out frame 5101 is slidably connected to the collection frame 32, and the push-out frame 5101 is used for pushing cold water thereon to flow upward into the support chassis 1.

The sealing assembly 6 comprises a wedge-shaped pushing frame 61, a swinging plate 62 and a torsion spring 63, the top of the pushing frame 5101 is connected with the wedge-shaped pushing frame 61, the wedge-shaped pushing frame 61 is used for pushing the swinging plate 62 to swing, the supporting bottom frame 1 is rotatably connected with a pair of swinging plates 62, the swinging plates 62 are in contact with the wedge-shaped pushing frame 61, the torsion spring 63 is connected between the swinging plates 62 and the supporting bottom frame 1, and the torsion spring 63 is used for driving the swinging plates 62 to reset.

Firstly, reaction substances are filled in a reaction kettle 25, hot water is filled in a supporting chassis 1, half of cold water is filled in a collecting frame 32 at the side far away from a motor 21, the motor 21 is manually controlled to start, so that the straight gear 22 and the device thereon are slowly reversed, the straight gear 22 drives the gear ring 24 and the device thereon to be slowly reversed, thereby the first stirring frame 23 stirs the hot water in the supporting chassis 1, thereby accelerating the heat conduction rate of the hot water in the supporting chassis 1 to the reaction kettle 25, and simultaneously through the matching of the straight gear 22 and the connecting rod 27, the second stirring frame 26 and the device thereon are rotated, so that the second stirring frame 26 stirs the reaction materials in the reaction kettle 25, thereby improving the reaction rate of the reaction substances in the reaction kettle 25 and achieving the effect of effectively improving the reaction rate of the reaction substances in the reaction kettle 25 to save energy.

When the reaction material in the reaction kettle 25 needs to be cooled, one of the limit sliding frames 42 is manually pulled to move in the direction away from the supporting chassis 1, one of the third springs 43 is compressed, so that one of the fixed limit blocks 44 does not block one of the limit sliding frames 42, then one of the limit sliding frames 42 is manually rotated according to the degree of cooling of the reaction material in the reaction kettle 25, so that one of the swing frames 41 and the devices thereon move downwards, one of the limit sliding frames 42 is pushed to move in the direction close to the supporting chassis 1, one of the third springs 43 is reset, so that one of the fixed limit blocks 44 block one of the limit sliding frames 42, one of the limit open slot frames 45 does not block one of the collection frames 32, then the clamping column 31 contacts with the first pushing frame 34, and the clamping column 31 pushes the first pushing frame 34 and the devices thereon to move, the first springs 35 are stretched accordingly, the slotted plate 36 drives the first sliding frame 37 and the devices thereon to move downwards, so that one of the first connecting frames 38 can drive one of the collecting frames 32 and the devices thereon to move downwards, one of the second springs 39 is not compressed, the other second spring 39 is compressed, the other first connecting frame 38 cannot drive the other collecting frame 32 and the devices thereon to move downwards, when one of the collecting frames 32 is in contact with one of the spacing slotted frames 45, one of the second springs 39 is also compressed accordingly, during the downward movement of one of the collecting frames 32 and the devices thereon, one of the collecting frames 32 no longer blocks one of the openings on the supporting chassis 1, so that the hot water in the supporting chassis 1 flows into one of the collecting frames 32, so that half of the hot water in one of the collecting frames 32 flows through the heat-insulating plate 310, and the hot water flowing into one of the collecting frames 32 can be insulated, is convenient for secondary use, is beneficial to saving energy, can cut off the heat source of the reaction of the reactants in the reaction kettle 25, and is beneficial to cooling the reactants in the reaction kettle 25.

After the ring gear 24 and the devices thereon are reversed by a quarter of a turn, the clamping column 31 does not push the first pushing frame 34 any more, the first pushing frame 34 and the devices thereon are reset by the resetting action of the first spring 35, the slotted plate 36 drives the first sliding frame 37 and the devices thereon to be reset, and the second spring 39 is reset accordingly.

In the process of moving down one of the limiting slotted frames 45 and the upper device thereof, the second connecting frame 54 no longer supports the slotted pushing frame 52 on the side far from the motor 21, the slotted pushing frame 52 on the side far from the motor 21 moves down, and the slotted pushing frame 52 on the side far from the motor 21 drives the limiting frame 53 on the side far from the motor 21 and the upper device thereof to move towards the direction close to the other collecting frame 32.

Then the clamp column 31 pushes the slotted pushing frame 58 to move, the fifth spring 59 is compressed, the slotted pushing frame 58 drives the second pushing frame 510 to move upward, the second pushing frame 510 pushes one of the second sliding frames 56 to move upward, a fourth spring 562 is stretched, a second sliding rack 56 pushes one of the pushing racks 5101 and the device thereon to move upwards, in the process, one of the wedge-shaped pushing racks 61 pushes one of the swinging plates 62 to swing, one of the torsion springs 63 is then compressed, so that one of the swing plates 62 no longer blocks one of the openings in the support chassis 1, meanwhile, one of the pushing-out frames 5101 pushes the cold water thereon to flow upward into the supporting base frame 1, so that the cooling speed of the reactant in the reaction kettle 25 can be increased, and further, the working efficiency can be improved, and the effect of effectively accelerating the cooling speed of the reactants in the reaction kettle 25 is achieved.

When the clamp column 31 pushes the slot pushing frame 58 to move to the maximum distance, half of the cold water in the other collecting frame 32 flows into the supporting chassis 1, one of the limiting sliding frames 42 is manually pulled to separate from one of the fixed limiting blocks 44, one of the third springs 43 is compressed, one of the limiting sliding frames 42 is rotated to reset one of the swinging frames 41 and the devices thereon, one of the limiting sliding frames 42 is released to clamp one of the limiting sliding frames 42 again, one of the third springs 43 is reset, when one of the swinging frames 41 and the devices thereon is reset, one of the limiting open sliding frames 45 and the devices thereon are reset, the second connecting frame 54 pushes the slot pushing frame 52 to reset upwards, the slot pushing frame 52 drives the limiting frame 53 and the devices thereon away from the motor 21 to reset, one of the second sliding frames 56 is reset under the reset action of one of the fourth springs 562, one of the pushing-out frames 5101 is reset under the action of gravity, one of the swinging plates 62 is reset under the reset action of one of the torsion springs 63, the clamping column 31 does not push the slotted pushing frame 58 any more in the process of continuing to rotate the gear ring 24 and the upper device thereof, the slotted pushing frame 58 and the upper device thereof are reset under the reset action of the fifth spring 59, and the second pushing frame 510 is reset accordingly.

When reation kettle 25 heats once more, another spacing carriage 42 of manual pulling and the device motion on it, and in the same way, cold water in the support chassis 1 can flow to another collection frame 32, hot water in one of them collection frame 32 then can flow to support chassis 1, the rethread external heating equipment continues the heating to the hot water in the support chassis 1, thereby can shorten the required time of heating, be favorable to improving work efficiency, and then can the energy saving, reached and to shorten the effect of heating time with the energy saving effectively.

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

Claims

1. The utility model provides a rotary type energy-saving hydrothermal reation kettle, characterized by: including supporting the chassis, stirring the subassembly, pouring the subassembly, empting the control assembly, pouring the subassembly and airtight subassembly into, stir the subassembly and locate on supporting the chassis, pour the subassembly and locate on supporting the chassis, empty the control assembly and locate on supporting the chassis, pour the subassembly and locate on supporting the chassis, airtight subassembly is located and is poured the subassembly into on.

2. A rotary energy-saving hydrothermal reaction kettle according to claim 1, wherein: mix the subassembly including the motor, the straight-teeth gear, first stirring frame, the ring gear, reation kettle, second stirring frame and connecting rod, the motor is located on supporting the chassis, motor output shaft one end hookup has the straight-teeth gear, the last rotary type of supporting the chassis is connected with first stirring frame, first stirring frame top hookup has the ring gear, ring gear and straight-teeth gear meshing, first stirring frame is gone up the rotary type and is connected with reation kettle, reation kettle and supporting the chassis rigid coupling, the last rotary type of reation kettle is connected with second stirring frame, the last rotary type of second stirring frame is connected with the connecting rod, the connecting rod other end is connected with the straight-teeth gear rotary type.

3. A rotary energy-saving hydrothermal reaction kettle according to claim 2, wherein: the pouring component comprises a clamping column, a collecting frame, a first supporting frame, a first pushing frame and a first spring, the groove plate, first carriage, first link, second spring and heated board, the hookup of ring gear top has the card post, it has a pair of collection frame to slide to be connected with on the support chassis, be equipped with first support frame on the support chassis, slide to be connected with first propelling movement frame on the first support frame, be connected with first spring between first propelling movement frame and the first support frame, the welding has the groove plate on the first propelling movement frame, the groove plate contacts with first support frame, slide to be connected with first carriage on the support chassis, first carriage and the spacing cooperation of groove plate, a pair of first link of fixedly connected with on the first carriage, first link and the cooperation of collection frame slidingtype, be connected with the second spring between collection frame and the first link, the hookup has the heated board on the support chassis, the heated board contacts with one of them collection frame.

4. A rotary energy-saving hydrothermal reaction kettle according to claim 3, wherein: toppling control assembly is including the swinging bracket, spacing carriage, the third spring, fixed stopper and spacing slotting machine, the rotation type is connected with a pair of swinging bracket on the support chassis, the rotation type is connected with spacing carriage on the swinging bracket, be connected with the third spring between swinging bracket and the spacing carriage, a pair of fixed stopper of fixedly connected with on the support chassis, fixed stopper is connected with the swinging bracket rotary type, fixed stopper with spacing carriage contact, the rotation type is connected with a pair of spacing slotting machine on the support chassis, spacing slotting machine contacts with the collection frame, spacing slotting machine and the spacing cooperation of swinging bracket.

5. A rotary energy-saving hydrothermal reaction kettle according to claim 4, wherein: the pouring assembly comprises a second support frame, a slotting push frame, a limiting frame, a second connecting frame, a third connecting frame, a second sliding frame, a sliding block, a fourth spring, a supporting block, a slotting push frame, a fifth spring, a second push frame and a push frame, wherein the top of the supporting underframe is connected with a pair of second support frames, the second support frames are connected with the slotting push frame in a sliding way, the limiting frames are connected with the limiting frame in a sliding way, the limiting frames are in limit fit with the slotting push frame, one limiting slotting frame is connected with the second connecting frame, the other limiting slotting frame is connected with the third connecting frame, the supporting underframe is connected with a pair of second sliding frames in a sliding way, the second sliding frames are in sliding fit with the limiting frames, the supporting underframe is connected with a pair of sliding blocks in a sliding way, the sliding block is in sliding fit with the second sliding frame, and the fourth spring is connected between the sliding block and the second sliding frame, the top of the supporting underframe is connected with a supporting block, the supporting block is connected with a slotting pushing frame in a sliding mode, a fifth spring is connected between the slotting pushing frame and the supporting block, the supporting underframe is connected with a second pushing frame in a sliding mode, the second pushing frame is in limit fit with the slotting pushing frame, and the collecting frame is connected with the pushing frame in a sliding mode.

6. A rotary energy-saving hydrothermal reaction kettle according to claim 5, wherein: the closed assembly comprises a wedge-shaped pushing frame, a swinging plate and a torsion spring, the top of the pushing frame is connected with the wedge-shaped pushing frame, the supporting bottom frame is rotatably connected with a pair of swinging plates, the swinging plates are in contact with the wedge-shaped pushing frame, and the torsion spring is connected between the swinging plates and the supporting bottom frame.