CN219722854U - Intelligent temperature control chemical reaction kettle - Google Patents

Abstract

The utility model relates to the technical field of chemical equipment, in particular to an intelligent temperature control chemical reaction kettle. According to the utility model, the second coil pipe is arranged in the pipeline cavity of the reaction kettle body, and the first coil pipe is arranged on the spiral blade, so that the spiral blade can heat reactants in the reaction cavity while stirring and mixing the reactants, the reactants in the reaction cavity can be effectively heated, the reactants are heated more uniformly, the reaction rate is improved, and the product quality is greatly improved; in addition, the first sleeve and the second sleeve are arranged in the reaction cavity, and the water outlet and the water inlet are arranged on the rotating shaft, so that the rotating shaft can drive the spiral blade to rotate and simultaneously does not prevent the flow of water flow; finally, the heating water tank is independently arranged, so that the circulating heating of water flow can be realized, the temperature in the reaction kettle body is ensured, water resources can be saved, and the circulating utilization of the water resources is realized.

Description

Intelligent temperature control chemical reaction kettle

Technical Field

The utility model relates to the technical field of chemical equipment, in particular to an intelligent temperature control chemical reaction kettle.

Background

The chemical reaction kettle is a container for reacting chemical products, generally has the functions of mixing, heating, catalyzing, standing and the like, has wide application in chemical industries such as petroleum, agriculture, fertilizers, medicines, fuels and the like, but is usually heated by arranging a heating pipe in a reaction kettle wall, and can lead to high temperature of reactants contacting with the kettle wall or being close to the kettle wall and low temperature of reactants far from the kettle wall, thereby causing uneven heating of the reactants, low reaction rate, poor quality of generated products and low production efficiency.

Disclosure of Invention

Aiming at the problems in the prior art, the utility model provides an intelligent temperature control chemical reaction kettle.

The technical scheme adopted for solving the technical problems is as follows: the intelligent temperature control chemical reaction kettle comprises a reaction kettle body, a heating water tank, a chassis and a support column, wherein the reaction kettle body and the heating water tank are both positioned on the chassis and fixedly connected with the chassis, and the lower side of the chassis is fixedly connected with the support column;

the reaction kettle body comprises a reaction cavity, a pipeline cavity and a motor, wherein the pipeline cavity is positioned at the outer side of the reaction cavity, and the motor is positioned at the upper side of the reaction kettle body and is fixedly connected with the reaction kettle body;

the reaction chamber is internally provided with a rotating shaft, a spiral blade, a first sleeve, a first water outlet pipe, a second sleeve and a first water inlet pipe, a water flow channel is arranged in the rotating shaft, the upper end and the lower end of the rotating shaft are both closed, the side wall of the upper end of the rotating shaft is provided with a water outlet hole, the side wall of the lower end of the rotating shaft is provided with a water inlet hole, and the water outlet hole and the water inlet hole are both communicated with the water flow channel;

the first sleeve is a cylindrical cavity, the first sleeve is movably sleeved on the rotating shaft, the water outlet hole is positioned in the first sleeve, the diameter of the inner wall of the first sleeve is larger than that of the rotating shaft, the upper side wall of the first sleeve is fixedly connected with the inner wall of the reaction cavity, the side wall of the first sleeve is fixedly communicated with one end of the first water outlet pipe, the second sleeve is a cylindrical cavity, the second sleeve is movably sleeved on the rotating shaft, the water inlet hole is positioned in the second sleeve, the diameter of the inner wall of the second sleeve is larger than that of the rotating shaft, the bottom wall of the second sleeve is fixedly connected with the bottom wall of the reaction cavity, one end of the first water inlet pipe penetrates through the reaction kettle body and is fixedly communicated with the second sleeve, the top end of the rotating shaft penetrates through the first sleeve in sequence, the reaction cavity is rotationally connected with the motor, and the bottom end of the rotating shaft stretches into the second sleeve and is not connected with the bottom wall of the second sleeve;

the spiral blade is fixedly sleeved on the rotating shaft, a first coil is arranged on the spiral blade, and the first coil is communicated with the water flow channel.

Specifically, a second coil pipe, a second water outlet pipe and a second water inlet pipe are arranged in the pipeline cavity, the upper end of the second coil pipe is communicated with the second water outlet pipe, and the lower end of the second coil pipe is communicated with the second water inlet pipe.

Specifically, be provided with heater strip, suction pump, third outlet pipe, third water inlet pipe and temperature regulation panel in the heating water tank, the heating water tank is hollow cylindrical cavity, the heater strip is located in the heating water tank, and with the inner wall fixed connection of heating water tank, the suction pump with the diapire fixed connection of chassis, just the one end of suction pump runs through in proper order the chassis the diapire of heating water tank with the heating water tank is linked together.

Specifically, the third outlet pipe is an L-shaped water pipe, one end of the third outlet pipe is fixedly connected with the water suction pump, the other end of the third outlet pipe is vertically and fixedly connected with the first water inlet pipe, and the middle part of the third outlet pipe is vertically and fixedly connected with the second water inlet pipe.

Specifically, the third water inlet pipe is an L-shaped water pipe, one end of the third water inlet pipe penetrates through the upper side wall of the heating water tank and is communicated with the heating water tank, the other end of the third water inlet pipe is fixedly connected with the first water outlet pipe vertically, and the middle part of the third water inlet pipe is fixedly connected with the second water outlet pipe vertically.

Specifically, the temperature regulation panel is located the up end of heating water tank.

Specifically, the reaction chamber still includes pan feeding hole and discharging pipe, the pan feeding hole is located the up end of the reaction kettle body, and with the reaction chamber is linked together, the discharging pipe is located the lower terminal surface of the reaction kettle body, and with the reaction chamber is linked together.

Specifically, the support column is provided with 5 at least.

Compared with the prior art, the utility model has the following beneficial effects:

according to the utility model, the second coil pipe is arranged in the pipeline cavity of the reaction kettle body, and the first coil pipe is arranged on the spiral blade, so that the spiral blade can heat reactants in the reaction cavity while stirring and mixing the reactants, the reactants in the reaction cavity can be effectively heated, the reactants are heated more uniformly, the reaction rate is improved, and the product quality is greatly improved; in addition, the first sleeve and the second sleeve are arranged in the reaction cavity, and the water outlet and the water inlet are arranged on the rotating shaft, so that the rotating shaft can drive the spiral blade to rotate and simultaneously does not prevent the flow of water flow; finally, the heating water tank is independently arranged, so that the circulating heating of water flow can be realized, the temperature in the reaction kettle body is ensured, water resources can be saved, and the circulating utilization of the water resources is realized.

Drawings

The technical solution of the present utility model and its advantageous effects will be made apparent by the following detailed description of the specific embodiments of the present utility model with reference to the accompanying drawings.

FIG. 1 is a schematic structural diagram of an intelligent temperature control chemical reaction kettle;

FIG. 2 is a schematic diagram of the structure of an intelligent temperature-control chemical reaction kettle according to another view angle;

FIG. 3 is a cross-sectional view of an intelligent temperature control chemical reaction kettle according to the utility model;

FIG. 4 is a schematic view of the structure of the rotary shaft and the helical blade according to the present utility model;

fig. 5 is a cross-sectional view of the spindle and helical blade of the present utility model.

In the figure: 10. a reaction kettle body; 11. a reaction chamber; 111. a rotating shaft; 1111. a water outlet hole; 1112. a water inlet hole; 1113. a water flow channel; 112. a helical blade; 1121. a first coil; 113. a first sleeve; 114. a first water outlet pipe; 115. a second sleeve; 116. a first water inlet pipe; 117. a feeding hole; 118. a discharge pipe; 12. a conduit cavity; 121. a second coil; 122. a second water outlet pipe; 123. a second water inlet pipe; 13. a motor; 20. heating the water tank; 21. a heating wire; 22. a water pump; 23. a third water outlet pipe; 24. a third water inlet pipe; 25. a temperature adjustment panel; 30. a chassis; 40. and (5) supporting the column.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to fall within the scope of the utility model.

As shown in fig. 1-5, the intelligent temperature control chemical reaction kettle comprises a reaction kettle body 10, a heating water tank 20, a chassis 30 and a support column 40, wherein the reaction kettle body 10 and the heating water tank 20 are both positioned on the chassis 30 and fixedly connected with the chassis 30, water flow in the heating water tank 20 circularly flows in the reaction kettle body 10 for heat exchange, the lower side of the chassis 30 is fixedly connected with the support column 40, and the size and shape of the chassis 30 are matched with those of the reaction kettle body 10 and the heating water tank 20.

Wherein, the reaction kettle body 10 includes reaction chamber 11, pipeline chamber 12 and motor 13, and pipeline chamber 12 is located the outside of reaction chamber 11, and motor 13 is located the upside of reaction kettle body 10, and with reaction kettle body 10 fixed connection.

Wherein, be provided with pivot 111, helical blade 112, first sleeve pipe 113, first outlet pipe 114, second sleeve pipe 115 and first water inlet pipe 116 in the reaction chamber 11, the inside of pivot 111 is provided with water flow channel 1113, and the upper end and the lower extreme of pivot 111 are all sealed, the upper end lateral wall of pivot 111 is provided with apopore 1111, the lower extreme lateral wall of pivot 111 is provided with into water hole 1112, and apopore 1111 and income water hole 1112 all communicate with water flow channel 1113, the rivers in the pivot 111 can only be flowed in by income water hole 1112, flow in from apopore 1111.

Further, the first sleeve 113 is a cylindrical cavity, the first sleeve 113 is movably sleeved on the rotating shaft 111, the water outlet 1111 is located in the first sleeve 113, the diameter of the inner wall of the first sleeve 113 is larger than that of the rotating shaft 111, the upper side wall of the first sleeve 113 is fixedly connected with the inner wall of the reaction chamber 11, and the side wall of the first sleeve 113 is fixedly communicated with one end of the first water outlet pipe 114.

Further, the second sleeve 115 is a cylindrical cavity, the second sleeve 115 is movably sleeved on the rotating shaft 111, the water inlet 1112 is located in the second sleeve 115, the diameter of the inner wall of the second sleeve 115 is larger than that of the rotating shaft 111, the bottom wall of the second sleeve 115 is fixedly connected with the bottom wall of the reaction cavity 11, one end of the first water inlet pipe 116 penetrates through the reaction kettle body 10 and is fixedly communicated with the second sleeve 115, through the device, water flow in the first water inlet pipe 116 flows into the second sleeve 115, and after water flow in the second sleeve 115 is accumulated to a certain extent to reach the height of the water inlet 1112, the water flow enters the rotating shaft 111 from the water inlet 1112, flows out of the water outlet 1111 through the water flow channel 1113 and enters the first water outlet pipe 114.

The top end of the rotating shaft 111 sequentially penetrates through the first sleeve 113 and the reaction cavity 11 to be rotationally connected with the motor 13, the bottom end of the rotating shaft 111 stretches into the second sleeve 115 and is not connected with the bottom wall of the second sleeve 115, the motor 13 drives the rotating shaft 111 to rotate, it can be understood that the first sleeve 113 and the second sleeve 115 are fixedly connected with the reaction cavity 10 and are movably connected with the rotating shaft 111, and therefore the motor 13 does not drive the first sleeve 113 and the second sleeve 115 to rotate when driving the rotating shaft 111 to rotate.

Further, the spiral blade 112 is fixedly sleeved on the rotating shaft 111, the rotating shaft 111 drives the spiral blade 112 to rotate for stirring the reactant in the reaction chamber 11, the spiral blade 112 is provided with a first coil 1121, the first coil 1121 is communicated with the water flow channel 1113, and a part of water flow in the water flow channel 1113 can flow through the first coil 1121.

Wherein, the second coil pipe 121, the second water outlet pipe 122 and the second water inlet pipe 123 are arranged in the pipeline cavity 12, the upper end of the second coil pipe 121 is communicated with the second water outlet pipe 122, the lower end is communicated with the second water inlet pipe 123, and the water flow in the second water inlet pipe 123 flows out from the second water outlet pipe 122 after flowing through the second coil pipe 121.

Wherein, be provided with heater strip 21, suction pump 22, third outlet pipe 23, third water inlet pipe 24 and temperature regulation panel 25 in the heating water tank 20, heating water tank 20 is the cavity cylinder, heater strip 21 is located heating water tank 20, and with the inner wall fixed connection of heating water tank 20, the heater strip 21 can heat the water in the heating water tank 20, suction pump 22 and the diapire fixed connection of chassis 30, and the one end of suction pump 22 runs through chassis 30 in proper order, heating water tank 20's diapire is linked together with heating water tank 20, suction pump 22 is used for taking out water from heating water tank 20.

Further, the third water outlet pipe 23 is an "L" shaped water pipe, one end of the third water outlet pipe 23 is fixedly connected with the water pump 22, the other end is fixedly connected with the first water inlet pipe 116 vertically, the middle part of the third water outlet pipe 23 is fixedly connected with the second water inlet pipe 123 vertically, the water pump 22 pumps water from the heating water tank 20, and water flows into the third water outlet pipe 23 through the water pump 22 and then enters the first water inlet pipe 116 and the second water inlet pipe 123.

Further, the third water inlet pipe 24 is an "L" shaped water pipe, one end of the third water inlet pipe 24 penetrates through the upper side wall of the heating water tank 20 to be communicated with the heating water tank 20, the other end is vertically and fixedly connected with the first water outlet pipe 114, the middle part of the third water inlet pipe 24 is vertically and fixedly connected with the second water outlet pipe 122, and water flowing out from the first water outlet pipe 114 and the second water outlet pipe 122 flows into the heating water tank 20 through the third water inlet pipe 24 to be heated again, so that the recycling of water flow can be realized.

It will be appreciated that the water pump 22 has a pressure to the water flow, and the pressure is greater than the gravity of the water, so that the water flow can flow in from the first water inlet pipe 116 and the second water inlet pipe 123 and flow out from the first water outlet pipe 114 and the second water outlet pipe 122.

The temperature adjusting panel 25 is located on the upper end surface of the heating water tank 20, and the temperature adjusting panel 25 is used for adjusting and controlling the water temperature in the heating water tank 20.

Wherein, reaction chamber 11 still includes pan feeding hole 117 and discharging pipe 118, and pan feeding hole 117 is located the up end of reaction kettle body 10, and is linked together with reaction chamber 11, and discharging pipe 118 is located the lower terminal surface of reaction kettle body 10, and is linked together with reaction chamber 11.

Wherein, the support columns 40 are provided with at least 5 to increase the stability.

When the circulating heating device is used, reactants are firstly thrown into the reaction cavity 10 from the feeding holes 117, then the heating temperature on the temperature regulating panel 25 is set according to the properties of the reactants, water in the heating water tank 20 is heated, after the heating is completed, the water suction pump 22 is started, the water in the heating water tank 20 is pumped into the third water outlet pipe 23 and flows into the first water inlet pipe 116 and the second water inlet pipe 123, water flow in the first water inlet pipe 116 firstly flows into the second sleeve 115 and then flows into the water flow channel 1113 through the water inlet holes 1112, part of water flow in the water flow channel 1113 flows into the first coil 1121, the two water flows flow into the first sleeve 113 through the water outlet holes 1111 and finally flows into the first water outlet pipe 114, the water flow in the second water inlet pipe 123 flows into the second water outlet pipe 122 after flowing through the second coil 121, and the water flow in the first water outlet pipe 114 and the second water outlet pipe 122 flows into the heating water tank 20 through the third water inlet pipe 24 for reheating, and circulating heating of the water flow is realized; when heating, the motor 13 is started, and the motor 13 drives the spiral blade 112 to rotate through the rotating shaft 111, so that reactants in the reaction cavity 11 are stirred and mixed.

According to the utility model, the second coil pipe is arranged in the pipeline cavity of the reaction kettle body, and the first coil pipe is arranged on the spiral blade, so that the spiral blade can heat reactants in the reaction cavity while stirring and mixing the reactants, the reactants in the reaction cavity can be effectively heated, the reactants are heated more uniformly, the reaction rate is improved, and the product quality is greatly improved; in addition, the first sleeve and the second sleeve are arranged in the reaction cavity, and the water outlet and the water inlet are arranged on the rotating shaft, so that the rotating shaft can drive the spiral blade to rotate and simultaneously does not prevent the flow of water flow; finally, the heating water tank is independently arranged, so that the circulating heating of water flow can be realized, the temperature in the reaction kettle body is ensured, water resources can be saved, and the circulating utilization of the water resources is realized.

The foregoing is only the embodiments of the present utility model, and therefore, the patent scope of the utility model is not limited thereto, and all equivalent structures or equivalent processes using the descriptions of the present utility model and the accompanying drawings, or direct or indirect application in other related technical fields, are included in the scope of the utility model.

Claims (8)

1. The intelligent temperature control chemical reaction kettle is characterized by comprising a reaction kettle body, a heating water tank, a chassis and a support column, wherein the reaction kettle body and the heating water tank are both positioned on the chassis and fixedly connected with the chassis, and the lower side of the chassis is fixedly connected with the support column;

the reaction kettle body comprises a reaction cavity, a pipeline cavity and a motor, wherein the pipeline cavity is positioned at the outer side of the reaction cavity, and the motor is positioned at the upper side of the reaction kettle body and is fixedly connected with the reaction kettle body;

the reaction chamber is internally provided with a rotating shaft, a spiral blade, a first sleeve, a first water outlet pipe, a second sleeve and a first water inlet pipe, a water flow channel is arranged in the rotating shaft, the upper end and the lower end of the rotating shaft are both closed, the side wall of the upper end of the rotating shaft is provided with a water outlet hole, the side wall of the lower end of the rotating shaft is provided with a water inlet hole, and the water outlet hole and the water inlet hole are both communicated with the water flow channel;

the first sleeve is a cylindrical cavity, the first sleeve is movably sleeved on the rotating shaft, the water outlet hole is positioned in the first sleeve, the diameter of the inner wall of the first sleeve is larger than that of the rotating shaft, the upper side wall of the first sleeve is fixedly connected with the inner wall of the reaction cavity, the side wall of the first sleeve is fixedly communicated with one end of the first water outlet pipe, the second sleeve is a cylindrical cavity, the second sleeve is movably sleeved on the rotating shaft, the water inlet hole is positioned in the second sleeve, the diameter of the inner wall of the second sleeve is larger than that of the rotating shaft, the bottom wall of the second sleeve is fixedly connected with the bottom wall of the reaction cavity, one end of the first water inlet pipe penetrates through the reaction kettle body and is fixedly communicated with the second sleeve, the top end of the rotating shaft penetrates through the first sleeve in sequence, the reaction cavity is rotationally connected with the motor, and the bottom end of the rotating shaft stretches into the second sleeve and is not connected with the bottom wall of the second sleeve;

the spiral blade is fixedly sleeved on the rotating shaft, a first coil is arranged on the spiral blade, and the first coil is communicated with the water flow channel.

2. The intelligent temperature-control chemical reaction kettle according to claim 1, wherein a second coil pipe, a second water outlet pipe and a second water inlet pipe are arranged in the pipeline cavity, the upper end of the second coil pipe is communicated with the second water outlet pipe, and the lower end of the second coil pipe is communicated with the second water inlet pipe.

3. The intelligent temperature control chemical reaction kettle according to claim 2, wherein a heating wire, a water suction pump, a third water outlet pipe, a third water inlet pipe and a temperature adjusting panel are arranged in the heating water tank, the heating water tank is a hollow cylindrical cavity, the heating wire is positioned in the heating water tank and fixedly connected with the inner wall of the heating water tank, the water suction pump is fixedly connected with the bottom wall of the chassis, and one end of the water suction pump sequentially penetrates through the chassis, the bottom wall of the heating water tank is communicated with the heating water tank.

4. The intelligent temperature-control chemical reaction kettle according to claim 3, wherein the third water outlet pipe is an L-shaped water pipe, one end of the third water outlet pipe is fixedly connected with the water suction pump, the other end of the third water outlet pipe is vertically and fixedly connected with the first water inlet pipe, and the middle part of the third water outlet pipe is vertically and fixedly connected with the second water inlet pipe.

5. The intelligent temperature-control chemical reaction kettle according to claim 3, wherein the third water inlet pipe is an L-shaped water pipe, one end of the third water inlet pipe penetrates through the upper side wall of the heating water tank and is communicated with the heating water tank, the other end of the third water inlet pipe is fixedly connected with the first water outlet pipe vertically, and the middle part of the third water inlet pipe is fixedly connected with the second water outlet pipe vertically.

6. The intelligent temperature-controlled chemical reaction kettle according to claim 3, wherein the temperature-adjusting panel is located on the upper end face of the heating water tank.

7. The intelligent temperature-controlled chemical reaction kettle according to claim 1, wherein the reaction cavity further comprises a feeding hole and a discharging pipe, the feeding hole is positioned on the upper end face of the reaction kettle body and is communicated with the reaction cavity, and the discharging pipe is positioned on the lower end face of the reaction kettle body and is communicated with the reaction cavity.

8. The intelligent temperature-controlled chemical reaction kettle according to claim 1, wherein at least 5 support columns are arranged.