CN113996257A

CN113996257A - Reation kettle with adversion rapid cooling function

Info

Publication number: CN113996257A
Application number: CN202111439761.3A
Authority: CN
Inventors: 方子祥
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-11-30
Filing date: 2021-11-30
Publication date: 2022-02-01

Abstract

The invention discloses a reaction kettle with an inward rotation rapid cooling function, which comprises a kettle body, wherein a heat energy cylinder, a heat exchange pipe, a transmission sleeve and an annular driving disc are arranged at the bottom of the kettle body. In the invention, the bottom of the kettle body is provided with the heat energy cylinder, the bottom of the kettle body is provided with the rotary sleeve, the rotary sleeve is rotatably connected with the heat exchange tube, one end of the heat exchange tube extends to the inner cavity of the kettle body, the top of the heat exchange tube is connected with the heat dissipation tube through the suspension tube, the heat exchange tube, the heat dissipation tube and the suspension tube form a Z-shaped structure, the heat exchange tube, the heat dissipation tube and the suspension tube are internally provided with a flow channel, and the flow channel is used for flowing cooling water.

Description

Reation kettle with adversion rapid cooling function

Technical Field

The invention relates to the technical field of cooling of reaction kettles, in particular to a reaction kettle with an inward-rotation rapid cooling function.

Background

The general understanding of the reactor is that the physical or chemical reaction vessel is provided, the heating, evaporation, cooling and low and high speed mixing functions required by the process are realized by the structural design and parameter configuration of the vessel, after the chemical reaction vessel is used for processing the material, the material is too high in temperature and is not convenient to take out, the reaction vessel needs to be cooled firstly, when the chemical reaction vessel is cooled, the reaction vessel is cooled by circulating cooling water more frequently, but the cooling is slow in this way, the efficiency is low, and the processing work efficiency is influenced, the reaction vessel which is internally connected with cooling water in a stirring device in the vessel body is available in the market, the stirring device needs to be controlled to rotate during the cooling treatment, because the cooling water flowing through the stirring device generates centrifugal force when rotating, the centrifugal force can influence the flowing speed of the water body, and further the quick circulation of the cooling water is difficult to realize, therefore, the cooling effect is poor.

Therefore, the invention provides a reaction kettle with an inward-rotation rapid cooling function.

Disclosure of Invention

The invention aims to: in order to solve the problems mentioned in the background art, a reaction kettle with an inward-rotation rapid cooling function is provided.

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

a reaction kettle with an inward rotation rapid cooling function comprises a kettle body, wherein a heat energy cylinder, a heat exchange pipe, a transmission sleeve and an annular driving disc are arranged at the bottom of the kettle body, three positioning sleeves which are uniformly distributed in the circumferential direction and are communicated with an inner cavity are arranged at the bottom of the kettle body, the axis of each positioning sleeve is parallel to that of the kettle body, a rotating sleeve is sleeved outside and close to the bottom of each heat exchange pipe, a torsion spring is arranged between each rotating sleeve and each heat exchange pipe, each rotating sleeve is sleeved in each positioning sleeve in a rotating fit mode, a telescopic rod is fixedly connected to the outer wall of each rotating sleeve and close to the bottom of each rotating sleeve, a hanging sleeve which is distributed in the same axial direction is fixedly arranged at the bottom of the kettle body, each transmission sleeve is sleeved outside each positioning sleeve and is rotatably connected, three poking rods which are uniformly distributed in the circumferential direction are fixedly connected to the outer wall of each transmission sleeve, and the free ends of the poking rods are hinged to the free ends of the telescopic rods, the annular driving disc is sleeved outside the transmission sleeve and is in rotary connection, the peripheral wall of the annular driving disc is fixedly connected with three arc-shaped bulges which are uniformly distributed in the circumferential direction, the outer wall of the heat exchange tube is fixedly provided with an arm plate positioned below the rotary sleeve, the free end of the arm plate is matched with the peripheral wall of the annular driving disc, the top of the heat exchange tube is fixedly connected with a suspension tube positioned in the kettle body, the free end of the suspension pipe is fixedly connected with a radiating pipe, the heat exchange pipe is internally provided with a water channel, the bottom of the heat exchange pipe is fixedly provided with a water inlet pipe and a water outlet pipe, the heat energy cylinder is fixedly connected with the bottom of the suspension sleeve, when the heat energy cylinder returns to the journey, the cooling tube is close to the inner wall of the cauldron body this moment, and annular driving disk is rotatory when not contacting with the arm board, when the heat energy cylinder pushed away the journey, the axis that the cooling tube was close to the cauldron body this moment, and annular driving disk is rotatory when contacting with the arm board extrusion.

As a further description of the above technical solution:

the heat energy cylinder comprises a cylinder body and a piston which is located in the cylinder body and is in up-down sliding fit, one end of a plug rod on the piston extends out of the bottom of the cylinder body and is fixedly connected with a supporting plate, a free end of the supporting plate is fixedly connected with a driving plate which is distributed in parallel with the axis of a transmission sleeve, the outer wall of the transmission sleeve is provided with a chute, and one side of the driving plate is fixedly provided with a connecting shaft in sliding fit with the chute.

As a further description of the above technical solution:

the heat energy cylinder further comprises a reset spring, a thermal expansion cavity communicated with the piston cavity is formed in the top in the cylinder body, a heat conducting rod is fixedly arranged on the outer wall of the cylinder body, one end of the heat conducting rod is fixedly connected with the bottom of the kettle body, the thermal expansion cavity at the other end of the kettle body is communicated with the thermal expansion cavity, a valve control water pipe communicated with the thermal expansion cavity is fixedly arranged on the outer wall of the cylinder body, and the reset spring is located on one side of the piston in the cylinder body.

As a further description of the above technical solution:

the outer wall of cooling tube is fixed and is provided with the heat pipe, and this heat pipe is along the length direction evenly distributed of cooling tube.

As a further description of the above technical solution:

the hydraulic turbine is fixedly arranged on the outer wall of the transmission sleeve and provided with an output gear, one side of the annular driving disc is fixedly provided with a driving gear ring which is coaxially distributed, and the driving gear ring is meshed with the output gear.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. in the invention, a heat energy cylinder is arranged at the bottom of a kettle body, a rotating sleeve is arranged at the bottom of the kettle body, a heat exchange tube is rotatably connected in the rotating sleeve, one end of the heat exchange tube extends to an inner cavity of the kettle body, the top of the heat exchange tube is connected with a heat dissipation tube through a suspension tube, the heat exchange tube, the heat dissipation tube and the suspension tube form a Z-shaped structure, a flow channel is arranged in the heat exchange tube, the heat dissipation tube and the suspension tube, and cooling water flows through the flow channel, wherein the heat energy cylinder is used for controlling the heat exchange tube to rotate so that the heat dissipation tube is close to the middle position in the kettle body, an annular driving disc is arranged, and the annular driving disc can control the heat exchange tube to swing in small amplitude to enable the heat dissipation tube to swing in liquid, so that the heat dissipation efficiency can be greatly improved, and interference on a stirring device can not be caused.

2. According to the invention, the heat energy cylinder also comprises a return spring, a thermal expansion cavity communicated with the piston cavity is arranged at the top in the cylinder body, a heat conducting rod is fixedly arranged on the outer wall of the cylinder body, one end of the heat conducting rod is fixedly connected with the bottom of the kettle body, the thermal expansion cavity at the other end is communicated with the thermal expansion cavity, the heat conducting rod is used for conducting heat at the bottom of the cylinder body into the expansion cavity, a valve control water pipe communicated with the thermal expansion cavity is also fixedly arranged on the outer wall of the cylinder body, one end of the valve control water pipe is connected with an external water pipe, the valve control water pipe is started, a water body enters the thermal expansion cavity, the water body expands at high temperature to generate steam, and the steam pressure can push the piston outwards, so that the pushing action of the heat energy cylinder is controlled through heat energy at the bottom of the kettle body, the control is convenient and energy-saving, and the function of indicating the whole temperature height in the kettle body can be achieved.

3. According to the hydraulic energy-saving hydraulic turbine, the hydraulic turbine is arranged and fixedly arranged on the outer wall of the transmission sleeve, the output gear is arranged on the hydraulic turbine, the driving gear ring which is coaxially distributed is fixedly arranged on one side of the annular driving disc, the driving gear ring is meshed with the output gear, a water inlet of the hydraulic turbine is connected with external cooling water, a water outlet of the hydraulic turbine is connected with the water inlet pipe through a pipeline, the annular driving disc is driven to rotate through hydrodynamic force, and the hydraulic energy-saving hydraulic turbine has an energy-saving effect.

Drawings

FIG. 1 is a schematic structural diagram of a reaction kettle with an inward-rotation rapid cooling function, which is provided by the invention, wherein a kettle body, a heat energy cylinder, a heat exchange tube, a transmission sleeve, an annular driving disc, a rotating sleeve and a water turbine are matched;

FIG. 2 is a schematic structural diagram of a reaction vessel with an inward-rotation rapid cooling function according to the present invention, as shown in the bottom view of FIG. 1;

FIG. 3 is a schematic structural diagram of detailed connections of a heat exchange tube, a transmission sleeve, an annular driving disc, a rotating sleeve and a water turbine of the reaction kettle with an inward rotation and rapid cooling function, which is provided by the invention;

fig. 4 is a schematic structural diagram of connection between a heat energy cylinder and a transmission sleeve of a reaction kettle with an inward-rotation rapid cooling function according to the present invention.

Illustration of the drawings:

1. a kettle body; 11. a positioning sleeve; 12. hanging a sleeve; 2. a heat energy cylinder; 21. a cylinder body; 211. A thermal expansion chamber; 212. a heat conducting rod; 213. valve control water pipe; 22. a piston; 221. a supporting plate; 2211. a drive plate; 22111. a connecting shaft; 23. a return spring; 3. a heat exchange tube; 31. An arm plate; 32. a hanging tube; 321. a radiating pipe; 3211. a heat conducting pipe; 33. a water inlet pipe; 34. A water outlet pipe; 4. a transmission sleeve; 41. a deflector rod; 42. a chute; 5. an annular drive disc; 51. an arc-shaped bulge; 52. a drive gear ring; 6. rotating the sleeve; 61. a telescopic rod; 7. a water turbine; 71. an output gear.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all 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.

Example 1

Referring to fig. 1-4, a reaction kettle with an inward rotation rapid cooling function comprises a kettle body 1, a heat energy cylinder 2, a heat exchange pipe 3, a transmission sleeve 4 and an annular driving disk 5 are arranged at the bottom of the kettle body 1, the heat exchange pipe 3 is used for exchanging heat with liquid in the kettle body 1, a cooling water body flows through the heat exchange pipe 3, the cooling water body carries out heat, three positioning sleeves 11 which are uniformly distributed in the circumferential direction and communicated with an inner cavity are arranged at the bottom of the kettle body 1, the axis of each positioning sleeve 11 is parallel to the axis of the kettle body 1, a rotating sleeve 6 is sleeved outside the heat exchange pipe 3 and close to the bottom, a torsion spring is arranged between the rotating sleeve 6 and the heat exchange pipe 3, the rotating sleeve 6 and the heat exchange pipe 3 are elastically fixed in the circumferential direction under the action of the torsion spring, the rotating sleeve 6 is sleeved in the positioning sleeves 11 and is in a rotating fit, a telescopic rod 61 is fixedly connected to the outer wall of the rotating sleeve 6 and close to the bottom, the bottom of the kettle body 1 is fixedly provided with a suspension sleeve 12 which is coaxially distributed, a transmission sleeve 4 is sleeved outside a positioning sleeve 11 and is in rotary connection, the outer wall of the transmission sleeve 4 is fixedly connected with three shifting rods 41 which are uniformly distributed in the circumferential direction, the free end of each shifting rod 41 is hinged with the free end of each telescopic rod 61, the transmission sleeve 4 can drive the rotation sleeve 6 to rotate through each telescopic rod 61 when rotating, the heat exchange tubes 3 synchronously rotate under the action of a torsion spring, an annular driving disc 5 is sleeved outside the transmission sleeve 4 and is in rotary connection, the outer circumferential wall of the annular driving disc 5 is fixedly connected with three arc-shaped bulges 51 which are uniformly distributed in the circumferential direction, the outer wall of each heat exchange tube 3 is fixedly provided with an arm plate 31 which is positioned below the rotation sleeve 6, the free ends of the arm plates 31 are matched with the outer circumferential wall of the annular driving disc 5, and the arm plates 31 can drive the heat exchange tubes 3 to circumferentially swing relative to the rotation sleeve 6 under the stirring of the arc-shaped bulges 51, the top of the heat exchange tube 3 is fixedly connected with a suspension tube 32 positioned in the kettle body 1, the free end of the suspension tube 32 is fixedly connected with a heat radiation tube 321, the heat exchange tube 3, the heat radiation tube 321 and the suspension tube 32 form a Z-shaped structure, a water channel is arranged in the heat exchange tube 3, and the bottom of the heat exchange tube 3 is fixedly provided with a water inlet tube 33 and a water outlet tube 34, namely, cold water enters a water channel from the water inlet tube 33, then passes through the heat radiation tube 321 and flows back to the water outlet tube 34, the heat energy cylinder 2 is fixedly connected with the bottom of the suspension sleeve 12, concretely, the heat energy cylinder 2 comprises a cylinder body 21 and a piston 22 which is positioned in the cylinder body 21 and is in up-down sliding fit, one end of a plug rod 22 on the piston 22 extends out of the bottom of the cylinder body 21 and is fixedly connected with a supporting plate 221, the free end of the supporting plate 221 is fixedly connected with a driving plate 2211 which is distributed in parallel with the axis of the transmission sleeve 4, the outer wall of the transmission sleeve 4 is provided with an inclined groove 42, the chute 42 is a guiding slot structure with a spiral angle, one side of the driving plate 2211 is fixedly provided with a connecting shaft 22111 in sliding fit with the chute 42, when the heat energy cylinder 2 returns, the heat dissipation pipe 321 is close to the inner wall of the kettle body 1 at the moment, the annular driving plate 5 rotates without contacting with the arm plate 31, when the heat energy cylinder 2 pushes away, the heat dissipation pipe 321 is close to the axis of the kettle body 1 at the moment, the annular driving plate 5 rotates while being in extrusion contact with the arm plate 31, the heat dissipation pipe 321 is parallel to the axis of the kettle body 1, wherein the outer wall of the heat dissipation pipe 321 is fixedly provided with a heat conduction pipe 3211, the heat conduction pipe 3211 is used for increasing the contact area with the liquid in the kettle body 1, the heat conduction pipe 3211 is uniformly distributed along the length direction of the heat dissipation pipe 321, in conclusion, the heat dissipation pipe 321 is conveyed to the position, close to the middle of the liquid in the kettle body 1, the heat exchange pipe 3211 can be driven by controlling the swinging of the heat dissipation pipe 321, so as to swing at a small degree, thereby facilitating the heat in the liquid in the kettle body Discharge, have rapid cooling's effect, this device can not cause the interference to agitating unit moreover.

Example 2

Referring to fig. 4, the difference from embodiment 1 is that the thermal energy cylinder 2 further includes a return spring 23, the top of the cylinder 21 is provided with a thermal expansion cavity 211 communicated with the piston cavity, the outer wall of the cylinder 21 is fixedly provided with a heat conducting rod 212, one end of the heat conducting rod 212 is fixedly connected with the bottom of the kettle 1 and the other end of the thermal expansion cavity 211 is communicated, the heat conducting rod 212 is used for conducting the heat at the bottom of the cylinder 21 into the thermal expansion cavity 211, the outer wall of the cylinder 21 is further fixedly provided with a valve-controlled water pipe 213 communicated with the thermal expansion cavity 211, one end of the valve-controlled water pipe 213 is connected with an external water pipe, the valve-controlled water pipe 213 is opened, a water body enters the thermal expansion cavity 211, the water body expands at high temperature to generate steam, the steam pressure can push the piston 22 out, the return spring 23 is located at one side of the piston 22 in the cylinder 21, after the steam pressure is reduced, under the action of the return spring 23, the piston 22 is reset, and the reduction of the steam pressure indicates that the temperature of the liquid in the kettle body is reduced to a certain temperature, so that the function of indicating the temperature in the kettle body is achieved.

Example 3

Referring to fig. 4, the difference from embodiment 1 is that the hydraulic turbine 7 is further included, the hydraulic turbine 7 is fixedly disposed on the outer wall of the transmission sleeve 4 and provided with an output gear 71, one side of the annular driving disk 5 is fixedly provided with a driving ring gear 52 coaxially distributed, the driving ring gear 52 is engaged with the output gear 71, a water inlet of the hydraulic turbine 7 is connected with external cooling water, and a water outlet of the hydraulic turbine 7 is connected with the water inlet pipe 33 through a pipeline, so that the hydrodynamic driving of the annular driving disk 5 is realized, and the energy-saving effect is achieved.

The working principle is as follows: when the rapid cooling device is used, when the liquid in the kettle body 1 needs to be rapidly cooled after the reaction is finished, the control valve control water pipe 213 is opened, the water body enters the high-temperature thermal expansion cavity 211, then the valve control water pipe 213 is closed, the water body in the thermal expansion cavity 211 is vaporized to generate high pressure, the high pressure pushes the piston 22 to move outwards, the return spring 23 is compressed, the drive plate 2211 moves downwards, the connecting shaft 22111 slides in the inclined groove 42, the transmission sleeve 4 rotates at the moment, the poking rod 41 drives the telescopic rod 61 to swing, the telescopic rod 61 extends out to compensate, meanwhile, the rotary sleeve 6 swings to drive the radiating pipe 321 to move towards the middle position in the kettle body 1 due to the position close to the inner peripheral wall of the kettle body 1, the movement mode does not cause interference on the stirring device, at the moment, the cooling water is controlled to enter the water turbine 7, the water body flowing through the water turbine 7 enters the water inlet pipe 33 of the heat exchange pipe 3 through the pipeline, and then enters the radiating pipe 321 and the heat conduction pipe 3211, then converge to outlet pipe 34, with outlet pipe 34 and outside circulation pipeline switch-on, realize the heat dissipation to the internal water body middle part of cauldron, output gear 71 on hydraulic turbine 7 rotates simultaneously and drives drive ring gear 52 rotatory, and then annular driving disk 5 is rotatory, and annular driving disk 5 rotatory in-process, arc arch 51 and arm plate 31 contact, can drive hot exchange pipe 3 swing, can realize the circulation swing under the effect of torsional spring, increase coverage.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention should be covered by the scope of the present invention.

Claims

1. The utility model provides a reation kettle with adversion rapid cooling function, includes the cauldron body (1), its characterized in that, the bottom of the cauldron body (1) is provided with heat energy cylinder (2), hot exchange pipe (3), transmission cover (4) and annular driving-disc (5), the position sleeve (11) that just communicates the inner chamber of three circumference evenly distributed is seted up to the bottom of the cauldron body (1), and the axis of this position sleeve (11) is parallel with the axis of the cauldron body (1), the outside of hot exchange pipe (3) just is close to the bottom cover and is equipped with commentaries on classics cover (6), is provided with the torsional spring between this commentaries on classics cover (6) and hot exchange pipe (3), commentaries on classics cover (6) cover is established in position sleeve (11) and is normal running fit, the outer wall of commentaries on classics cover (6) just is close to bottom fixedly connected with telescopic link (61), the bottom of the cauldron body (1) is fixed to be provided with axle center distribution hang cover (12), the transmission sleeve (4) is sleeved outside the positioning sleeve (11) and is in rotary connection, the outer wall of the transmission sleeve (4) is fixedly connected with three shifting rods (41) which are uniformly distributed in the circumferential direction, the free end of each shifting rod (41) is hinged with the free end of each telescopic rod (61), the annular driving disk (5) is sleeved outside the transmission sleeve (4) and is in rotary connection, the peripheral wall of each annular driving disk (5) is fixedly connected with three arc-shaped bulges (51) which are uniformly distributed in the circumferential direction, the outer wall of each heat exchange tube (3) is fixedly provided with an arm plate (31) positioned below the corresponding rotary sleeve (6), the free end of each arm plate (31) is matched with the peripheral wall of each annular driving disk (5) for use, the top of each heat exchange tube (3) is fixedly connected with a suspension tube (32) positioned in the kettle body (1), and the free end of each suspension tube (32) is fixedly connected with a radiating tube (321), be provided with water course and fixed inlet tube (33) and outlet pipe (34) that are provided with in heat exchange tube (3) bottom, heat energy cylinder (2) fixed connection is in the bottom of hanging cover (12), when heat energy cylinder (2) return stroke, the inner wall that the cauldron body (1) was close to in cooling tube (321) this moment, and annular driving dish (5) are rotatory when not contacting with arm board (31), when heat energy cylinder (2) push away the journey, the axis that the cauldron body (1) was close to in cooling tube (321) this moment, when annular driving dish (5) are rotatory with arm board (31) extrusion contact.

2. The reaction kettle with the function of quickly cooling by inward rotation according to claim 1, wherein the heat energy cylinder (2) comprises a cylinder body (21) and a piston (22) which is positioned in the cylinder body (21) and is in up-down sliding fit, one end of a plug rod (22) on the piston (22) extends out of the bottom of the cylinder body (21) and is fixedly connected with a supporting plate (221), a free end of the supporting plate (221) is fixedly connected with a driving plate (2211) which is distributed in parallel with the axis of the driving sleeve (4), the outer wall of the driving sleeve (4) is provided with a chute (42), and one side of the driving plate (2211) is fixedly provided with a connecting shaft (22111) which is in sliding fit with the chute (42).

3. The reaction kettle with the function of quickly cooling by inward turning according to claim 2, wherein the heat energy cylinder (2) further comprises a return spring (23), a heat expansion cavity (211) communicated with the piston cavity is arranged at the top in the cylinder body (21), a heat conducting rod (212) is fixedly arranged on the outer wall of the cylinder body (21), one end of the heat conducting rod (212) is fixedly connected with the bottom of the kettle body (1) and the other end of the heat expansion cavity (211) is communicated, a valve-controlled water pipe (213) communicated with the heat expansion cavity (211) is further fixedly arranged on the outer wall of the cylinder body (21), and the return spring (23) is positioned at one side of the piston (22) in the cylinder body (21).

4. The reaction kettle with an inward turning rapid cooling function as claimed in claim 2, wherein the heat pipe (3211) is fixedly disposed on the outer wall of the heat pipe (321), and the heat pipe (3211) is uniformly distributed along the length direction of the heat pipe (321).

5. The reaction kettle with the function of quickly reducing the temperature through inward rotation according to claim 4, further comprising a water turbine (7), wherein the water turbine (7) is fixedly arranged on the outer wall of the transmission sleeve (4) and is provided with an output gear (71), one side of the annular driving disk (5) is fixedly provided with a driving gear ring (52) which is coaxially distributed, and the driving gear ring (52) is meshed with the output gear (71).