CN219209940U - Intelligent temperature control type mixing reaction kettle - Google Patents

Abstract

The application discloses intelligent control by temperature change formula hybrid reaction cauldron relates to reation kettle technical field. The application comprises the following steps: the kettle body is internally provided with a mixing cavity and a temperature control cavity which are distributed inside and outside, the kettle body is provided with a kettle cover, a steam pipe, a water outlet pipe, a discharge pipe and a connecting pipe, the free ends of the steam pipe, the water outlet pipe and the connecting pipe are communicated with the temperature control cavity, the free end of the discharge pipe is communicated with the mixing cavity, and the kettle cover is rotatably provided with a stirring rod positioned in the mixing cavity; the storage box and the conveying pipe are arranged on the kettle cover and are mutually communicated, a spiral conveying rod is rotationally arranged in the conveying pipe, the free end of the conveying pipe is detachably connected with the connecting pipe, and the conveying pipe is provided with a conveying motor with an output shaft connected with the spiral conveying rod. The utility model discloses a when using, realize cooling function through the ice-cube, cooling efficiency is high, can satisfy some circumstances that need cool down fast in the short time, can carry out recycle to the water resource simultaneously, and is more energy-concerving and environment-protective, therefore more has the practicality.

Description

Intelligent temperature control type mixing reaction kettle

Technical Field

The application relates to the technical field of reaction kettles, in particular to an intelligent temperature control type mixing reaction kettle.

Background

The reaction kettle is widely understood to be a stainless steel container with physical or chemical reaction, the structural design and parameter configuration of the container are carried out according to different technological condition requirements, the design conditions, the process, the inspection, the manufacture and the acceptance are required to be based on relevant technical standards, so that the heating, evaporation, cooling and low-speed mixing reaction functions of technological requirements are realized, along with the continuous development of technology, the reaction kettle gradually tends to be intelligent and can automatically control the temperature, so that the intelligent temperature control type hybrid reaction kettle is also called as an intelligent temperature control type hybrid reaction kettle, when the intelligent temperature control type reaction kettle is used, cooling water is usually used for cooling, although the cooling function can be realized, the cooling efficiency is lower, and the requirements are difficult to meet in the face of the situation that rapid cooling is required in a short time, so that the intelligent temperature control type hybrid reaction kettle is provided.

Disclosure of Invention

The purpose of the present application is: for solving the problem that the background art provided, this application provides an intelligent control by temperature change formula hybrid reaction cauldron.

The application specifically adopts the following technical scheme for realizing the purposes:

an intelligent temperature control type mixing reaction kettle, comprising:

the kettle body is internally provided with a mixing cavity and a temperature control cavity which are distributed inside and outside, the kettle body is provided with a kettle cover, a steam pipe, a water outlet pipe, a discharge pipe and a connecting pipe, the free ends of the steam pipe, the water outlet pipe and the connecting pipe are communicated with the temperature control cavity, the free end of the discharge pipe is communicated with the mixing cavity, and the kettle cover is rotatably provided with a stirring rod positioned in the mixing cavity;

the storage box and the conveying pipe are arranged on the kettle cover and are mutually communicated, a spiral conveying rod is rotationally arranged in the conveying pipe, the free end of the conveying pipe is detachably connected with the connecting pipe, and the conveying pipe is provided with a conveying motor with an output shaft connected with the spiral conveying rod.

Further, a heat conducting annular plate is arranged in the temperature control cavity.

Further, two symmetrically distributed crushing rollers are rotationally arranged in the storage box and are in transmission connection through a gear pair.

Further, the free end of the screw conveyor rod rotates through the conveyor pipe and is in driving connection with one of the crushing rollers through a belt pulley assembly.

Further, the kettle body is rotatably provided with a swivel, and the swivel is provided with a toggle rod positioned in the temperature control cavity.

Further, a fixed rod is sleeved on the stirring rod, a positioning hole is formed in the rotating ring, and a positioning block in plug-in fit with the positioning hole is arranged on the fixed rod.

Further, two auxiliary rods distributed in an annular array are arranged on the fixed rod.

Further, the auxiliary rod is rotatably arranged on the fixed rod, the free end of the auxiliary rod is provided with a transmission gear, the kettle cover is provided with an inner gear ring, and the two transmission gears are meshed with the inner gear ring.

The beneficial effects of this application are as follows: the utility model discloses a when using, realize cooling function through the ice-cube, cooling efficiency is high, can satisfy some circumstances that need cool down fast in the short time, can carry out recycle to the water resource simultaneously, and is more energy-concerving and environment-protective, therefore more has the practicality.

Drawings

FIG. 1 is a perspective view of the structure of the present application;

FIG. 2 is a perspective cross-sectional view of the present application;

FIG. 3 is an enlarged view of FIG. 2A of the present application;

fig. 4 is an enlarged view at B in fig. 2 of the present application.

Reference numerals: 1. a kettle body; 2. a mixing chamber; 3. a temperature control cavity; 4. a kettle cover; 5. a steam pipe; 6. a water outlet pipe; 7. a discharge pipe; 8. a connecting pipe; 9. a stirring rod; 10. a storage tank; 11. a delivery tube; 12. a screw conveyor rod; 13. a conveying motor; 14. a heat conducting annular plate; 15. a crushing roller; 16. a gear pair; 17. a pulley assembly; 18. a swivel; 19. a toggle rod; 20. a fixed rod; 21. positioning holes; 22. a positioning block; 23. an auxiliary rod; 24. a transmission gear; 25. an inner gear ring.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application more clear, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application.

As shown in fig. 1-4, an intelligent temperature-controlled hybrid reaction kettle according to an embodiment of the present application includes: the kettle body 1 is internally provided with a mixing cavity 2 and a temperature control cavity 3 which are distributed inside and outside, the kettle body 1 is in a vertical direction, the kettle body 1 is provided with a kettle cover 4, a steam pipe 5, a water outlet pipe 6, a discharge pipe 7 and a connecting pipe 8, the kettle cover 4 is detachably arranged at the top of the kettle body 1, the free ends of the steam pipe 5, the water outlet pipe 6 and the connecting pipe 8 are all communicated with the temperature control cavity 3, the free end of the discharge pipe 7 is communicated with the mixing cavity 2, the steam pipe 5, the water outlet pipe 6 and the discharge pipe 7 are all provided with valves, in an initial state, the three valves are all in a closed state, the kettle cover 4 is rotatably provided with a stirring rod 9 positioned in the mixing cavity 2, the stirring rod 9 is in a vertical direction, and the kettle cover 4 is provided with a stirring motor with an output shaft connected with the stirring rod 9; the storage tank 10 and the conveying pipe 11 are arranged on the kettle cover 4 and are mutually communicated, a screw conveying rod 12 is arranged in the conveying pipe 11 in a rotating way, the screw conveying rod 12 is in a horizontal direction, the free end of the conveying pipe 11 is detachably connected with the connecting pipe 8 through two bolts, a conveying motor 13 with an output shaft connected with the screw conveying rod 12 is arranged on the conveying pipe 11, in actual use, a temperature controller is additionally arranged on the kettle cover 4 and is electrically connected with the conveying motor 13, the temperature inside the mixing cavity 2 can be monitored in real time through a temperature sensor, ice cubes are added into the storage tank 10 before use, a valve on the water outlet pipe 6 is opened, in use, materials to be mixed are added into the mixing cavity 2, the kettle cover 4 is mounted on the top of the kettle body 1, the conveying pipe 11 is connected with the connecting pipe 8 through two bolts, the free end of the steam pipe 5 is connected with the steam generating equipment, the free end of the water outlet pipe 6 is connected with the ice making equipment, the free end of the water outlet pipe 7 is connected with the receiving container, the stirring motor is driven to work, the output shaft rotates, the stirring rod 9 is driven to rotate, materials in the mixing cavity 2 are mixed, when the materials in the mixing cavity 2 are required to be heated, the valve on the steam pipe 5 is opened, steam is supplied into the steam pipe 5 through the steam generating equipment, the steam enters the temperature control cavity 3 and transfers heat to the materials in the mixing cavity 2, thereby heating the materials, in the process, the temperature of the mixing cavity 2 is monitored in real time by the temperature controller, the steam is liquefied into condensed water due to temperature reduction, the condensed water is discharged into the ice making equipment through the water outlet pipe 6, and recycling of the condensed water is realized, more energy-concerving and environment-protective, when the high temperature, stop to supply steam and close the valve on the steam pipe 5 to steam pipe 5 through steam generating equipment, otherwise, when the material to mixing chamber 2 is cooled down, order about conveying motor 13 work, the output shaft rotates, drive screw conveyer pole 12 together rotates, carry the ice-cube in the bin 10 to in the connecting pipe 8, afterwards, the ice-cube enters into the control by connecting pipe 8 in the control by temperature change chamber 3 and carries out rapid cooling to the material that is located mixing chamber 2, in this process, carry out real-time supervision by the temperature controller to the temperature in the mixing chamber 2, the ice-cube can liquefy into water and discharge to ice-making equipment from outlet pipe 6 because of the temperature rise, in order to realize the recycle to the water resource, more energy-concerving and environment-protective, when the temperature is too low, close conveying motor 13, after the material in mixing chamber 2 is accomplished, open the valve on the discharging pipe 7, the material in the mixing chamber 2 is discharged along the pipe 7, in the above-mentioned, this application is when using, realize the cooling function through the ice-cube, high efficiency can satisfy some needs in a short time, simultaneously can be cooled down more energy-concerving and environment-protective, and can be used to the water resource is cooled down more effectively.

As shown in fig. 3, in some embodiments, the heat-conducting annular plate 14 is disposed in the temperature control cavity 3, and the heat-conducting annular plate 14 is made of copper with good heat-conducting performance, and referring to the above, the heat-conducting annular plate 14 can improve the heating and cooling efficiency of the material to a certain extent.

As shown in fig. 1, in some embodiments, two symmetrically distributed crushing rollers 15 are rotationally arranged in the storage box 10, the two crushing rollers 15 are in transmission connection through a gear pair 16, the two crushing rollers 15 are all in a horizontal direction, the gear pair 16 is composed of two meshed gears, the two gears are respectively sleeved on the two crushing rollers 15, when ice cubes are added into the storage box 10, one of the crushing rollers 15 is driven to rotate, the other crushing roller 15 is driven to synchronously and reversely rotate through the gear pair 16, and the ice cubes are crushed through the two synchronously and reversely rotating crushing rollers 15, so that the screw conveying rod 12 is prevented from being blocked by the ice cubes with larger volumes.

As shown in fig. 1, in some embodiments, the free end of the screw conveying rod 12 rotates to penetrate through the conveying pipe 11 and is in transmission connection with one of the crushing rollers 15 through the belt pulley assembly 17, the belt pulley assembly 17 is composed of two belt pulleys and a connecting belt, the two belt pulleys are respectively sleeved on the free end of the screw conveying rod 12 and one of the crushing rollers 15, and when the screw conveying rod 12 rotates, the belt pulley assembly 17 drives one of the crushing rollers 15 to synchronously rotate, so that not only can the synchronous implementation of ice crushing and ice conveying be realized, but also the electric energy consumption can be reduced to a certain extent, and the energy conservation and the environmental protection are realized.

As shown in fig. 3, in some embodiments, a swivel 18 is rotatably disposed on the kettle body 1, the swivel 18 is in a horizontal direction, a toggle rod 19 located in the temperature control cavity 3 is disposed on the swivel 18, the toggle rod 19 is in a vertical direction, and according to the above, when ice cubes enter the temperature control cavity 3, the swivel 18 is driven to rotate, the toggle rod 19 is driven to rotate synchronously, and ice cubes in the temperature control cavity 3 are scattered through the rotating toggle rod 19, so that ice cubes are prevented from being accumulated at a certain position in the temperature control cavity 3, and cooling efficiency is improved.

As shown in fig. 3, in some embodiments, the stirring rod 9 is sleeved with a fixing rod 20, the fixing rod 20 is in a horizontal direction, a positioning hole 21 is formed in the swivel 18, a positioning block 22 in plug-in fit with the positioning hole 21 is arranged on the fixing rod 20, and when the kettle cover 4 is installed at the top of the kettle body 1, the positioning block 22 is correspondingly plugged into the positioning hole 21, and when the stirring rod 9 rotates, the fixing rod 20 is driven to rotate together, and at the moment, the swivel 18 rotates together with the fixing rod 20 due to the fact that the positioning block 22 is plugged into the positioning hole 21, not only can synchronous material mixing and ice-cube scattering in the temperature control cavity 3 be realized, but also electric energy consumption can be reduced to a certain extent, and the stirring rod is more energy-saving and environment-friendly.

As shown in fig. 4, in some embodiments, two auxiliary rods 23 distributed in a ring array are disposed on the fixed rod 20, and the auxiliary rods 23 are in a vertical direction, and referring to the above, when the stirring rod 9 rotates, the fixed rod 20 is driven to rotate together, at this time, the two auxiliary rods 23 both rotate together with the fixed rod 20, and the mixing effect of materials can be improved to a certain extent through the two rotating auxiliary rods 23.

As shown in fig. 4, in some embodiments, the auxiliary rod 23 is rotatably disposed on the fixed rod 20, the free end is provided with a transmission gear 24, the two transmission gears 24 are both horizontally disposed and respectively disposed at the top ends of the two auxiliary rods 23, the kettle cover 4 is provided with an inner gear ring 25, the inner gear ring 25 is horizontally disposed, the two transmission gears 24 are both meshed with the inner gear ring 25, and when the fixed rod 20 rotates, the two auxiliary rods 23 rotate together with the fixed rod 20, and at the same time, the two transmission gears 24 are both rotated due to the meshing effect, so that the two auxiliary rods 23 are respectively driven to rotate around their own axes, and the two auxiliary rods 23 are respectively rotated around their own axes while revolving around the axis of the stirring rod 9, thereby further improving the mixing effect of materials.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the application. Thus, the present application is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (8)

1. An intelligent temperature control type mixing reaction kettle, which is characterized by comprising:

the kettle body (1) is internally provided with a mixing cavity (2) and a temperature control cavity (3) which are distributed inside and outside, the kettle body (1) is provided with a kettle cover (4), a steam pipe (5), a water outlet pipe (6), a discharging pipe (7) and a connecting pipe (8), the free ends of the steam pipe (5), the water outlet pipe (6) and the connecting pipe (8) are communicated with the temperature control cavity (3), the free end of the discharging pipe (7) is communicated with the mixing cavity (2), and a stirring rod (9) positioned in the mixing cavity (2) is rotationally arranged on the kettle cover (4);

the storage box (10) and the conveying pipe (11) are arranged on the kettle cover (4) and are mutually communicated, a spiral conveying rod (12) is rotationally arranged in the conveying pipe (11), the free end of the conveying pipe (11) is detachably connected with the connecting pipe (8), and a conveying motor (13) with an output shaft connected with the spiral conveying rod (12) is arranged on the conveying pipe (11).

2. The intelligent temperature-control type mixing reaction kettle according to claim 1, wherein a heat-conducting annular plate (14) is arranged in the temperature-control cavity (3).

3. The intelligent temperature-control type mixing reaction kettle according to claim 1, wherein two symmetrically distributed crushing rollers (15) are rotationally arranged in the storage box (10), and the two crushing rollers (15) are in transmission connection through a gear pair (16).

4. An intelligent temperature-controlled mixing reactor according to claim 3, characterized in that the free end of the screw conveyor (12) rotates through the conveyor pipe (11) and is in driving connection with one of the crushing rollers (15) through a pulley assembly (17).

5. The intelligent temperature-control type mixing reaction kettle according to claim 1, wherein a swivel (18) is rotatably arranged on the kettle body (1), and a toggle rod (19) positioned in the temperature control cavity (3) is arranged on the swivel (18).

6. The intelligent temperature-control type mixing reaction kettle according to claim 5, wherein a fixed rod (20) is sleeved on the stirring rod (9), a positioning hole (21) is formed in the swivel (18), and a positioning block (22) in plug-in fit with the positioning hole (21) is arranged on the fixed rod (20).

7. The intelligent temperature-control type mixing reaction kettle according to claim 6, wherein two auxiliary rods (23) distributed in an annular array are arranged on the fixed rod (20).

8. The intelligent temperature-control type mixing reaction kettle according to claim 7, wherein the auxiliary rod (23) is rotatably arranged on the fixed rod (20) and a transmission gear (24) is arranged at the free end, an inner gear ring (25) is arranged on the kettle cover (4), and the two transmission gears (24) are meshed with the inner gear ring (25).

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