CN214636357U - Automatic accurate temperature control system of reation kettle - Google Patents

Abstract

The utility model discloses an automatic accurate temperature control system of reation kettle, including the reation kettle body: the fixed motor that is equipped with in reation kettle body top, the fixed cover that is equipped with in reation kettle body outside is equipped with the cover that presss from both sides, the inside both sides of cover are all fixed to inlay and are equipped with the heating pipe, both sides heating pipe one end is extended and is pressed from both sides the cover outside, the fixed casing that is equipped with in reation kettle body bottom, inside cooling body and the rabbling mechanism of being equipped with respectively of motor, the inside heating mechanism that is equipped with of casing, cooling body includes the ring cover, the fixed reactor body inner wall of inlaying of ring cover, the inside fixed water injection pipe that is equipped with of ring cover, the reation kettle body outside is extended respectively at water injection pipe both ends, water injection pipe both ends fixedly connected with second water pump and first water pump respectively, through using the utility model discloses temperature control system can provide the guarantee for the production process, also can alleviate operative employee's operating pressure, improves production efficiency.

Description

Automatic accurate temperature control system of reation kettle

Technical Field

The utility model relates to an automatic temperature control technical field especially relates to an automatic accurate temperature control system of reation kettle.

Background

The reaction kettle is widely used in the industries of medicine, food and chemical industry, the reaction kettle is broadly understood to be a container for physical or chemical reaction, the heating, evaporation, cooling and low-speed and high-speed mixing functions required by the process are realized by the structural design and parameter configuration of the container, the reaction kettle is widely applied to petroleum, chemical industry, rubber, pesticide, dye, medicine and food, and is a pressure container for completing the processes of vulcanization, nitration, hydrogenation, alkylation, polymerization, condensation and the like, such as a reactor, a reaction kettle, a decomposition kettle, a polymerization kettle and the like; the material is generally carbon manganese steel, stainless steel, zirconium, nickel-based (Hastelloy, Monel, Inconel) alloy and other composite materials.

The traditional drying method is to obtain heat through medium burning and heat up and dry the raw materials from the bottom, the method is very easy to cause uneven heating so as to cause bad reaction of chemical products, in the processing process, the temperature control is strict, the temperature can not be too high, otherwise, the product quality can be influenced, even scrapping is caused, when the temperature is too high, the rapid cooling is needed, and a common reaction kettle is arranged for special operators to detect the temperature at any time at present, the operators are often in a busy hand and foot, sweat streams down, the labor intensity is high, and the method is particularly suitable for hot summer.

Therefore, in view of the above technical problems, it is necessary for those skilled in the art to develop an automatic precise temperature control system for a reaction vessel.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an automatic accurate temperature control system of reation kettle.

In order to realize the purpose of automatic temperature control of the reaction kettle, the utility model provides a following technical scheme:

the utility model discloses an automatic accurate temperature control system of reation kettle, including the reation kettle body: the reaction kettle comprises a reaction kettle body and is characterized in that a motor is fixedly arranged at the top of the reaction kettle body, a jacket is fixedly sleeved outside the reaction kettle body, heating pipes are fixedly embedded in two sides of the interior of the jacket, one end of each heating pipe on two sides extends out of the jacket, a shell is fixedly arranged at the bottom of the reaction kettle body, a cooling mechanism and a stirring mechanism are respectively arranged in the motor, and a heating mechanism is arranged in the shell;

the cooling mechanism comprises an annular sleeve, the annular sleeve is fixedly embedded in the inner wall of the reaction kettle body, a water injection pipe is fixedly arranged in the annular sleeve, two ends of the water injection pipe respectively extend out of the reaction kettle body, and two ends of the water injection pipe are respectively and fixedly connected with a second water pump and a first water pump;

the stirring mechanism comprises a transmission rod, the transmission rod is fixedly connected with the output end of the motor, one end of the transmission rod is fixedly connected with a first bevel gear, two sides of the first bevel gear are respectively provided with a second bevel gear, the first bevel gear is meshed with the second bevel gears, one end of each of the second bevel gears at two sides is fixedly connected with a first connecting rod, one end of the first connecting rod is connected with the side wall of the reaction kettle body through a bearing, a plurality of fan blades are fixedly sleeved outside the first connecting rod, third bevel gears are arranged at the bottoms of the second bevel gears on two sides, the third bevel gear is meshed with the second bevel gear, one end of the third bevel gear is fixedly provided with a transmission column, a plurality of second connecting plates are fixedly sleeved outside the transmission column, one end of each second connecting plate is fixedly provided with a stirring component, the stirring assembly comprises a stirring rod, and the top of the stirring rod is fixedly connected with the second connecting plate.

Further, heating mechanism includes first connecting plate, first connecting plate is fixed to be located inside the casing, first connecting plate both sides all are fixed and are equipped with the electric conductor, both sides the electric conductor top all contacts with the heating pipe.

Furthermore, the two sides of the shell are provided with water tanks, and the second water pump and the first water pump extend into the water tanks on the two sides respectively.

Further, a first connecting shaft is arranged between the first connecting plates at the two sides, a sliding groove is arranged at one side of the first connecting plate, a connecting shaft is arranged in the sliding groove, two ends of the connecting shaft penetrate through the first connecting plate and are fixedly connected with the electric conductor, two sides of the first connecting shaft are fixedly connected with second supporting plates, one side of each second supporting plate at two sides is provided with two third connecting plates, the insides of the two third connecting plates are provided with sliding blocks, one side of one of the third connecting plates is fixedly provided with a first supporting plate, the first supporting plate is connected with the second supporting plate through a bearing, one end of the sliding block is connected with a second connecting shaft through a bearing, one side of the second connecting shaft is provided with a sliding rail, the equal fixedly connected with slide bar in first connecting axle both sides, the slide bar extends into inside the slide rail, second backup pad and second connecting axle swing joint.

Furthermore, a pedal is fixedly arranged at one end of the second connecting shaft, and a fixing hole is formed in one side of the pedal.

Further, a clamping plate is fixedly arranged on one side of the shell, a hollow groove is formed in the clamping plate, a hydrant is arranged in the clamping plate, a spring is fixedly sleeved on the outside of the hydrant, and the hydrant penetrates through the clamping plate.

Further, the inside protective housing that is equipped with of reation kettle body, head rod, transfer line and transmission post run through the protective housing and pass through the bearing with the protective housing and be connected, the equal fixedly connected with bracing piece in protective housing both sides, the bracing piece other end and reation kettle body inner wall fixed connection.

Further, the stirring assembly comprises a second stirring rod, and the top of the second stirring rod is fixedly connected with the second connecting plate.

In the technical scheme, the utility model provides a pair of automatic accurate temperature control system of reation kettle has following beneficial effect:

1. the utility model discloses a heating mechanism's design lets the heating pipe evenly distributed outside the reation kettle body, can carry out the bulk heating to the reation kettle body when the heating pipe heats, can let the chemical products inside the reation kettle evenly be heated, can not produce the uneven chemical products phenomenon of reaction failure that is heated, and heating simple structure, the simple operation can carry out strict handle to the temperature and control;

2. the utility model discloses a design of rabbling mechanism and cooling body, when the high temperature, pull out the hydrant, heating mechanism can self-closing, opens the cooling water valve and cools off, can cool down fast to the chemicals this moment, can not influence the quality problem because of the high temperature, and overall structure is simple, and the operation is convenient, and low in labor strength has practiced thrift labour cost, and it is very convenient to let the operative employee operate.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained by those skilled in the art according to these drawings.

Fig. 1 is a schematic structural diagram of an automatic precise temperature control system of a reaction kettle according to an embodiment of the present invention;

fig. 2 is an enlarged view of a point a in fig. 1 according to an embodiment of the present invention;

fig. 3 is an enlarged view of a portion B in fig. 1 according to an embodiment of the present invention;

fig. 4 is a side view of an automatic precise temperature control system of a reaction kettle according to an embodiment of the present invention;

fig. 5 is a schematic structural view of a pedal plate of an automatic precise temperature control system of a reaction kettle according to an embodiment of the present invention;

fig. 6 is a schematic view of the overall structure of embodiment 2 of an automatic accurate temperature control system of a reaction kettle according to an embodiment of the present invention.

Description of reference numerals:

the reaction kettle comprises a reaction kettle body 1, a motor 2, a transmission rod 3, a first bevel gear 4, a second bevel gear 5, a first connecting rod 6, fan blades 7, a third bevel gear 8, a transmission column 9, a second connecting plate 10, an annular sleeve 11, a protective shell 12, a water injection pipe 13, a heating pipe 14, a shell 15, a water tank 16, a stirring rod 17, a connecting port 18, a first connecting plate 19, an electric conductor 20, a first water pump 21, a second water pump 22, a first connecting shaft 23, a third connecting plate 24, a sliding block 25, a second connecting shaft 26, a first supporting plate 27, a pedal 28, a clamping plate 29, a bolt 30, a spring 31, a second stirring rod 32 and a second supporting plate 33.

Detailed Description

In order to make the technical solution of the present invention better understood by those skilled in the art, the present invention will be further described in detail with reference to the accompanying drawings.

Example 1:

as shown in fig. 1 to 5;

the utility model discloses an automatic accurate temperature control system of reation kettle, including reation kettle body 1: the top of the reaction kettle body 1 is fixedly provided with a motor 2, the outside of the reaction kettle body 1 is fixedly sleeved with a jacket, heating pipes 14 are fixedly embedded in two sides of the inside of the jacket, one end of each of the heating pipes 14 in two sides extends out of the jacket, the bottom of the reaction kettle body 1 is fixedly provided with a shell 15, the inside of the motor 2 is respectively provided with a cooling mechanism and a stirring mechanism, and the inside of the shell 15 is provided with a heating mechanism;

the cooling mechanism comprises an annular sleeve 11, the annular sleeve 11 is fixedly embedded in the inner wall of the reaction kettle body 1, a water injection pipe 13 is fixedly arranged in the annular sleeve 11, two ends of the water injection pipe 13 respectively extend out of the reaction kettle body 1, and two ends of the water injection pipe 13 are respectively and fixedly connected with a second water pump 22 and a first water pump 21;

the stirring mechanism comprises a transmission rod 3, the transmission rod 3 is fixedly connected with the output end of a motor 2, one end of the transmission rod 3 is fixedly connected with a first bevel gear 4, two sides of the first bevel gear 4 are respectively provided with a second bevel gear 5, the first bevel gear 4 is meshed with the second bevel gear 5, one end of the second bevel gear 5 at two sides is respectively fixedly connected with a first connecting rod 6, one end of each first connecting rod 6 is connected with the side wall of the reaction kettle body 1 through a bearing, the first connecting rod 6 is fixedly sleeved with a plurality of fan blades 7, the bottom of the second bevel gear 5 at two sides is provided with a third bevel gear 8, the third bevel gear 8 is meshed with the second bevel gear 5, one end of each third bevel gear 8 is fixedly provided with a transmission column 9, the outer part of each transmission column 9 is fixedly sleeved with a plurality of second connecting plates 10, and one end of each second connecting plate 10 is fixedly provided with a stirring component, stirring subassembly includes puddler 17, puddler 17 top and second connecting plate 10 fixed connection, water injection pipe 13 have carry out refrigerated effect to motor 2, and puddler 17 has stirring effect auxiliary motor 2 rapid cooling, and annular cover 11 has the guard action to water injection pipe 13.

Preferably, the heating mechanism comprises a first connecting plate 19, the first connecting plate 19 is fixedly arranged inside the housing 15, electric conductors 20 are fixedly arranged on both sides of the first connecting plate 19, the tops of the electric conductors 20 on both sides are in contact with the heating pipe 14, the first connecting plate 19 has a supporting function, and the first connecting plate 19 can actuate the electric conductors 20 to move.

Preferably, the water tanks 16 are disposed on both sides of the housing 15, the second water pump 22 and the first water pump 21 respectively extend into the water tanks 16 on both sides, and the water tanks 16 have a water storage function.

Preferably, a first connecting shaft 23 is arranged between the first connecting plates 19 at two sides, a sliding groove is arranged at one side of the first connecting plate 19, a connecting shaft is arranged in the sliding groove, two ends of the connecting shaft penetrate through the first connecting plates 19 and are fixedly connected with the electric conductors 20, a second supporting plate 33 is fixedly connected at two sides of the first connecting shaft 23, two third connecting plates 24 are arranged at one side of the second supporting plate 33 at two sides, a sliding block 25 is arranged in each of the two third connecting plates 24, a first supporting plate 27 is fixedly arranged at one side of one of the third connecting plates 24, the first supporting plate 27 is connected with the second supporting plate 33 through a bearing, a second connecting shaft 26 is connected to one end of the sliding block 25 through a bearing, a sliding rail is arranged at one side of the second connecting shaft 26, sliding rods are fixedly connected at two sides of the first connecting shaft 23, and extend into the sliding rail, the second support plate 33 is movably connected with the second connecting shaft 26, the sliding block 25 has the function of driving the pedal plate 28 to move, and the first support plate 27 has the function of supporting the second support plate 33.

Preferably, a pedal 28 is fixedly disposed at one end of the second connecting shaft 26, a fixing hole is disposed at one side of the pedal 28, and the pedal 28 has an effect of driving the electric conductor 20 to move up and down integrally.

Preferably, a clamping plate 29 is fixedly arranged on one side of the casing 15, a hollow groove is formed in the clamping plate 29, a hydrant 30 is arranged in the clamping plate 29, a spring 31 is fixedly sleeved outside the hydrant 30, the hydrant 30 penetrates through the clamping plate 29, and the hydrant 30 has the function of fixing the pedal 28.

Preferably, the inside protective housing 12 that is equipped with of reation kettle body 1, head rod 6, transfer line 3 and transmission post 9 run through protective housing 12 and are connected through the bearing with protective housing 12, the equal fixedly connected with bracing piece in protective housing 12 both sides, the bracing piece other end and the 1 inner wall fixed connection of reation kettle body, protective housing 12 have the effect of protection head rod 6, transfer line 3 and transmission post 9.

The implementation mode is specifically as follows: the utility model is connected with an external power supply, when the temperature of the reaction kettle body 1 needs to be raised, a downward acting force is given to the pedal plate 28 by feet, at the moment, the pedal plate 28 moves downwards to be in the same horizontal line with the clamping plate 29, the hydrant 30 in the clamping plate 29 can enter the fixed hole arranged in the pedal plate 28 under the drive of the spring 31, the pedal plate 28 can drive the first supporting plate 27 to move upwards by taking the second supporting plate 33 as a fulcrum, the first supporting plate 27 moves upwards to drive the second supporting plate 33 to move upwards, the second supporting plate 33 moves upwards to drive the electric conductor 20 to move upwards to be contacted with the heating pipe 14, the heating pipe 14 is electrified, the heating pipe 14 can heat the reaction kettle body 1 to carry out integral heating from the outer wall, when the heating temperature is overhigh, the hydrant 30 is pulled out, at the moment, the pedal plate 28 moves upwards, the pedal plate 28 can be disconnected upwards to be connected with the fulcrum of the second supporting plate 33, the first supporting plate 27 moves downwards to drive the second supporting plate 33 to move downwards, the second supporting plate 33 moves downwards to drive the electric conductor 20 to move downwards to be disconnected from being in contact with the heating pipe 14, the first connecting shaft 23 is started, the first connecting shaft 23 can drive cold water in the water tank 16 into the heating pipe 14, the cold water winds the inner wall of the reaction kettle body 1 by the heating pipe 14 for one circle to cool the reaction kettle body 1, the cold water winds the reaction kettle body 1 for one circle and then is output out of the reaction kettle body 1 through the other end of the heating pipe 14 to enter the water tank 16, the cold water is cooled by the first water pump 21 and is brought into the heating pipe 14 to circulate, the water resource is saved, at the moment, the power supply is started, the motor 2 rotates to drive the transmission rod 3 to rotate, the transmission rod 3 rotates to drive the first bevel gear 4 and the third bevel gear 8 to rotate, the first bevel gear 4 rotates to drive the second bevel gear 5 to rotate, second bevel gear 5 rotates and drives head rod 6 and rotate, head rod 6 rotates and drives outside flabellum 7 and rotate, third bevel gear 8 rotates and drives transmission post 9 and rotate, transmission post 9 rotates and drives second connecting plate 10 and rotate, second connecting plate 10 rotates and drives puddler 17 and rotate, flabellum 7 and puddler 17 rotate and can stir the loss of accelerating inside temperature to 1 inside of reation kettle body, let the cooling rapider.

Example 2:

the difference from example 1 is:

as shown in fig. 6;

the utility model discloses an automatic accurate temperature control system of reation kettle, the stirring subassembly includes second puddler 32, second puddler 32 top all with 10 fixed connection of second connecting plate:

the implementation mode is specifically as follows: the utility model is connected with an external power supply, when the temperature of the reaction kettle body 1 needs to be raised, a downward acting force is given to the pedal plate 28 by feet, at the moment, the pedal plate 28 moves downwards to be in the same horizontal line with the clamping plate 29, the hydrant 30 in the clamping plate 29 can enter the fixed hole arranged in the pedal plate 28 under the drive of the spring 31, the pedal plate 28 can drive the first supporting plate 27 to move upwards by taking the second supporting plate 33 as a fulcrum, the first supporting plate 27 moves upwards to drive the second supporting plate 33 to move upwards, the second supporting plate 33 moves upwards to drive the electric conductor 20 to move upwards to be contacted with the heating pipe 14, the heating pipe 14 is electrified, the heating pipe 14 can heat the reaction kettle body 1 to carry out integral heating from the outer wall, when the heating temperature is overhigh, the hydrant 30 is pulled out, at the moment, the pedal plate 28 moves upwards, the pedal plate 28 can be disconnected upwards to be connected with the fulcrum of the second supporting plate 33, the first supporting plate 27 moves downwards to drive the second supporting plate 33 to move downwards, the second supporting plate 33 moves downwards to drive the electric conductor 20 to move downwards to be disconnected from being in contact with the heating pipe 14, the first connecting shaft 23 is started, the first connecting shaft 23 can drive cold water in the water tank 16 into the heating pipe 14, the cold water winds the inner wall of the reaction kettle body 1 by the heating pipe 14 for one circle to cool the reaction kettle body 1, the cold water winds the reaction kettle body 1 for one circle and then is output out of the reaction kettle body 1 through the other end of the heating pipe 14 to enter the water tank 16, the cold water is cooled by the first water pump 21 and is brought into the heating pipe 14 to circulate, the water resource is saved, at the moment, the power supply is started, the motor 2 rotates to drive the transmission rod 3 to rotate, the transmission rod 3 rotates to drive the first bevel gear 4 and the third bevel gear 8 to rotate, the first bevel gear 4 rotates to drive the second bevel gear 5 to rotate, second bevel gear 5 rotates and drives head rod 6 and rotates, head rod 6 rotates and drives outside flabellum 7 and rotates, third bevel gear 8 rotates and drives transmission post 9 and rotates, transmission post 9 rotates and drives second connecting plate 10 and rotate, second connecting plate 10 rotates and drives second puddler 32 and rotate, flabellum 7 and second puddler 32 rotate and can stir the loss that accelerates inside temperature to 1 inside of reation kettle body, second puddler 32 area is big, can obtain better stirring to 1 bottom of reation kettle body, let the cooling rapider.

In the technical scheme, the utility model provides a pair of automatic accurate temperature control system of reation kettle has following beneficial effect:

1. the utility model discloses a heating mechanism's design lets the heating pipe evenly distributed outside the reation kettle body, can carry out the bulk heating to the reation kettle body when the heating pipe heats, can let the chemical products inside the reation kettle evenly be heated, can not produce the uneven chemical products phenomenon of reaction failure that is heated, and heating simple structure, the simple operation can carry out strict handle to the temperature and control;

2. the utility model discloses a design of rabbling mechanism and cooling body, when the high temperature, pull out the hydrant, heating mechanism can self-closing, opens the cooling water valve and cools off, can cool down fast to the chemicals this moment, can not influence the quality problem because of the high temperature, and overall structure is simple, and the operation is convenient, and low in labor strength has practiced thrift labour cost, and it is very convenient to let the operative employee operate.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the present invention. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the invention.

Claims (8)

1. The automatic accurate temperature control system of reation kettle, characterized by, include reation kettle body (1): the reactor comprises a reaction kettle body (1), and is characterized in that a motor (2) is fixedly arranged at the top of the reaction kettle body (1), a jacket is fixedly sleeved outside the reaction kettle body (1), heating pipes (14) are fixedly embedded in two sides of the inside of the jacket, one end of each of the heating pipes (14) on two sides extends out of the jacket, a shell (15) is fixedly arranged at the bottom of the reaction kettle body (1), a cooling mechanism and a stirring mechanism are respectively arranged in the motor (2), and a heating mechanism is arranged in the shell (15);

the cooling mechanism comprises an annular sleeve (11), the annular sleeve (11) is fixedly embedded in the inner wall of the reaction kettle body (1), a water injection pipe (13) is fixedly arranged in the annular sleeve (11), two ends of the water injection pipe (13) respectively extend out of the reaction kettle body (1), and two ends of the water injection pipe (13) are respectively and fixedly connected with a second water pump (22) and a first water pump (21);

the stirring mechanism comprises a transmission rod (3), the transmission rod (3) is fixedly connected with the output end of a motor (2), one end of the transmission rod (3) is fixedly connected with a first bevel gear (4), two sides of the first bevel gear (4) are respectively provided with a second bevel gear (5), the first bevel gear (4) is meshed with the second bevel gear (5), one ends of the second bevel gears (5) at two sides are respectively fixedly connected with a first connecting rod (6), one end of the first connecting rod (6) is connected with the side wall of the reaction kettle body (1) through a bearing, a plurality of fan blades (7) are fixedly sleeved outside the first connecting rod (6), a third bevel gear (8) is arranged at the bottom of the second bevel gear (5) at two sides, the third bevel gear (8) is meshed with the second bevel gear (5), one end of the third bevel gear (8) is fixedly provided with a transmission column (9), the fixed cover in transmission post (9) outside is equipped with a plurality of second connecting plates (10), and is a plurality of second connecting plate (10) one end is fixed and is equipped with the stirring subassembly, the stirring subassembly includes puddler (17), puddler (17) top and second connecting plate (10) fixed connection.

2. The automatic precise temperature control system of the reaction kettle according to claim 1, wherein the heating mechanism comprises a first connecting plate (19), the first connecting plate (19) is fixedly arranged inside the shell (15), electric conductors (20) are fixedly arranged on both sides of the first connecting plate (19), and tops of the electric conductors (20) on both sides are in contact with the heating pipe (14).

3. The automatic precise temperature control system of the reaction kettle according to claim 1, wherein water tanks (16) are arranged on both sides of the housing (15), and the second water pump (22) and the first water pump (21) respectively extend into the water tanks (16) on both sides.

4. The automatic precise temperature control system of the reaction kettle according to claim 2, wherein a first connecting shaft (23) is arranged between the first connecting plates (19) at two sides, a sliding groove is formed at one side of the first connecting plates (19), a connecting shaft is arranged in the sliding groove, two ends of the connecting shaft penetrate through the first connecting plates (19) and are fixedly connected with the electric conductors (20), a second supporting plate (33) is fixedly connected at two sides of the first connecting shaft (23), two third connecting plates (24) are arranged at one side of the second supporting plate (33) at two sides, a sliding block (25) is arranged in each of the two third connecting plates (24), a first supporting plate (27) is fixedly arranged at one side of one of the third connecting plates (24), the first supporting plate (27) is connected with the second supporting plate (33) through a bearing, and a second connecting shaft (26) is bearing-connected at one end of the sliding block (25), a sliding rail is arranged on one side of the second connecting shaft (26), sliding rods are fixedly connected to two sides of the first connecting shaft (23) and extend into the sliding rail, and the second supporting plate (33) is movably connected with the second connecting shaft (26).

5. The automatic precise temperature control system of the reaction kettle according to claim 1, wherein a pedal (28) is fixedly arranged at one end of the second connecting shaft (26), and a fixing hole is formed at one side of the pedal (28).

6. The automatic precise temperature control system of the reaction kettle according to claim 1, wherein a clamping plate (29) is fixedly arranged on one side of the housing (15), a hollow groove is arranged inside the clamping plate (29), a hydrant (30) is arranged inside the clamping plate (29), a spring (31) is fixedly arranged outside the hydrant (30), and the hydrant (30) penetrates through the clamping plate (29).

7. The automatic accurate temperature control system of reation kettle according to claim 1, characterized in that protective housing (12) is equipped with to reation kettle body (1) inside, first connecting rod (6), transfer line (3) and transmission post (9) run through protective housing (12) and are connected through the bearing with protective housing (12), the equal fixedly connected with bracing piece in protective housing (12) both sides, the bracing piece other end and reation kettle body (1) inner wall fixed connection.

8. The automatic precise temperature control system of the reaction kettle according to claim 1, wherein the stirring assembly comprises a second stirring rod (32), and the top of the second stirring rod (32) is fixedly connected with the second connecting plate (10).

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