Non-oxidizing sterilizing agent concentration kettle

Abstract

The utility model relates to the technical fields of chemical industry especially, it can make the moisture in bactericide evaporate fast under low temperature, avoid the high temperature to cause the damage to bactericide, convenient to use, reliability and practicality are high, including bottom plate, support, cauldron body and charging pipe, the cauldron body is fixedly installed on the bottom plate upper end through the support, is provided with the chamber in the cauldron body, the upper portion of cauldron body is provided with the charging pipe that communicates with the chamber, is provided with the valve on the charging pipe, still including electric heater, stirring mechanism, vacuum mechanism and spraying mechanism, the electric heater is fixedly installed on the cauldron body, and the output of electric heater is located in the lower part of cauldron body chamber, and the stirring mechanism is installed on the cauldron body, and the stirring mechanism has the function of stirring, and the vacuum mechanism is installed on the cauldron body, and the vacuum mechanism has the function of vacuum, and the spraying mechanism is installed on the cauldron body.

Description

Technical Field

[0001] This utility model relates to the technical field of chemical industry, and in particular to a non-oxidizing bactericide concentration kettle. Background Technology

[0002] Water-based non-oxidizing bactericides require concentration during production to reduce water content. In the prior art, utility model patent application number 201820122914.9 discloses a concentration vessel, mainly composed of a shell, a stirring device, and a heater. When concentrating liquid, the liquid is added to the shell, then heated by the heater while simultaneously agitated by the stirring device, causing the water in the liquid to evaporate and thus concentrate the liquid. However, this method has the following problems: the liquid needs to be heated above the boiling point of water for rapid evaporation and concentration. Excessive heating temperature can also affect the composition of the bactericide in the liquid, impacting its effectiveness and making it inconvenient to use. Therefore, a device that allows for rapid evaporation and concentration of water at low temperatures is needed. Utility Model Content

[0003] To solve the above-mentioned technical problems, this utility model provides a non-oxidizing bactericide concentration kettle that allows the water in the bactericide to evaporate rapidly at low temperatures, avoiding damage to the bactericide caused by high temperatures. It is convenient to use, reliable, and highly practical.

[0004] This utility model relates to a non-oxidizing bactericide concentration vessel, comprising a base plate, a support, a vessel body, and a feeding pipe. The vessel body is fixedly mounted on the upper part of the base plate via the support. A chamber is provided inside the vessel body, and a feeding pipe communicating with the chamber is located on the upper part of the vessel body. A valve is installed on the feeding pipe. The vessel also includes a heater, a stirring mechanism, a vacuum mechanism, and a spraying mechanism. The heater is fixedly mounted on the vessel body, with its output end located at the lower part of the vessel body's chamber. The stirring mechanism is mounted on the vessel body and functions as a stirrer. The vacuum mechanism is mounted on the vessel body and functions as a vacuum system. The spraying mechanism is mounted on the vessel body. This vessel is used for non-oxidizing bactericide concentration. During agent concentration, the non-oxidizing bactericide is first added to the reactor chamber through the feeding pipe. Then, the valve on the feeding pipe is closed, and the electric heater is turned on to heat the bactericide in the reactor chamber. At the same time, the vacuum mechanism is turned on to create negative pressure in the reactor chamber, lowering the boiling point of water in the reactor chamber and promoting the evaporation of water in the bactericide. This allows the water in the bactericide to evaporate rapidly at low temperatures. Simultaneously, the stirring mechanism is turned on to ensure that the bactericide is heated evenly, further promoting the evaporation of water in the bactericide. This method allows the water in the bactericide to evaporate rapidly at low temperatures, avoiding damage to the bactericide caused by high temperatures. It is convenient to use and has high reliability and practicality.

[0005] Preferably, the vacuum mechanism includes a vacuum pump and an exhaust pipe. The vacuum pump is fixedly installed on the vessel body, and the input end of the vacuum pump is connected to the upper part of the vessel body chamber. An exhaust pipe is provided on the vacuum pump. When the vessel body chamber is under negative pressure, the vacuum pump is turned on, and the air in the vessel body chamber is transported to the outside through the exhaust pipe, so that the vessel body chamber is under negative pressure, thereby lowering the boiling point of water in the vessel body chamber.

[0006] Preferably, the stirring mechanism includes a rotating shaft, multiple stirring blades, and a driving mechanism. The rotating shaft is rotatably mounted on a base plate and a vessel body. The multiple stirring blades are all fixedly mounted on the rotating shaft and are located within the cavity of the vessel body. The driving mechanism is mounted on the base plate and is used to drive the rotating shaft to rotate. When heating the non-oxidizing bactericide within the vessel body cavity, the driving mechanism is activated, causing the rotating shaft to drive the multiple stirring blades to rotate, promoting the movement of the non-oxidizing bactericide, ensuring uniform heating of the non-oxidizing bactericide, and promoting the evaporation of moisture in the non-oxidizing bactericide.

[0007] Preferably, the drive mechanism includes bevel gear A, bevel gear B, a drive shaft, a fixed plate, and a drive motor. Bevel gear A is fixedly mounted on the rotating shaft, and bevel gear A meshes with bevel gear B. Bevel gear B is fixedly mounted on the drive shaft, and the drive shaft is rotatably mounted on the fixed plate. The input end of the drive shaft is connected to the drive motor. Both the fixed plate and the drive motor are fixedly mounted on the base plate. When the drive shaft rotates, the drive motor is turned on, and the drive motor drives bevel gear B to rotate bevel gear A through the drive shaft, which in turn drives the rotating shaft to rotate. This facilitates the rotation of the drive shaft.

[0008] Preferably, the spraying mechanism includes a delivery pump, a delivery pipe, a spray pipe, and multiple nozzles. The delivery pump is installed on the vessel body, with its input end connected to the lower part of the vessel body chamber. The output end of the delivery pump is connected to the spray pipe via the delivery pipe. The spray pipe is installed on the upper part of the vessel body chamber, and multiple nozzles are provided on the spray head. When evaporating and concentrating the bactericide in the vessel body chamber, the delivery pump is turned on, causing the bactericide in the vessel body chamber to be sprayed sequentially through the delivery pipe, the spray pipe, and the multiple nozzles into the vessel body chamber. This promotes the relative movement between the bactericide and the air in the vessel body chamber, promotes the evaporation of moisture in the bactericide, and improves the concentration efficiency.

[0009] Preferably, it also includes multiple electric heating lamps, all of which are fixedly installed on the upper part of the vessel cavity. Each of the multiple electric heating lamps is equipped with a transparent waterproof cover, and the multiple electric heating lamps are evenly distributed around the circumference of the vessel cavity. When multiple nozzles spray the bactericide into the vessel cavity, the multiple electric heating lamps are turned on to heat the sprayed bactericide, promote the evaporation of water in the bactericide, and improve the efficiency of concentration.

[0010] Preferably, a thermometer is provided on the vessel body; this facilitates the monitoring of the temperature inside the vessel body cavity.

[0011] Compared with the prior art, the advantages of this utility model are: it can make the water in the bactericide evaporate quickly at low temperature, avoiding the damage of the bactericide by high temperature, making it convenient to use, reliable and practical. Attached Figure Description

[0012] Figure 1 This is a cross-sectional structural schematic diagram of the present invention;

[0013] Figure 2 This is a schematic diagram of the first isometric structure of this utility model;

[0014] Figure 3 This is a schematic diagram of the second isometric structure of this utility model;

[0015] Figure 4 This is a structural diagram of the spraying mechanism and the electric heating lamp;

[0016] Figure 5 This is a schematic diagram of the stirring mechanism.

[0017] The following are labels in the attached diagram: 1. Base plate; 2. Support; 3. Kettle body; 4. Feed pipe; 5. Electric heater; 6. Vacuum pump; 7. Exhaust pipe; 8. Rotating shaft; 9. Stirring blade; 10. Bevel gear A; 11. Bevel gear B; 12. Drive shaft; 13. Fixing plate; 14. Drive motor; 15. Conveying pump; 16. Conveying pipe; 17. Spraying pipe; 18. Nozzle; 19. Electric heating lamp. Detailed Implementation

[0018] To facilitate understanding of this utility model, a more complete description will be given below with reference to the accompanying drawings. This utility model can be implemented in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided to make the disclosure of this utility model more thorough and complete.

[0019] Example 1

[0020] like Figures 1 to 5This utility model's non-oxidizing bactericide concentration kettle includes a bottom plate 1, a support 2, a kettle body 3, a feeding pipe 4, an electric heater 5, a stirring mechanism, a vacuum mechanism, and a spraying mechanism. The kettle body 3 is fixedly mounted on the upper end of the bottom plate 1 via the support 2. A chamber is provided inside the kettle body 3. The feeding pipe 4, communicating with the chamber, is located on the upper part of the kettle body 3. A valve is installed on the feeding pipe 4. The electric heater 5 is fixedly mounted on the kettle body 3, with its output end located at the lower part of the chamber in the kettle body 3. The stirring mechanism is mounted on the kettle body 3 and has a stirring function. The vacuum mechanism is mounted on the kettle body 3 and has a vacuum function. The spraying mechanism is mounted on the kettle body 3. For non-oxidizing bactericides... When concentrating chemical bactericides, the non-oxidizing bactericide is first added to chamber 3 of the vessel through the feeding pipe 4. Then, the valve on the feeding pipe 4 is closed, and the electric heater 5 is turned on to heat the bactericide in chamber 3. At the same time, the vacuum mechanism is turned on to create a negative pressure in chamber 3, which lowers the boiling point of water in chamber 3 and promotes the evaporation of water in the bactericide. This allows the water in the bactericide to evaporate quickly at low temperatures. Simultaneously, the stirring mechanism is turned on to ensure that the bactericide is heated evenly, further promoting the evaporation of water in the bactericide. This method allows the water in the bactericide to evaporate quickly at low temperatures, avoiding damage to the bactericide caused by high temperatures. It is convenient to use and has high reliability and practicality.

[0021] like Figure 2 and Figure 3 The vacuum mechanism includes a vacuum pump 6 and an exhaust pipe 7. The vacuum pump 6 is fixedly installed on the vessel body 3. The input end of the vacuum pump 6 is connected to the upper part of the chamber of the vessel body 3. The vacuum pump 6 is equipped with an exhaust pipe 7. When the chamber of the vessel body 3 is under negative pressure, the vacuum pump 6 is turned on, so that the air in the chamber of the vessel body 3 is transported to the outside through the exhaust pipe 7, so that the chamber of the vessel body 3 is under negative pressure, thereby lowering the boiling point of water in the chamber of the vessel body 3.

[0022] like Figure 1 and Figure 5 The stirring mechanism includes a rotating shaft 8, multiple stirring blades 9, and a driving mechanism. The rotating shaft 8 is rotatably mounted on the base plate 1 and the vessel body 3. The multiple stirring blades 9 are all fixedly mounted on the rotating shaft 8 and are located in the cavity of the vessel body 3. The driving mechanism is mounted on the base plate 1 and is used to drive the rotating shaft 8 to rotate. When heating the non-oxidizing bactericide in the cavity of the vessel body 3, the driving mechanism is turned on, so that the rotating shaft 8 drives the multiple stirring blades 9 to rotate, promoting the movement of the non-oxidizing bactericide, so that the non-oxidizing bactericide is heated evenly, and promoting the evaporation of water in the non-oxidizing bactericide.

[0023] like Figure 5The drive mechanism includes a bevel gear A10, a bevel gear B11, a drive shaft 12, a fixed plate 13, and a drive motor 14. The bevel gear A10 is fixedly mounted on the rotating shaft 8 and meshes with the bevel gear B11. The bevel gear B11 is fixedly mounted on the drive shaft 12, and the drive shaft 12 is rotatably mounted on the fixed plate 13. The input end of the drive shaft 12 is connected to the drive motor 14. Both the fixed plate 13 and the drive motor 14 are fixedly mounted on the base plate 1. When the drive shaft 8 rotates, the drive motor 14 is turned on. The drive motor 14 drives the bevel gear A10 to rotate through the drive shaft 12, and the bevel gear A10 drives the rotating shaft 8 to rotate, thus facilitating the rotation of the drive shaft 8.

[0024] like Figure 1 and Figure 4 The spraying mechanism includes a delivery pump 15, a delivery pipe 16, a spray pipe 17, and multiple nozzles 18. The delivery pump 15 is installed on the vessel body 3, and its input end is connected to the lower part of the chamber of the vessel body 3. The output end of the delivery pump 15 is connected to the spray pipe 17 through the delivery pipe 16. The spray pipe 17 is installed on the upper part of the chamber of the vessel body 3, and multiple nozzles 18 are provided on the nozzles 18. When evaporating and concentrating the bactericide in the chamber of the vessel body 3, the delivery pump 15 is turned on, so that the bactericide in the chamber of the vessel body 3 is sprayed into the chamber of the vessel body 3 in sequence through the delivery pipe 16, the spray pipe 17, and the multiple nozzles 18. This promotes the relative movement between the bactericide and the air in the chamber of the vessel body 3, promotes the evaporation of water in the bactericide, and improves the concentration efficiency.

[0025] A thermometer is installed on the vessel body 3; this feature facilitates the monitoring of the temperature inside the vessel body 3.

[0026] Example 2

[0027] like Figure 4 Based on Example 1, multiple electric heating lamps 19 are added. The multiple electric heating lamps 19 are all fixedly installed on the upper part of the 3-chamber of the vessel body. Each of the multiple electric heating lamps 19 is equipped with a transparent waterproof cover. The multiple electric heating lamps 19 are evenly distributed around the circumference of the 3-chamber of the vessel body. When the multiple nozzles 18 spray the bactericide into the 3-chamber of the vessel body, the multiple electric heating lamps 19 are turned on to heat the sprayed bactericide, promote the evaporation of water in the bactericide, and improve the efficiency of concentration.

[0028] The non-oxidizing bactericide concentration kettle of this utility model consists of a kettle body 3, an electric heater 5, a vacuum pump 6, a stirring plate 9, a delivery pump 15, and an electric heating lamp 19, all of which are commercially available. Technical personnel in this industry only need to install and operate it according to the accompanying instruction manual, without requiring any creative work from those skilled in the art.

[0029] The above description is only a preferred embodiment of the present utility model. It should be noted that for those skilled in the art, several improvements and modifications can be made without departing from the technical principles of the present utility model, and these improvements and modifications should also be considered within the protection scope of the present utility model.

Claims

1. A non-oxidizing bactericide concentrator, comprising a bottom plate (1), a support (2), a vessel body (3), and a feeding pipe (4), wherein the vessel body (3) is fixedly mounted on the upper end of the bottom plate (1) via the support (2), a chamber is provided inside the vessel body (3), and a feeding pipe (4) communicating with the chamber is provided on the upper part of the vessel body (3), and a valve is provided on the feeding pipe (4); characterized in that, It also includes an electric heater (5), a stirring mechanism, a vacuum mechanism and a spraying mechanism. The electric heater (5) is fixedly installed on the vessel body (3). The output end of the electric heater (5) is located at the lower part of the chamber of the vessel body (3). The stirring mechanism is installed on the vessel body (3) and has the function of stirring. The vacuum mechanism is installed on the vessel body (3) and has the function of vacuuming. The spraying mechanism is installed on the vessel body (3).

2. The non-oxidizing bactericide concentration vessel as described in claim 1, characterized in that, The vacuum mechanism includes a vacuum pump (6) and an exhaust pipe (7). The vacuum pump (6) is fixedly installed on the vessel body (3). The input end of the vacuum pump (6) is connected to the upper part of the chamber of the vessel body (3). An exhaust pipe (7) is provided on the vacuum pump (6).

3. The non-oxidizing bactericide concentration kettle as described in claim 1, characterized in that, The stirring mechanism includes a rotating shaft (8), multiple stirring blades (9) and a driving mechanism. The rotating shaft (8) is rotatably mounted on the base plate (1) and the vessel body (3). The multiple stirring blades (9) are all fixedly mounted on the rotating shaft (8). The multiple stirring blades (9) are all located in the cavity of the vessel body (3). The driving mechanism is mounted on the base plate (1) and is used to drive the rotating shaft (8) to rotate.

4. The non-oxidizing bactericide concentration kettle as described in claim 3, characterized in that, The drive mechanism includes bevel gear A (10), bevel gear B (11), drive shaft (12), fixed plate (13) and drive motor (14). Bevel gear A (10) is fixedly mounted on the rotating shaft (8). Bevel gear A (10) meshes with bevel gear B (11). Bevel gear B (11) is fixedly mounted on drive shaft (12). Drive shaft (12) is rotatably mounted on fixed plate (13). The input end of drive shaft (12) is connected to drive motor (14). Fixed plate (13) and drive motor (14) are both fixedly mounted on base plate (1).

5. The non-oxidizing bactericide concentration vessel as described in claim 1, characterized in that, The spraying mechanism includes a delivery pump (15), a delivery pipe (16), a spray pipe (17), and multiple nozzles (18). The delivery pump (15) is installed on the vessel body (3). The input end of the delivery pump (15) is connected to the lower part of the chamber of the vessel body (3). The output end of the delivery pump (15) is connected to the spray pipe (17) through the delivery pipe (16). The spray pipe (17) is installed on the upper part of the chamber of the vessel body (3). Multiple nozzles (18) are provided on the nozzles (18).

6. The non-oxidizing bactericide concentration vessel as described in claim 1, characterized in that, It also includes multiple electric heating lamps (19), which are all fixedly installed on the upper part of the chamber of the vessel body (3). Each of the multiple electric heating lamps (19) is equipped with a transparent waterproof cover, and the multiple electric heating lamps (19) are evenly distributed around the circumference of the chamber of the vessel body (3).

7. The non-oxidizing bactericide concentration vessel as described in claim 1, characterized in that, A thermometer is installed on the vessel body (3).

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