A uniform dropwise reaction tank for viscous building material auxiliaries
By using a heating device and high-temperature gas to prevent the viscous building material additives from condensing, and combining a metering pump and mixing components, the problems of clogging and condensation during the dripping process of viscous building material additives are solved, achieving uniform dripping and efficient mixing.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- SHANXI JINRONGYUAN BUILDING MATERIALS TECHNOLOGY CO LTD
- Filing Date
- 2026-05-20
- Publication Date
- 2026-06-26
AI Technical Summary
Existing viscous building material additives tend to adhere to the inner wall of the discharge pipe during the dripping process, causing blockages. They also tend to solidify as the temperature drops, affecting the dripping effect.
Design a uniform dropping reaction vessel including a heating device, a dropping component, an anti-clogging component, and a mixing component. The heating device maintains the material temperature, high-temperature gas is used to prevent condensation, a metering pump enables precise dropping, and the mixing component improves mixing efficiency.
It enables precise and uniform dripping of viscous building material additives, avoids clogging, improves mixing efficiency, and ensures smooth and effective dripping process.
Smart Images

Figure CN122273458A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of reaction technology for viscous building material additives, specifically to a uniform dropwise reaction vessel for viscous building material additives. Background Technology
[0002] Viscous building material additives are a class of high-viscosity paste, slurry or gel functional additives used in the production, processing and construction of building materials. They are mostly viscous mixtures of water-based or oil-based systems. They are core auxiliary materials for improving the performance of building materials and optimizing production and construction processes. They are widely compatible with various building materials such as concrete, mortar, coatings, waterproof membranes, and adhesives. Most existing viscous building material additives have straight or angled discharge pipes designed for drip-feeding structures. Viscous building material additives have poor fluidity and tend to adhere strongly to the inner wall of the discharge pipe when falling under gravity during the drip-feeding process. Some material will adhere to the pipe wall and gradually accumulate. Since the discharge pipe of the drip-feeding structure is generally exposed to the outside, the additive is prone to temperature drop due to the outside temperature during the transfer to the discharge pipe, which will further increase the viscosity and continuously worsen the fluidity, resulting in material accumulation inside the discharge pipe. Summary of the Invention
[0003] The purpose of this invention is to provide a uniform dropwise reaction vessel for viscous building material additives, so as to solve the problems mentioned in the background art.
[0004] To solve the above-mentioned technical problems, the present invention is achieved through the following technical solution: This invention relates to a uniform dripping reaction vessel for viscous building material additives, comprising a reaction vessel with a heating device on its surface and a sealed filling port on its top. Raw materials are added to the interior of the reaction vessel through the filling port for reaction. After addition, the vessel is sealed. The heating device heats the reaction vessel to prevent the viscous building material additive from solidifying due to temperature drop during the stirring reaction. The invention also includes: A dripping component, comprising a metering pump, wherein the inlet end of the metering pump is connected to an inlet pipe, the outlet end of the metering pump is connected to a base frame, and the bottom of the base frame is connected to an outlet pipe; An anti-clogging component includes a sleeve, the inner wall of the end of the sleeve is fixedly connected to the surface of the feed pipe, the surface of the sleeve is connected to a connecting pipe, the end of the connecting pipe away from the sleeve is connected to a bottom pipe, and the inner wall of the end of the bottom pipe is fixedly connected to the surface of the discharge pipe. A mixing component, comprising a rotating rod, a reinforcing rod fixedly connected to the surface of the rotating rod, and a spiral stirring blade fixedly connected to the surface of the reinforcing rod.
[0005] Furthermore, a support is fixedly connected to the lower surface of the reaction vessel, a discharge valve is connected to the bottom of the reaction vessel, the bottom of the support extends to the bottom of the reaction vessel, and the heating device is located above the support.
[0006] Furthermore, the dripping component includes a fixing ring, the inner wall of which is fixedly connected to the upper surface of the reaction vessel, a support frame fixedly connected to the surface of the fixing ring, the top of the support frame fixedly connected to the bottom of the metering pump, a heating storage tank fixedly connected to the top of the fixing ring, and a limit frame fixedly connected to the surface of the base frame.
[0007] Furthermore, the end of the feed pipe away from the metering pump passes through the heating storage tank and extends to the lower interior of the heating storage tank. The top of the heating storage tank is connected to a feeding rack. The limiting rack is connected to the base frame. The bottom of the discharge pipe passes through the reaction tank and extends to the interior of the reaction tank. The bottom of the discharge pipe is arc-shaped.
[0008] Furthermore, the anti-clogging component includes an air pump, the bottom of which is fixedly connected to the top of the support frame. A filter is inserted into the air inlet of the air pump, and a bend is connected to the air outlet of the air pump. A T-shaped pipe is slidably connected to the inner wall of the bend away from the air pump. A sealing plate is fixedly connected to the surface of the T-shaped pipe, and an automatic valve is connected to the surface of the bend. A heater is connected to the end of the automatic valve away from the bend, and a transmission pipe is connected to the end of the heater away from the automatic valve. The end of the transmission pipe away from the heater is connected to the upper surface of the bottom pipe. The bottom of the heater is fixedly connected to the top of the support frame, and an electric telescopic frame is fixedly connected to the top of the support frame. The telescopic end of the electric telescopic frame is fixedly connected to the surface of the sealing plate.
[0009] Furthermore, the two ends of the sleeve are located at the output end of the metering pump and the top of the heating storage tank, respectively. The top of the bottom tube is in contact with the bottom of the base frame. The end of the T-shaped tube away from the bend passes through the limiting frame and extends into the interior of the limiting frame. The bottom of the inner wall of the limiting frame is horizontally set with the bottom of the inner wall of the base frame. The end of the sleeve away from the metering pump is connected to a one-way valve. The one-way valve is used to discharge the gas in the sleeve, so that the heated gas can be continuously pumped into the interior of the sleeve and the bottom tube.
[0010] Furthermore, the bottom of the T-shaped tube contacts the bottom of the limiting frame, and two sealing plates are provided, which are symmetrically arranged with the bottom of the T-shaped tube as the center, and the surface of the sealing plate contacts the inner wall of the limiting frame.
[0011] Furthermore, the mixing component includes a shaft, the center of the shaft surface is fixedly connected to the inner wall of the reinforcing rod, a mounting bracket is fixedly connected to the end of the shaft, a flexible scraper is fixedly connected to the inner wall of the mounting bracket, a round rod is fixedly connected to the surface of the mounting bracket, a flexible scraper is fixedly connected to the surface of the round rod, a power device is installed on the top of the reaction vessel, the output end of the power device is fixedly connected to the top of the rotating rod, and a rotating frame is fixedly connected to the upper surface of the rotating rod.
[0012] Furthermore, the bottom of the rotating rod penetrates through the reaction vessel and extends into the interior of the reaction vessel. The bottom of the rotating rod is rotatably connected to the bottom of the inner wall of the reaction vessel. The surface of the rotating frame is adapted to the bottom surface of the discharge pipe. There are two spiral stirring blades. The surfaces of the first flexible scraper and the second flexible scraper are in contact with the inner wall of the reaction vessel.
[0013] The present invention has the following beneficial effects: During operation, the metering pump of this invention draws a fixed amount of viscous building material additives into the base frame through the feed pipe, and then drips the viscous building material additives into the reaction tank through the discharge pipe for reaction. This achieves precise and uniform dripping and mixing of the viscous additives. The discharge pipe is perpendicular to the inner wall of the reaction tank, and the viscous building material additives drip rapidly into the reaction tank under the action of vertical gravity, avoiding the accumulation of viscous building material additives in the discharge pipe and causing blockage.
[0014] This invention utilizes a sleeve and a bottom pipe to store high-temperature gas on the surface of the feed pipe and the discharge pipe. The high-temperature gas heats the feed pipe and the discharge pipe, preventing viscous building material additives from condensing inside the feed pipe during transmission and causing blockages that would affect the dripping effect of the viscous building material additives. At the same time, the bottom pipe heats the viscous building material additives inside the discharge pipe, allowing the viscous building material additives entering the discharge pipe to be rapidly dripped into the reaction vessel for reaction processing.
[0015] In this invention, the gas in the bend is transmitted to the inside of the discharge pipe through the T-shaped pipe. The viscous building material additive inside the discharge pipe will drip rapidly into the inside of the reaction tank under the action of the gas, avoiding the viscous building material additive from condensing in the discharge pipe. When the electric telescopic frame retracts, it pulls the T-shaped pipe into the inside of the limiting frame. The limiting frame is sealed by the sealing plate to prevent the viscous building material additive from entering the inside of the limiting frame. Without affecting the dripping operation of the viscous building material additive, the gas is used to push the viscous building material additive into the inside of the reaction tank, preventing the viscous building material additive from condensing inside the discharge pipe.
[0016] In this invention, the spiral stirring blades contact the material and push it along the length of the rotating rod, pushing the material at the bottom upwards along the wall. At the same time, the material in the central area flows downwards due to spatial compression, causing the material to exchange and fold, thereby improving the mixing efficiency of viscous building material additives. The spiral stirring blades exert a squeezing and tearing effect on the material, breaking the agglomerated structure of the viscous building material additives, improving the dispersion effect, and accelerating the mixing efficiency of the viscous building material additives.
[0017] Of course, any product implementing this invention does not necessarily need to achieve all of the advantages described above at the same time. Attached Figure Description
[0018] To more clearly illustrate the technical solutions of the embodiments of the present invention, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0019] Figure 1 This is a schematic diagram of the overall structure of the present invention; Figure 2 This is a schematic diagram of the reaction vessel structure of the present invention; Figure 3 This is a schematic cross-sectional view of the reaction vessel of the present invention; Figure 4 This is a schematic diagram of the overall structure of the dripping component of the present invention; Figure 5 This is another schematic diagram of the dropping component of the present invention; Figure 6 This is a schematic diagram of the overall structure of the anti-clogging component of the present invention; Figure 7 This is another structural schematic diagram of the anti-clogging component of the present invention; Figure 8 This is a schematic cross-sectional view of the limiting frame of the present invention; Figure 9 This is a schematic diagram of the overall structure of the hybrid component of the present invention; Figure 10 This is another structural schematic diagram of the hybrid component of the present invention.
[0020] The attached diagram lists the components represented by each number as follows: In the diagram: 1. Reaction vessel; 2. Heating device; 3. Support; 4. Discharge valve; 5. Dropping component; 6. Anti-clogging component; 7. Mixing component; 10. Fixing ring; 11. Heated storage tank; 12. Feed pipe; 13. Metering pump; 14. Support frame; 15. Base frame; 16. Limiting frame; 17. Discharge pipe; 20. Sleeve; 21. Transfer pipe; 22. Bottom pipe; 23. Electric telescopic frame; 24. Automatic valve; 25. Heater; 26. Bend; 27. Air pump; 28. Filter frame; 29. Connecting pipe; 30. T-shaped pipe; 31. Sealing plate; 40. Power unit; 41. Shaft; 42. Rotating rod; 43. Spiral stirring blade; 44. Reinforcing rod; 45. Mounting frame; 46. Flexible scraper one; 47. Round rod; 48. Flexible scraper two; 49. Rotating frame. Detailed Implementation
[0021] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0022] Please see Figures 1-10 As shown, the present invention is a reaction vessel for uniformly adding viscous building material additives, comprising a reaction vessel 1, a heating device 2 disposed on the surface of the reaction vessel 1, and further comprising: The dripping component 5 includes a metering pump 13, the feed end of which is connected to a feed pipe 12, the discharge end of which is connected to a base frame 15, and the bottom of the base frame 15 is connected to a discharge pipe 17. Anti-blocking component 6 includes a sleeve 20, the inner wall of the end of the sleeve 20 is fixedly connected to the surface of the feed pipe 12, the surface of the sleeve 20 is connected to a connecting pipe 29, the end of the connecting pipe 29 away from the sleeve 20 is connected to a bottom pipe 22, and the inner wall of the end of the bottom pipe 22 is fixedly connected to the surface of the discharge pipe 17. The mixing component 7 includes a rotating rod 42, a reinforcing rod 44 fixedly connected to the surface of the rotating rod 42, and a spiral stirring blade 43 fixedly connected to the surface of the reinforcing rod 44.
[0023] A support 3 is fixedly connected to the lower surface of the reaction vessel 1, and a discharge valve 4 is connected to the bottom of the reaction vessel 1. The bottom of the support 3 extends to the bottom of the reaction vessel 1, and the heating device 2 is located above the support 3.
[0024] The dripping component 5 includes a fixing ring 10, the inner wall of which is fixedly connected to the upper surface of the reaction vessel 1. A support frame 14 is fixedly connected to the surface of the fixing ring 10, the top of which is fixedly connected to the bottom of the metering pump 13. A heating storage tank 11 is fixedly connected to the top of the fixing ring 10. A limit frame 16 is fixedly connected to the surface of the base frame 15. During operation, the metering pump 13 draws a fixed amount of viscous building material additive through the feed pipe 12 into the interior of the base frame 15. The viscous building material additive is then dripped into the interior of the reaction vessel 1 through the discharge pipe 17 for reaction, achieving precise and uniform dripping and mixing of the viscous additive. The discharge pipe 17 is perpendicular to the inner wall of the reaction vessel 1, and the viscous building material additive quickly drips into the interior of the reaction vessel 1 under the action of vertical gravity, preventing the viscous building material additive from accumulating inside the discharge pipe 17 and causing blockage.
[0025] The end of the feed pipe 12 away from the metering pump 13 passes through the heating storage tank 11 and extends to the lower interior of the heating storage tank 11. The top of the heating storage tank 11 is connected to the feeding rack. The limiting rack 16 is connected to the base frame 15. The bottom of the discharge pipe 17 passes through the reaction tank 1 and extends to the interior of the reaction tank 1. The bottom of the discharge pipe 17 is arc-shaped.
[0026] The anti-clogging component 6 includes an air pump 27. The bottom of the air pump 27 is fixedly connected to the top of the support frame 14. A filter frame 28 is inserted into the air inlet of the air pump 27. A bend 26 is connected to the air outlet of the air pump 27. A T-shaped pipe 30 is slidably connected to the inner wall of the end of the bend 26 away from the air pump 27. A sealing plate 31 is fixedly connected to the surface of the T-shaped pipe 30. An automatic valve 24 is connected to the surface of the bend 26. A heater 25 is connected to the end of the automatic valve 24 away from the bend 26. A transmission pipe 21 is connected to the end of the heater 25 away from the automatic valve 24. The end of the transmission pipe 21 away from the heater 25 is connected to the upper surface of the bottom pipe 22. The bottom of the heater 25 is fixedly connected to the top of the support frame 14. An electric telescopic frame 23 is fixedly connected to the top of the support frame 14. The telescopic end of the electric telescopic frame 23 is fixedly connected to the surface of the sealing plate 31. High-temperature gas is stored on the surface of the feed pipe 12 and the discharge pipe 17 using the sleeve 20 and the bottom pipe 22. The high-temperature gas heats the feed pipe 12 and the discharge pipe 17 to prevent the viscous building material additives from condensing inside the feed pipe 12 during transmission and causing blockage, which would affect the dripping effect of the viscous building material additives. At the same time, the bottom pipe 22 heats the viscous building material additives inside the discharge pipe 17, so that the viscous building material additives entering the discharge pipe 17 are quickly dripped into the interior of the reaction tank 1 for reaction processing.
[0027] The two ends of the sleeve 20 are located at the output end of the metering pump 13 and the top of the heating storage tank 11, respectively. The top of the bottom tube 22 contacts the bottom of the base frame 15. The end of the T-shaped tube 30 away from the bend 26 passes through the limiting frame 16 and extends into the interior of the limiting frame 16. The bottom of the inner wall of the limiting frame 16 is horizontally set with the bottom of the inner wall of the base frame 15.
[0028] The bottom of the T-shaped tube 30 contacts the bottom of the limiting frame 16. There are two sealing plates 31, which are symmetrically arranged with the bottom of the T-shaped tube 30 as the center. The surface of the sealing plate 31 contacts the inner wall of the limiting frame 16.
[0029] The mixing component 7 includes a shaft 41, the center of which is fixedly connected to the inner wall of a reinforcing rod 44. A mounting bracket 45 is fixedly connected to the end of the shaft 41. A flexible scraper 46 is fixedly connected to the inner wall of the mounting bracket 45. A round rod 47 is fixedly connected to the surface of the mounting bracket 45. A flexible scraper 48 is fixedly connected to the surface of the round rod 47. A power unit 40 is installed on the top of the reaction tank 1. The output end of the power unit 40 is fixedly connected to the top of a rotating rod 42. A rotating frame 49 is fixedly connected to the upper surface of the rotating rod 42. The spiral stirring blade 43 contacts the material and pushes the material along the length of the rotating rod 42, pushing the bottom material upward along the wall. At the same time, the material in the central area flows downward due to spatial compression, causing the material to exchange and fold, improving the mixing efficiency of viscous building material additives. The spiral stirring blade 43 exerts a squeezing and tearing effect on the material, breaking the agglomerated structure of the viscous building material additives, improving the dispersion effect, and accelerating the mixing efficiency of the viscous building material additives.
[0030] The bottom of the rotating rod 42 penetrates through the reaction vessel 1 and extends into the interior of the reaction vessel 1. The bottom of the rotating rod 42 is rotatably connected to the bottom of the inner wall of the reaction vessel 1. The surface of the rotating frame 49 is adapted to the bottom surface of the discharge pipe 17. There are two spiral stirring blades 43. The surfaces of flexible scraper 1 46 and flexible scraper 2 48 are in contact with the inner wall of the reaction vessel 1.
[0031] During use, other materials required for the reaction of the viscous building material additive are added to the inside of reaction tank 1 through the filling port. The viscous building material additive is then added to the inside of heating storage tank 11 through the feeding rack. Heating storage tank 11 heats and maintains the temperature of the viscous building material additive to prevent it from cooling and condensing inside the tank, thus affecting the dripping effect. When it is necessary to drip the viscous building material additive into the inside of reaction tank 1, the metering pump 13 is started to begin operation. 13 During operation, a fixed amount of viscous building material additive is drawn into the base frame 15 through the feed pipe 12, and then dripped into the reaction tank 1 through the discharge pipe 17 for reaction operation, so as to achieve precise and uniform dripping and mixing of viscous additive. The discharge pipe 17 is perpendicular to the inner wall of the reaction tank 1, and the viscous building material additive drops quickly into the reaction tank 1 under the action of vertical gravity, so as to avoid the viscous building material additive accumulating in the discharge pipe 17 and causing blockage. When the feed pipe 12 and discharge pipe 17 transport viscous building material additives, the air pump 27 is started to begin operation. The gas generated by the air pump 27 enters the interior of the heater 25 through the automatic valve 24. During operation, the temperature inside the heater 25 rises. At this time, the gas temperature rises after being heated by the heater 25. The heated gas then enters the interior of the bottom pipe 22 through the transmission pipe 21. The gas inside the bottom pipe 22 enters the interior of the sleeve 20 through the connecting pipe 29. The sleeve 20 and the bottom pipe 22 are used to transport the viscous building material additives. High-temperature gas is stored on the surface of the feed pipe 12 and the discharge pipe 17. The high-temperature gas is used to heat the feed pipe 12 and the discharge pipe 17 to prevent the viscous building material additives from condensing inside the feed pipe 12 during transmission and causing blockage, which would affect the dripping effect of the viscous building material additives. At the same time, the bottom pipe 22 heats the viscous building material additives inside the discharge pipe 17, so that the viscous building material additives entering the discharge pipe 17 are quickly dripped into the reaction tank 1 for reaction processing. When it is necessary to push the viscous building material additive in the discharge pipe 17 into the interior of the reaction tank 1, the automatic valve 24 is activated to close, and at the same time, the electric telescopic frame 23 is activated to push the T-shaped pipe 30 into the interior of the base frame 15. When the bottom of the T-shaped pipe 30 aligns with the top of the discharge pipe 17, the bottom of the T-shaped pipe 30 will seal with the top of the discharge pipe 17. At this time, the gas in the bend 26 will be transmitted to the interior of the discharge pipe 17 through the T-shaped pipe 30. The viscous building material additive inside the discharge pipe 17 will drip rapidly into the interior of the reaction tank 1 under the action of the gas, preventing the viscous building material additive from condensing. In the case of the discharge pipe 17, when the electric telescopic frame 23 retracts, it pulls the T-shaped pipe 30 into the interior of the limiting frame 16. The limiting frame 16 is sealed by the sealing plate 31 to prevent the viscous building material additives from entering the interior of the limiting frame 16. Without affecting the dripping operation of the viscous building material additives, the gas is used to push the viscous building material additives into the interior of the reaction tank 1 to prevent the viscous building material additives from condensing inside the discharge pipe 17. A filter frame 28 is provided at the air inlet end of the air pump 27 to prevent impurities from entering the interior of the reaction tank 1 through the air pump 27 and affecting the reaction of the viscous building material additives. After the viscous building material additive enters the reaction tank 1, the power unit 40 is activated to drive the rotating rod 42 to rotate inside the reaction tank 1. As the rotating rod 42 rotates, it drives the spiral stirring blade 43 to rotate via the reinforcing rod 44. When the spiral stirring blade 43 rotates, it contacts the material and pushes the material along the length of the rotating rod 42, pushing the material at the bottom upwards along the wall. Simultaneously, the material in the central area flows downwards due to spatial compression, causing material exchange and folding, improving the mixing efficiency of the viscous building material additive. The spiral stirring blade 43 exerts a squeezing and tearing effect on the material, breaking down the agglomerated structure of the viscous building material additive and improving dispersion. The effect is to accelerate the mixing efficiency of viscous building material additives. When the reinforcing rod 44 rotates, it drives the flexible scraper 1 46 and flexible scraper 2 48 to rotate through the shaft 41. The flexible scraper 1 46 and flexible scraper 2 48 rotate in contact with the tank wall and continuously scrape off the residue on the inner wall, so as to avoid the viscous building material additives from condensing on the inner wall of the reaction tank 1 and affecting the reaction effect. When the rotating frame 49 rotates with the rotating rod 42, it will clean the bottom of the discharge pipe 17 to prevent the viscous building material additives from condensing at the outlet of the discharge pipe 17.
[0032] The preferred embodiments of the present invention disclosed above are merely illustrative of the invention. These preferred embodiments do not exhaustively describe all details, nor do they limit the invention to the specific implementations described. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of the invention, thereby enabling those skilled in the art to better understand and utilize the invention. The invention is limited only by the claims and their full scope and equivalents.
Claims
1. A uniform dropwise addition reaction vessel for viscous building material additives, comprising a reaction vessel (1), wherein a heating device (2) is provided on the surface of the reaction vessel (1), characterized in that, Also includes: The dripping component (5) includes a metering pump (13), the feed end of the metering pump (13) is connected to a feed pipe (12), the discharge end of the metering pump (13) is connected to a base frame (15), and the bottom of the base frame (15) is connected to a discharge pipe (17). Anti-blocking component (6), the anti-blocking component (6) includes a sleeve (20), the inner wall of the end of the sleeve (20) is fixedly connected to the surface of the feed pipe (12), the surface of the sleeve (20) is connected to a connecting pipe (29), the end of the connecting pipe (29) away from the sleeve (20) is connected to a bottom pipe (22), the inner wall of the end of the bottom pipe (22) is fixedly connected to the surface of the discharge pipe (17); The mixing component (7) includes a rotating rod (42), a reinforcing rod (44) is fixedly connected to the surface of the rotating rod (42), and a spiral stirring blade (43) is fixedly connected to the surface of the reinforcing rod (44).
2. The uniform dropwise addition reaction vessel for viscous building material additives according to claim 1, characterized in that: A bracket (3) is fixedly connected to the lower surface of the reaction vessel (1), and a discharge valve (4) is connected to the bottom of the reaction vessel (1). The bottom of the bracket (3) extends to the bottom of the reaction vessel (1), and the heating device (2) is located above the bracket (3).
3. The uniform dropwise addition reaction vessel for viscous building material additives according to claim 2, characterized in that: The dripping component (5) includes a fixing ring (10), the inner wall of which is fixedly connected to the upper surface of the reaction vessel (1), a support frame (14) is fixedly connected to the surface of the fixing ring (10), the top of the support frame (14) is fixedly connected to the bottom of the metering pump (13), a heating storage tank (11) is fixedly connected to the top of the fixing ring (10), and a limit frame (16) is fixedly connected to the surface of the base frame (15).
4. The uniform dropwise addition reaction vessel for viscous building material additives according to claim 3, characterized in that: The end of the feed pipe (12) away from the metering pump (13) passes through the heating storage tank (11) and extends to the lower interior of the heating storage tank (11). The top of the heating storage tank (11) is connected to a feeding rack. The limiting frame (16) is connected to the base frame (15). The bottom of the discharge pipe (17) passes through the reaction tank (1) and extends to the interior of the reaction tank (1). The bottom of the discharge pipe (17) is arc-shaped.
5. A uniformly dropping reaction vessel for viscous building material additives according to claim 4, characterized in that: The anti-clogging component (6) includes an air pump (27), the bottom of which is fixedly connected to the top of the support frame (14). A filter frame (28) is inserted into the air inlet of the air pump (27). A bend (26) is connected to the air outlet of the air pump (27). A T-shaped pipe (30) is slidably connected to the inner wall of the end of the bend (26) away from the air pump (27). A sealing plate (31) is fixedly connected to the surface of the T-shaped pipe (30). An automatic valve (24) is connected to the surface of the bend (26). 24) A heater (25) is connected to the end away from the bend (26). A transmission pipe (21) is connected to the end of the heater (25) away from the automatic valve (24). The end of the transmission pipe (21) away from the heater (25) is connected to the upper surface of the bottom pipe (22). The bottom of the heater (25) is fixedly connected to the top of the support frame (14). An electric telescopic frame (23) is fixedly connected to the top of the support frame (14). The telescopic end of the electric telescopic frame (23) is fixedly connected to the surface of the sealing plate (31).
6. A uniformly dropping reaction vessel for viscous building material additives according to claim 5, characterized in that: The two ends of the sleeve (20) are located at the output end of the metering pump (13) and the top of the heating storage tank (11), respectively. The top of the bottom tube (22) is in contact with the bottom of the base frame (15). The end of the T-shaped tube (30) away from the bend (26) passes through the limiting frame (16) and extends into the interior of the limiting frame (16). The bottom of the inner wall of the limiting frame (16) and the bottom of the inner wall of the base frame (15) are set horizontally.
7. A uniformly dropping reaction vessel for viscous building material additives according to claim 6, characterized in that: The bottom of the T-shaped tube (30) is in contact with the bottom of the limiting frame (16). There are two sealing plates (31). The two sealing plates (31) are symmetrically arranged with the bottom of the T-shaped tube (30) as the center. The surface of the sealing plate (31) is in contact with the inner wall of the limiting frame (16).
8. A uniformly dropping reaction vessel for viscous building material additives according to claim 7, characterized in that: The mixing component (7) includes a shaft (41), the center of the surface of the shaft (41) is fixedly connected to the inner wall of the reinforcing rod (44), the end of the shaft (41) is fixedly connected to a mounting bracket (45), the inner wall of the mounting bracket (45) is fixedly connected to a flexible scraper (46), the surface of the mounting bracket (45) is fixedly connected to a round rod (47), the surface of the round rod (47) is fixedly connected to a flexible scraper (48), the top of the reaction vessel (1) is equipped with a power device (40), the output end of the power device (40) is fixedly connected to the top of the rotating rod (42), and the upper surface of the rotating rod (42) is fixedly connected to a rotating frame (49).
9. A uniform dropwise addition reaction vessel for viscous building material additives according to claim 8, characterized in that: The bottom of the rotating rod (42) penetrates the reaction tank (1) and extends into the interior of the reaction tank (1). The bottom of the rotating rod (42) is rotatably connected to the bottom of the inner wall of the reaction tank (1). The surface of the rotating frame (49) is adapted to the bottom surface of the discharge pipe (17). There are two spiral stirring blades (43). The surfaces of the first flexible scraper (46) and the second flexible scraper (48) are in contact with the inner wall of the reaction tank (1).