An automatic stirring mixing kettle

Abstract

The utility model relates to the technical field of automobile manufacturing, especially to an automatic stirring mixing kettle, including base and kettle body, a plurality of sliding plates, a plurality of sensors, a plurality of supporting ears, a plurality of sets of mounting mechanisms, stirring assembly and feeding assembly, and the mounting mechanism includes power unit, displacement plate, two mounting rods and spring, the base has a plurality of sliding slots and a plurality of clamping holes, the sliding plate is slidably connected with the corresponding sliding slot, the sliding plate has an arc groove, a recess and two through holes, the sensor is placed in the corresponding arc groove, the supporting ear is fixedly connected with the kettle body and contacts the corresponding sensor, the displacement plate is slidably connected with the recess, one end of the mounting rod is fixedly connected with the displacement plate, the other end of the mounting rod penetrates the corresponding through hole and is placed in the corresponding clamping hole, and in this way, the technical problem that the sensor is inconvenient to mount and dismount when directly weighing the kettle body in the prior art and leads to poor practicality is solved.

Description

Technical Field

[0001] This utility model relates to the field of automobile manufacturing technology, and in particular to an automatic stirring and mixing vessel. Background Technology

[0002] In the motorcycle, tricycle, and automobile manufacturing industries, oil-based coatings are key surface treatment materials, and their quality directly affects the product's appearance, corrosion resistance, and service life. Oil-based coatings are typically composed of a mixture of various raw materials in specific proportions, including resins, pigments, solvents, and additives. The uniform mixing of these raw materials is crucial for ensuring stable coating performance and achieving the desired results. During production, weighing is usually required, and current methods often involve directly weighing the reactor vessel to control the feed.

[0003] However, when the existing method uses sensors to directly weigh the vessel, it is inconvenient to install and remove the sensors, resulting in poor practicality. Utility Model Content

[0004] The purpose of this invention is to provide an automatic stirring and mixing vessel, which aims to solve the technical problem that the existing technology, which uses sensors to directly weigh the vessel body, is not convenient to install and remove the sensors, resulting in poor practicality.

[0005] To achieve the above objectives, this utility model employs an automatic mixing vessel, comprising a base and vessel body, multiple sliding plates, multiple sensors, multiple lugs, multiple sets of mounting mechanisms, a mixing assembly, and a feeding assembly. The vessel body provides a carrier for mixing various raw materials. The mounting mechanism includes a power unit, a displacement plate, two mounting rods, and a spring. The base has multiple grooves and multiple retaining holes. The sliding plates are slidably connected to the corresponding grooves. Each sliding plate has an arc-shaped groove, a recess, and two through holes. The sensors are placed in the corresponding arc-shaped grooves. The lugs are fixedly connected to the vessel body and contact the corresponding sensors. The displacement plate is slidably connected to the recess. One end of each mounting rod is fixedly connected to the displacement plate, and the other end of each mounting rod passes through the corresponding through hole and is placed in the corresponding retaining hole. Both ends of the spring are fixedly connected to the displacement plate and the sliding plate, respectively. The power unit is used to drive the displacement plate to move.

[0006] The power unit includes a force-applying block, a round rod, and a cam. The round rod is rotatably connected to the sliding plate. The force-applying block and the cam are fixedly connected to both ends of the round rod, and the cam is in contact with the displacement plate.

[0007] The stirring assembly includes a motor and a stirring rod. The motor is mounted on the vessel body, and the output end of the motor is inserted into the vessel body and fixedly connected to the stirring rod.

[0008] The feeding assembly includes a feeding pipe, a collection pipe, and multiple sets of material control units. The two ends of the feeding pipe are connected to the reactor body and the collection pipe, respectively. The two ends of the material control units are connected to the collection pipe and the corresponding raw material pipe, respectively.

[0009] The material control unit includes a connecting pipe, a flange, and a peristaltic pump. One end of the connecting pipe is connected to the collection pipe, and the other end of the connecting pipe is connected to the corresponding raw material pipe through the flange. The peristaltic pump is mounted on the connecting pipe.

[0010] This utility model discloses an automatic mixing vessel. In practical use, various raw materials, additives, pigments, etc., are added into the vessel body through the feeding assembly. After the required value is reached by the weighing sensor, the stirring assembly is activated to stir and mix the materials in the vessel body. When the sensor needs to be disassembled, the power unit drives the displacement plate to move upward. The upward movement of the displacement plate moves the two corresponding mounting rods, causing the mounting rods to slide out of the corresponding retaining holes. Then, the sliding plate can be slid out of the corresponding sliding groove. After that, the sensor can be disassembled from the arc-shaped groove. Conversely, it is convenient to replace the sensor and install it on the base. This method solves the technical problem in the prior art where the sensor is used to directly weigh the vessel body, making it inconvenient to install and disassemble the sensor, resulting in poor practicality. Attached Figure Description

[0011] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0012] Figure 1 This is a schematic diagram of the structure of the automatic stirring and mixing vessel of this utility model.

[0013] Figure 2 This is a partial structural schematic diagram of the automatic stirring and mixing vessel of this utility model.

[0014] Figure 3 This is a partial structural schematic diagram of the automatic stirring and mixing vessel of this utility model.

[0015] Figure 4 This is a schematic diagram of the stirring assembly of this utility model.

[0016] Figure 5 This is the utility model Figure 2A cross-sectional view of the AA line structure.

[0017] 101-Base, 102-Bottle body, 103-Sliding plate, 104-Sensor, 105-Support lug, 106-Displacement plate, 107-Mounting rod, 108-Spring, 109-Force block, 110-Round rod, 111-Cam, 112-Motor, 113-Stirring rod, 114-Feed pipe, 115-Combination pipe, 116-Connecting pipe, 117-Flange, 118-Peristaltic pump, 119-Slide groove, 120-Holding hole, 121-Arc groove, 122-Groove, 123-Through hole. Detailed Implementation

[0018] The embodiments of the present invention are described in detail below. Examples of the embodiments are shown in the accompanying drawings. The embodiments described below with reference to the accompanying drawings are exemplary and intended to explain the present invention, but should not be construed as limiting the present invention.

[0019] Please see Figures 1-5 ,in Figure 1 This is a schematic diagram of the structure of the automatic stirring and mixing vessel of this utility model. Figure 2 This is a partial structural schematic diagram of the automatic stirring and mixing vessel of this utility model. Figure 3 This is a partial structural schematic diagram of the automatic stirring and mixing vessel of this utility model. Figure 4 This is a schematic diagram of the stirring assembly of this utility model. Figure 5 This is the utility model Figure 2 A cross-sectional view of the AA line structure.

[0020] This utility model provides an automatic mixing vessel, including a base 101 and a vessel body 102, multiple sliding plates 103, multiple sensors 104, multiple lugs 105, multiple sets of mounting mechanisms, a stirring assembly, and a feeding assembly. The mounting mechanism includes a power unit, a displacement plate 106, two mounting rods 107, and a spring 108. The power unit includes a force-applying block 109, a round rod 110, and a cam 111. The stirring assembly includes a motor 112 and a stirring rod 113. The feeding assembly includes a feeding pipe 114, a collection pipe 115, and multiple sets of material control units. The material control unit includes a connecting pipe 116, a flange 117, and a peristaltic pump 118. The aforementioned solution solves the technical problem in the prior art where it is inconvenient to install and remove the sensor 104 when directly weighing the vessel body 102, resulting in poor practicality.

[0021] In this specific embodiment, the vessel body 102 is used to provide a carrier for mixing various raw materials by adding various raw materials, additives, pigments, etc. into the vessel body 102.

[0022] The base 101 has multiple sliding grooves 119 and multiple retaining holes 120. The sliding plate 103 is slidably connected to the corresponding sliding groove 119. The sliding plate 103 has an arc-shaped groove 121, a recess 122, and two through holes 123. The sensor 104 is placed in the corresponding arc-shaped groove 121. The support lug 105 is fixedly connected to the vessel body 102 and contacts the corresponding sensor 104. The displacement plate 106 is slidably connected to the recess 122. One end of the mounting rod 107 is fixedly connected to the displacement plate 106, and the other end of the mounting rod 107 passes through the corresponding through hole 123 and is placed in the corresponding retaining hole 120. The two ends of the spring 108 are fixedly connected to the displacement plate 106 and the sliding plate 103, respectively. The power unit is used to drive the displacement plate 106 to move. In actual use, various raw materials are fed by the feeding assembly. Additives, pigments, etc. are added to the vessel body 102, and after the required value is reached by the weighing sensor 104, the stirring assembly is activated to stir and mix the materials in the vessel body 102. When it is necessary to disassemble the sensor 104, the displacement plate 106 is moved upward by the power unit. The upward movement of the displacement plate 106 causes the two corresponding mounting rods 107 to move, so that the mounting rods 107 slide out of the corresponding retaining holes 120. Then, the sliding plate 103 can be slid out of the corresponding sliding groove 119. After that, the sensor 104 is removed from the arc groove 121. Conversely, it is convenient to replace the sensor 104 and install it on the base 101. This method solves the technical problem in the prior art that when the sensor 104 is used to directly weigh the vessel body 102, it is inconvenient to install and remove the sensor 104, resulting in poor practicality.

[0023] Secondly, the round rod 110 is rotatably connected to the sliding plate 103. The force-applying block 109 and the cam 111 are respectively fixedly connected to both ends of the round rod 110. The cam 111 contacts the displacement plate 106. By applying force to the force-applying block 109, the force-applying block 109 drives the round rod 110 to rotate. The round rod 110 drives the cam 111 to rotate, and the cam 111 can then push against the displacement plate 106 and move upward.

[0024] Meanwhile, the motor 112 is installed on the vessel body 102, and the output end of the motor 112 is inserted into the vessel body 102 and fixedly connected to the stirring rod 113. In actual use, by starting the motor 112, the output end of the motor 112 drives the stirring rod 113 to rotate, and the stirring rod 113 stirs and mixes the materials.

[0025] In addition, the two ends of the feed pipe 114 are respectively connected to the vessel body 102 and the collection pipe 115, and the two ends of the material control unit are respectively connected to the collection pipe 115 and the corresponding raw material pipe.

[0026] One end of the connecting pipe 116 is connected to the summing pipe 115, and the other end of the connecting pipe 116 is connected to the corresponding raw material pipe through the flange 117. The peristaltic pump 118 is installed on the connecting pipe 116. The raw material in the raw material pipe enters the summing pipe 115 through the corresponding connecting pipe 116, and then enters the feed pipe 114 and then enters the reactor body 102. At this time, the flow rate can be controlled by the peristaltic pump 118.

[0027] In the application of this automatic mixing vessel, various raw materials, additives, pigments, etc., are added to the vessel body 102 via the feeding assembly. After the required value is reached by the weighing sensor 104, the stirring assembly is activated to stir and mix the materials in the vessel body 102. When the sensor 104 needs to be disassembled, the displacement plate 106 is moved upward by the power unit. The upward movement of the displacement plate 106 moves the two corresponding mounting rods 107, causing the mounting rods 107 to slide out of the corresponding retaining holes 120. Then, the sliding plate 103 can be slid out of the corresponding sliding groove 119. After that, the sensor 104 can be disassembled from the arc groove 121. Conversely, it is convenient to replace the sensor 104 and install it on the base 101. This method solves the technical problem in the prior art where the sensor 104 is used to directly weigh the vessel body 102, making it inconvenient to install and disassemble the sensor 104, resulting in poor practicality.

[0028] The above-disclosed embodiments are merely preferred embodiments of the present utility model and should not be construed as limiting the scope of the present utility model. Those skilled in the art can understand that implementing all or part of the above-described embodiments and making equivalent changes in accordance with the claims of the present utility model are still within the scope of the utility model.

Claims

1. An automatic stirring and mixing vessel, comprising a base and a vessel body, wherein the vessel body provides a carrier for mixing various raw materials, characterized in that, It also includes multiple sliding plates, multiple sensors, multiple supports, multiple sets of mounting mechanisms, a stirring assembly, and a feeding assembly. The mounting mechanism includes a power unit, a displacement plate, two mounting rods, and a spring. The base has multiple sliding grooves and multiple retaining holes. The sliding plates are slidably connected to the corresponding sliding grooves. The sliding plates have arc-shaped grooves, recesses, and two through holes. The sensors are placed in the corresponding arc-shaped grooves. The supports are fixedly connected to the vessel body and contact the corresponding sensors. The displacement plate is slidably connected to the recesses. One end of the mounting rod is fixedly connected to the displacement plate, and the other end of the mounting rod passes through the corresponding through hole and is placed in the corresponding retaining hole. The two ends of the spring are fixedly connected to the displacement plate and the sliding plate, respectively. The power unit is used to drive the displacement plate to move.

2. The automatic stirring and mixing vessel as described in claim 1, characterized in that, The power unit includes a force-applying block, a round rod, and a cam. The round rod is rotatably connected to the sliding plate. The force-applying block and the cam are respectively fixedly connected to the two ends of the round rod. The cam is in contact with the displacement plate.

3. The automatic stirring and mixing vessel as described in claim 2, characterized in that, The stirring assembly includes a motor and a stirring rod. The motor is mounted on the vessel body, and the output end of the motor is inserted into the vessel body and fixedly connected to the stirring rod.

4. The automatic stirring and mixing vessel as described in claim 3, characterized in that, The feeding assembly includes a feeding pipe, a collection pipe, and multiple sets of material control units. The two ends of the feeding pipe are connected to the reactor body and the collection pipe, respectively. The two ends of the material control units are connected to the collection pipe and the corresponding raw material pipe, respectively.

5. The automatic stirring and mixing vessel as described in claim 4, characterized in that, The material control unit includes a connecting pipe, a flange, and a peristaltic pump. One end of the connecting pipe is connected to the collection pipe, and the other end of the connecting pipe is connected to the corresponding raw material pipe through the flange. The peristaltic pump is mounted on the connecting pipe.

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