A sorbitan monooleate synthesis reaction system
By designing a sorbitan monooleate synthesis reaction system that includes stirring and pressurizing mechanisms, the problem of easy solidification of sorbitan monooleate was solved, achieving the effects of preventing solidification and simplifying cleaning, thereby improving production efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- 山东金奥银雅化工有限公司
- Filing Date
- 2023-04-12
- Publication Date
- 2026-06-26
AI Technical Summary
After synthesis, sorbitan monooleate tends to solidify into lumps, causing solid particles to adhere to the inner wall of the reactor, affecting cleaning and reprocessing efficiency.
A sorbitan monooleate synthesis reaction system including a stirring mechanism and a pressurizing mechanism was designed. The stirring component and heating wire prevent solidification, and the pressurizing mechanism regulates the temperature and space to prevent solidification.
It effectively prevents sorbitan monooleate from solidifying, simplifies the cleaning process, and improves production efficiency and equipment utilization.
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Figure CN116586011B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of emulsifier production technology, specifically to a sorbitan monooleate synthesis reaction system. Background Technology
[0002] Sorbitan monooleate is an amber-colored, viscous, oily liquid or a pale yellow to brownish-yellow, hard, waxy solid in the form of small beads or flakes. It has a distinctive, mild odor and is insoluble in water, but disperses into an emulsion solution in hot water. It is soluble in hot ethanol, toluene, carbon tetrachloride, and other organic solvents.
[0003] The synthesis of sorbitan monooleate is relatively simple. It is usually prepared by esterification of oleic acid and dehydrated sorbitol and is a food additive.
[0004] Since sorbitan monooleate solidifies into lumps after synthesis and cooling, if production is not continued, many solid particles will adhere to the side walls and discharge port of the reactor, or even clump together, which will greatly hinder the cleaning of the reactor when production resumes. Summary of the Invention
[0005] In view of the shortcomings of the existing technology, the purpose of this invention is to provide a sorbitan monooleate synthesis reaction system to solve the problems mentioned in the background technology.
[0006] To achieve the above objectives, the present invention provides the following technical solution:
[0007] A sorbitan monooleate synthesis reaction system includes a support box, a processing box disposed within the support box, the processing box being fixedly connected to the support box, and further includes:
[0008] A stirring mechanism is disposed inside the processing chamber. The stirring mechanism is used to prevent sorbitan monooleate from curing. The stirring mechanism includes a first transmission component, a stirring component, and a power component. The first transmission component is movably connected to the power component. The stirring component is symmetrically arranged about the first transmission component and is fixedly connected to the first transmission component.
[0009] The first transmission assembly includes a first transmission member, a first transmission groove, a second transmission member, and a second transmission groove. The first transmission member is symmetrically arranged with respect to the second transmission member. The first transmission groove is symmetrically arranged on both sides of the first transmission member. The first transmission groove is movably connected to the power assembly. The second transmission member has a second transmission groove symmetrically arranged on its outer wall. The second transmission groove is movably connected to the power assembly.
[0010] The stirring assembly includes a rotating rod, a connecting sleeve, and stirring blades. The rotating rod is fixedly connected to the first transmission component. The rotating rod is symmetrically arranged about the second transmission component. The top of the rotating rod is provided with a connecting sleeve. Stirring blades are symmetrically arranged on both sides of the connecting sleeve. The stirring blades are fixedly connected to the connecting sleeve. A heating wire is provided inside the stirring blades.
[0011] The power assembly includes an electric rotating shaft, a mounting sleeve, a lever, a connecting rod, and a lever blade. The electric rotating shaft is connected to the mounting sleeve, and the mounting sleeve is fixedly connected to the lever. The lever is symmetrically arranged about the mounting sleeve and is movably connected to the second transmission groove. The mounting sleeve is fixedly connected to the connecting rod, and the connecting rod is symmetrically arranged about the mounting sleeve. The connecting rod is connected to the lever blade, and the lever blade is movably connected to the first transmission groove. Heating wires are provided inside the lever blade and the lever.
[0012] A pressurizing mechanism, one end of which is connected to the support box, the pressurizing mechanism passing through the processing box, and the pressurizing mechanism being used to heat and raise the temperature inside the processing box;
[0013] An electric rotating shaft drives the mounting sleeve to rotate, which in turn drives the lever and connecting rod to rotate. The connecting rod drives the second transmission component to rotate via an inclined second transmission groove, which in turn drives the first transmission component to rotate. The two sets of levers are arranged alternately with the leaf blades so that the leaf blades contact the first transmission groove. The connecting rod drives the first transmission groove to rotate via the leaf blades, which in turn drives the first transmission component to rotate. The rotating leaf blades stir sorbitan monooleate. A heating wire inside the leaf blades is used to prevent sorbitan monooleate from solidifying.
[0014] The first transmission component drives the rotating rod to rotate, and the rotating rod drives the stirring blade to rotate through the connecting sleeve. The rotating stirring blade stirs the sorbitan monooleate, and the heating wire set in the stirring blade is used to prevent the sorbitan monooleate from solidifying.
[0015] As a further aspect of the present invention, the pressurizing mechanism includes:
[0016] A first pressurizing component, one end of which is fixedly connected to the inner wall of the supporting box, the first pressurizing component penetrating the processing box, and the first pressurizing component being movably connected to the processing box; and
[0017] The second transmission assembly is movably connected to the first pressurizing assembly. One end of the second transmission assembly is fixedly connected to the outer wall of the support box, and the other end of the second transmission assembly is movably connected to the second pressurizing assembly. The second pressurizing assembly passes through the processing box and is movably connected to the processing box.
[0018] As a further aspect of the present invention, the first pressurizing component includes:
[0019] A telescopic rod, one end of which is fixedly connected to the inner wall of the support box, and the other end of which is fixedly connected to a first mounting plate, the first mounting plate being movably connected to the inner wall of the support box;
[0020] A first fixing rod, one end of which is fixedly connected to the first mounting plate, and the first fixing rod penetrates the processing housing; and
[0021] A first pressure plate is movably connected to the inner wall of the processing box, and the first pressure plate is fixedly connected to the first fixing rod.
[0022] As a further aspect of the present invention, the second transmission component includes:
[0023] A first transmission rod, one end of which is connected to the first mounting plate, and the other end of which is connected to a second transmission rod;
[0024] A limiting rod, the outer side of which is fixedly connected to the outer wall of the support box, the limiting rod passing through the second transmission rod, and the limiting rod being movably connected to the second transmission rod; and
[0025] The third transmission rod has one end movably connected to the second transmission rod and the other end movably connected to the second pressurizing assembly.
[0026] As a further aspect of the present invention, the second pressurizing component includes:
[0027] A slider is movably connected to the third transmission rod, and the slider is movably connected to a slide groove, which is symmetrically arranged on both sides of the support box.
[0028] A second mounting plate is connected to the slider and is movably connected to the inner wall of the support box.
[0029] A second fixing rod, one end of which is fixedly connected to the first mounting plate, and the second fixing rod passes through the processing housing; and
[0030] The second pressure plate is movably connected to the inner wall of the processing box, and the second pressure plate is fixedly connected to the second fixing rod.
[0031] As a further embodiment of the present invention, flexible hoses are symmetrically arranged at the bottom of the processing box, the flexible hoses penetrate the support box and the second mounting plate, a connecting pipe is provided at the bottom of the support box, the flexible hoses are connected to the connecting pipes, and the flexible hoses are fixedly connected to the processing box.
[0032] As a further embodiment of the present invention, the connecting pipe is fixedly connected to the discharge disc, the discharge disc is provided with a plurality of distributing ports, the distributing ports are evenly distributed about the discharge disc, and a metering instrument is provided in each distributing port.
[0033] In summary, the embodiments of the present invention have the following beneficial effects compared with the prior art:
[0034] An electric rotating shaft drives the mounting sleeve to rotate, which in turn drives the lever and connecting rod to rotate. The connecting rod drives the second transmission component to rotate via an inclined second transmission groove, which in turn drives the first transmission component to rotate. The two sets of levers are arranged alternately with the blades so that the blades contact the first transmission groove. The connecting rod drives the first transmission groove to rotate via the blades, which in turn drives the first transmission component to rotate. The rotating blades stir sorbitan monooleate. A heating wire inside the blades is used to prevent sorbitan monooleate from solidifying, thus completing the vertical stirring.
[0035] The first transmission component drives the rotating rod to rotate, and the rotating rod drives the stirring blade to rotate through the connecting sleeve. The rotating stirring blade stirs the sorbitan monooleate. The heating wire set in the stirring blade is used to prevent the sorbitan monooleate from solidifying, thus completing the horizontal stirring. At the same time, the action of the pressurizing mechanism can adjust the space inside the processing box. Compressing the space inside the processing box can increase the temperature inside the processing box, effectively preventing the sorbitan monooleate from solidifying, and can also further stir the sorbitan monooleate.
[0036] To more clearly illustrate the structural features and effects of the present invention, the present invention will be described in detail below with reference to the accompanying drawings and specific embodiments. Attached Figure Description
[0037] Figure 1 This is a schematic diagram of an embodiment of the invention.
[0038] Figure 2 This is a schematic diagram of the stirring mechanism in an embodiment of the invention.
[0039] Figure 3 This is a side view of the stirring mechanism in an embodiment of the invention.
[0040] Figure 4 This is a side view of the second pressurizing component in an embodiment of the invention.
[0041] Figure 5 This is a top view of the discharge disc in an embodiment of the invention.
[0042] Reference numerals: 1-Support box, 2-Processing box, 3-Feed inlet, 4-Stirring mechanism, 41-First transmission assembly, 411-First transmission component, 412-First transmission groove, 413-Second transmission component, 414-Second transmission groove, 42-Stirring assembly, 421-Rotating rod, 422-Connecting sleeve, 423-Stirring blade, 43-Power assembly, 431-Electric rotating shaft, 432-Mounting sleeve, 433-Pulley, 434-Connecting rod, 435-Pulley, 5-Pressure mechanism, 51-First 511-Telescopic rod, 512-First mounting plate, 513-First fixing rod, 514-First pressure plate, 52-Second transmission assembly, 521-First transmission rod, 522-Second transmission rod, 523-Limiting rod, 524-Third transmission rod, 53-Second pressure assembly, 531-Slider, 532-Second mounting plate, 533-Second fixing rod, 534-Second pressure plate, 6-Slide groove, 7-Hose, 8-Connecting pipe, 9-Discharge disc, 10-Distribution port, 11-Quantitative meter. Detailed Implementation
[0043] To make the objectives, technical solutions, and advantages of this invention clearer, the invention will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative and not intended to limit the invention.
[0044] The specific implementation of the present invention will be described in detail below with reference to specific embodiments.
[0045] In one embodiment, a sorbitan monooleate synthesis reaction system is described in [reference needed]. Figures 1-5 The system includes a support housing 1, a processing housing 2 housed within the support housing 1, and the processing housing 2 being fixedly connected to the support housing 1. It also includes:
[0046] A stirring mechanism 4 is disposed inside the processing chamber 2. The stirring mechanism 4 is used to prevent sorbitan monooleate from curing. The stirring mechanism 4 includes a first transmission component 41, a stirring component 42, and a power component 43. The first transmission component 41 is movably connected to the power component 43. The stirring component 42 is symmetrically arranged about the first transmission component 41 and is fixedly connected to the first transmission component 41.
[0047] The first transmission assembly 41 includes a first transmission member 411, a first transmission groove 412, a second transmission member 413, and a second transmission groove 414. The first transmission member 411 is symmetrically arranged with respect to the second transmission member 413. The first transmission groove 412 is symmetrically arranged on both sides of the first transmission member 411. The first transmission groove 412 is movably connected to the power assembly 43. The second transmission member 413 has the second transmission groove 414 symmetrically arranged on its outer wall. The second transmission groove 414 is movably connected to the power assembly 43.
[0048] The stirring assembly 42 includes a rotating rod 421, a connecting sleeve 422, and stirring blades 423. The rotating rod 421 is fixedly connected to the first transmission member 411. The rotating rod 421 is symmetrically arranged about the second transmission member 413. The top of the rotating rod 421 is provided with the connecting sleeve 422. The stirring blades 423 are symmetrically arranged on both sides of the connecting sleeve 422. The stirring blades 423 are fixedly connected to the connecting sleeve 422. A heating wire is provided inside the stirring blades 423.
[0049] The power assembly 43 includes an electric rotating shaft 431, a mounting sleeve 432, a lever 433, a connecting rod 434, and a paddle 435. The electric rotating shaft 431 is connected to the mounting sleeve 432. The mounting sleeve 432 is fixedly connected to the lever 433. The lever 433 is symmetrically arranged about the mounting sleeve 432. The lever 433 is movably connected to the second transmission groove 414. The mounting sleeve 432 is fixedly connected to the connecting rod 434. The connecting rod 434 is symmetrically arranged about the mounting sleeve 432. The connecting rod 434 is connected to the paddle 435. The paddle 435 is movably connected to the first transmission groove 412. Heating wires are provided inside the paddle 435 and the lever 433.
[0050] A pressurizing mechanism 5 is provided, one end of which is connected to the support box 1. The pressurizing mechanism 5 passes through the processing box 2 and is used to heat and raise the temperature inside the processing box 2.
[0051] The electric rotating shaft 431 drives the mounting sleeve 432 to rotate, the mounting sleeve 432 drives the lever 433 and the connecting rod 434 to rotate, the connecting rod 434 drives the second transmission component 413 to rotate through the inclined second transmission groove 414, the second transmission component 413 drives the first transmission component 411 to rotate, the two sets of levers 433 are arranged alternately with the leaf 435 so that the leaf 435 contacts the first transmission groove 412, the connecting rod 434 drives the first transmission groove 412 to rotate through the leaf 435, the first transmission groove 412 drives the first transmission component 411 to rotate, the rotating leaf 435 stirs the sorbitan monooleate, and the heating wire set in the leaf 435 is used to prevent the sorbitan monooleate from solidifying;
[0052] The first transmission component 411 drives the rotating rod 421 to rotate, and the rotating rod 421 drives the stirring blade 423 to rotate through the connecting sleeve 422. The rotating stirring blade 423 stirs the sorbitan monooleate, and the heating wire set in the stirring blade 423 is used to prevent the sorbitan monooleate from solidifying.
[0053] In this embodiment, the stirring mechanism 4 can be installed in the processing box 2 by a support rod or a fixing frame. The stirring mechanism 4 can stir and mix the raw materials fed into the processing box 2 from the feed inlet 3, and at the same time prevent sorbitan monooleate from solidifying.
[0054] The electric rotating shaft 431 drives the mounting sleeve 432 to rotate, the mounting sleeve 432 drives the lever 433 and the connecting rod 434 to rotate, the connecting rod 434 drives the second transmission component 413 to rotate through the inclined second transmission groove 414, the second transmission component 413 drives the first transmission component 411 to rotate, the two sets of levers 433 are arranged alternately with the blades 435 so that the blades 435 contact the first transmission groove 412, the connecting rod 434 drives the first transmission groove 412 to rotate through the blades 435, the first transmission groove 412 drives the first transmission component 411 to rotate, the rotating blades 435 stir sorbitan monooleate, the heating wire set in the blades 435 is used to prevent sorbitan monooleate from solidifying, and vertical stirring is completed;
[0055] The first transmission component 411 drives the rotating rod 421 to rotate, and the rotating rod 421 drives the stirring blade 423 to rotate through the connecting sleeve 422. The rotating stirring blade 423 stirs the sorbitan monooleate. The heating wire set in the stirring blade 423 is used to prevent the sorbitan monooleate from solidifying, thus completing the horizontal stirring. At the same time, the action of the pressurizing mechanism 5 can adjust the space inside the processing box 2. Compressing the space inside the processing box 2 can increase the temperature inside the processing box 2, effectively preventing the sorbitan monooleate from solidifying, and can also further stir the sorbitan monooleate.
[0056] In one embodiment, see Figures 1-5 The pressurizing mechanism 5 includes:
[0057] A first pressurizing component 51, one end of which is fixedly connected to the inner wall of the support housing 1, the first pressurizing component 51 penetrates the processing housing 2, and the first pressurizing component 51 is movably connected to the processing housing 2; and
[0058] The second transmission component 52 is movably connected to the first pressurizing component 51. One end of the second transmission component 52 is fixedly connected to the outer wall of the support box 1, and the other end of the second transmission component 52 is movably connected to the second pressurizing component 53. The second pressurizing component 53 passes through the processing box 2 and is movably connected to the processing box 2.
[0059] Further, see Figures 1-5 The first pressurization component 51 includes:
[0060] Telescopic rod 511, one end of which is fixedly connected to the inner wall of the support box 1, and the other end of which is fixedly connected to the first mounting plate 512, the first mounting plate 512 being movably connected to the inner wall of the support box 1;
[0061] A first fixing rod 513, one end of which is fixedly connected to the first mounting plate 512, and the first fixing rod 513 penetrates the processing box 2; and
[0062] The first pressure plate 514 is movably connected to the inner wall of the processing box 2, and the first pressure plate 514 is fixedly connected to the first fixing rod 513.
[0063] Further, see Figures 1-5 The second transmission assembly 52 includes:
[0064] A first transmission rod 521, one end of which is connected to the first mounting plate 512, and the other end of which is connected to the second transmission rod 522;
[0065] A limiting rod 523 is fixedly connected to the outer wall of the support box 1 on its outer side. The limiting rod 523 passes through the second transmission rod 522 and is movably connected to the second transmission rod 522.
[0066] The third transmission rod 524 has one end movably connected to the second transmission rod 522 and the other end movably connected to the second pressurizing assembly 53.
[0067] Further, see Figures 1-5 The second pressurization component 53 includes:
[0068] The slider 531 is movably connected to the third transmission rod 524 and the slider 531 is movably connected to the slide groove 6, which is symmetrically arranged on both sides of the support box 1.
[0069] The second mounting plate 532 is connected to the slider 531 and is movably connected to the inner wall of the support box 1.
[0070] A second fixing rod 533, one end of which is fixedly connected to the first mounting plate 512, and the second fixing rod 533 penetrates the processing housing 2; and
[0071] The second pressure plate 534 is movably connected to the inner wall of the processing box 2, and the second pressure plate 534 is fixedly connected to the second fixing rod 533.
[0072] In this embodiment, the telescopic rod 511 drives the first mounting plate 512 to move downward. The first mounting plate 512 drives the first pressure plate 514 to move downward via the first fixing rod 513. At the same time, the downward-moving first mounting plate 512 drives the first transmission rod 521 to move downward. The first transmission rod 521 drives the second transmission rod 522 to rotate about the limiting rod 523. Under the limiting action of the limiting rod 523, the second transmission rod 522 lifts the third transmission rod 524. The third transmission rod 524 drives the second mounting plate 532 to move upward via the slider 531. The second mounting plate 532 drives the second pressure plate 534 to move upward via the second fixing rod 533, so that the second pressure plate 534 and the first pressure plate 514 move closer to each other, completing the stirring and heating of sorbitan monooleate in the processing box 2.
[0073] The telescopic rod 511 drives the first mounting plate 512 to move upward. The first mounting plate 512 drives the first pressure plate 514 to move upward via the first fixing rod 513. At the same time, the downward-moving first mounting plate 512 drives the first transmission rod 521 to move upward. The first transmission rod 521 drives the second transmission rod 522 to rotate about the limiting rod 523. Under the limiting action of the limiting rod 523, the second transmission rod 522 presses down the third transmission rod 524. The third transmission rod 524 drives the second mounting plate 532 to move downward via the slider 531. The second mounting plate 532 drives the second pressure plate 534 to move downward via the second fixing rod 533, so that the second pressure plate 534 and the first pressure plate 514 move away from each other.
[0074] In one embodiment, see Figures 1-5 The bottom of the processing box 2 is symmetrically provided with flexible hoses 7, which pass through the support box 1 and the second mounting plate 532. The bottom of the support box 1 is provided with a connecting pipe 8, and the flexible hoses 7 are connected to the connecting pipe 8. The flexible hoses 7 are fixedly connected to the processing box 2.
[0075] Further, see Figures 1-5The connecting pipe 8 is fixedly connected to the discharge disc 9. The discharge disc 9 is provided with a plurality of distributing ports 10. The distributing ports 10 are evenly distributed about the discharge disc 9. A metering instrument 11 is provided inside the distributing port 10.
[0076] In this embodiment, the hose 7 is fixedly connected to the second pressure plate 534. The second pressure plate 534, which moves up and down, will drive the hose 7 to move up and down. The stirred sorbitan monooleate passes through the hose 7 and is guided to the connecting pipe 8. The connecting pipe 8 is guided to the dispensing port 10 through the discharge disc 9. After the sorbitan monooleate is stirred, multiple dispensing ports 10 can be used to receive the material, thereby improving efficiency. At the same time, the metering instrument 11 set in the dispensing port 10 can control the discharge amount.
[0077] The working principle of this invention is:
[0078] The electric rotating shaft 431 drives the mounting sleeve 432 to rotate, the mounting sleeve 432 drives the lever 433 and the connecting rod 434 to rotate, the connecting rod 434 drives the second transmission component 413 to rotate through the inclined second transmission groove 414, the second transmission component 413 drives the first transmission component 411 to rotate, the two sets of levers 433 are arranged alternately with the blades 435 so that the blades 435 contact the first transmission groove 412, the connecting rod 434 drives the first transmission groove 412 to rotate through the blades 435, the first transmission groove 412 drives the first transmission component 411 to rotate, the rotating blades 435 stir sorbitan monooleate, the heating wire set in the blades 435 is used to prevent sorbitan monooleate from solidifying, and vertical stirring is completed;
[0079] The first transmission component 411 drives the rotating rod 421 to rotate, and the rotating rod 421 drives the stirring blade 423 to rotate through the connecting sleeve 422. The rotating stirring blade 423 stirs the sorbitan monooleate. The heating wire set in the stirring blade 423 is used to prevent the sorbitan monooleate from solidifying, thus completing the horizontal stirring. At the same time, the action of the pressurizing mechanism 5 can adjust the space inside the processing box 2. Compressing the space inside the processing box 2 can increase the temperature inside the processing box 2, effectively preventing the sorbitan monooleate from solidifying, and can also further stir the sorbitan monooleate.
[0080] The telescopic rod 511 drives the first mounting plate 512 to move downward. The first mounting plate 512 drives the first pressure plate 514 to move downward through the first fixing rod 513. At the same time, the downward-moving first mounting plate 512 drives the first transmission rod 521 to move downward. The first transmission rod 521 drives the second transmission rod 522 to rotate about the limiting rod 523. Under the limiting action of the limiting rod 523, the second transmission rod 522 lifts the third transmission rod 524. The third transmission rod 524 drives the second mounting plate 532 to move upward through the slider 531. The second mounting plate 532 drives the second pressure plate 534 to move upward through the second fixing rod 533, so that the second pressure plate 534 and the first pressure plate 514 move closer to each other, completing the stirring and heating of sorbitan monooleate in the processing box 2.
[0081] The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention. Any modifications, equivalent substitutions, and improvements made within the spirit and principles of the present invention should be included within the protection scope of the present invention.
Claims
1. A sorbitan monooleate synthesis reaction system, comprising a support box, wherein a processing box is disposed within the support box, and the processing box is fixedly connected to the support box, characterized in that, Also includes: A stirring mechanism is disposed inside the processing chamber. The stirring mechanism is used to prevent sorbitan monooleate from curing. The stirring mechanism includes a first transmission component, a stirring component, and a power component. The first transmission component is movably connected to the power component. The stirring component is symmetrically arranged about the first transmission component and is fixedly connected to the first transmission component. The first transmission assembly includes a first transmission member, a first transmission groove, a second transmission member, and a second transmission groove. The first transmission member is symmetrically arranged with respect to the second transmission member. The first transmission groove is symmetrically arranged on both sides of the first transmission member. The first transmission groove is movably connected to the power assembly. The second transmission member has a second transmission groove symmetrically arranged on its outer wall. The second transmission groove is movably connected to the power assembly. The stirring assembly includes a rotating rod, a connecting sleeve, and stirring blades. The rotating rod is fixedly connected to the first transmission component. The rotating rod is symmetrically arranged about the second transmission component. The top of the rotating rod is provided with a connecting sleeve. Stirring blades are symmetrically arranged on both sides of the connecting sleeve. The stirring blades are fixedly connected to the connecting sleeve. A heating wire is provided inside the stirring blades. The power assembly includes an electric rotating shaft, a mounting sleeve, a lever, a connecting rod, and a lever blade. The electric rotating shaft is connected to the mounting sleeve, and the mounting sleeve is fixedly connected to the lever. The lever is symmetrically arranged about the mounting sleeve and is movably connected to the second transmission groove. The mounting sleeve is fixedly connected to the connecting rod, and the connecting rod is symmetrically arranged about the mounting sleeve. The connecting rod is connected to the lever blade, and the lever blade is movably connected to the first transmission groove. Heating wires are provided inside the lever blade and the lever. A pressurizing mechanism, one end of which is connected to the support box, the pressurizing mechanism passing through the processing box, and the pressurizing mechanism being used to heat and raise the temperature inside the processing box; An electric rotating shaft drives the mounting sleeve to rotate, which in turn drives the lever and connecting rod to rotate. The connecting rod drives the second transmission component to rotate via an inclined second transmission groove, which in turn drives the first transmission component to rotate. The two sets of levers are arranged alternately with the leaf blades so that the leaf blades contact the first transmission groove. The connecting rod drives the first transmission groove to rotate via the leaf blades, which in turn drives the first transmission component to rotate. The rotating leaf blades stir sorbitan monooleate. A heating wire inside the leaf blades is used to prevent sorbitan monooleate from solidifying. The first transmission component drives the rotating rod to rotate, and the rotating rod drives the stirring blade to rotate through the connecting sleeve. The rotating stirring blade stirs the sorbitan monooleate, and the heating wire set in the stirring blade is used to prevent the sorbitan monooleate from solidifying.
2. The sorbitan monooleate synthesis reaction system according to claim 1, characterized in that, The pressurization mechanism includes: A first pressurizing component, one end of which is fixedly connected to the inner wall of the supporting box, the first pressurizing component penetrating the processing box, and the first pressurizing component being movably connected to the processing box; and The second transmission assembly is movably connected to the first pressurizing assembly. One end of the second transmission assembly is fixedly connected to the outer wall of the support box, and the other end of the second transmission assembly is movably connected to the second pressurizing assembly. The second pressurizing assembly passes through the processing box and is movably connected to the processing box.
3. The sorbitan monooleate synthesis reaction system according to claim 2, characterized in that, The first pressurization component includes: A telescopic rod, one end of which is fixedly connected to the inner wall of the support box, and the other end of which is fixedly connected to a first mounting plate, the first mounting plate being movably connected to the inner wall of the support box; A first fixing rod, one end of which is fixedly connected to the first mounting plate, and the first fixing rod penetrates the processing housing; and A first pressure plate is movably connected to the inner wall of the processing box, and the first pressure plate is fixedly connected to the first fixing rod.
4. The sorbitan monooleate synthesis reaction system according to claim 3, characterized in that, The second transmission assembly includes: A first transmission rod, one end of which is connected to the first mounting plate, and the other end of which is connected to a second transmission rod; A limiting rod, the outer side of which is fixedly connected to the outer wall of the support box, the limiting rod passing through the second transmission rod, and the limiting rod being movably connected to the second transmission rod; and The third transmission rod has one end movably connected to the second transmission rod and the other end movably connected to the second pressurizing assembly.
5. The sorbitan monooleate synthesis reaction system according to claim 4, characterized in that, The second pressurization component includes: A slider is movably connected to the third transmission rod, and the slider is movably connected to a slide groove, which is symmetrically arranged on both sides of the support box. A second mounting plate is connected to the slider and is movably connected to the inner wall of the support box. A second fixing rod, one end of which is fixedly connected to the second mounting plate, and the second fixing rod passes through the processing housing; and The second pressure plate is movably connected to the inner wall of the processing box, and the second pressure plate is fixedly connected to the second fixing rod.
6. The sorbitan monooleate synthesis reaction system according to claim 1, characterized in that, The bottom of the processing box is symmetrically provided with flexible hoses, which pass through the support box and the second mounting plate. The bottom of the support box is provided with a connecting pipe, and the flexible hoses are connected to the connecting pipes. The flexible hoses are fixedly connected to the processing box.
7. The sorbitan monooleate synthesis reaction system according to claim 6, characterized in that, The connecting pipe is fixedly connected to the discharge disc, which has a number of distributing ports that are evenly distributed around the discharge disc. A metering instrument is installed inside each distributing port.