A tool for transporting stainless steel tanks
By installing connecting pipes and shafts on the top of the stainless steel tank, and combining them with a pressure sensor and an electromagnet-controlled slider, the problem of material agglomeration and blockage caused by pressure fluctuations inside the tank was solved, achieving stable material dispersion and quality assurance.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- YANGZHOU HUADAN POWER ELECTRONIC TECH CO LTD
- Filing Date
- 2025-07-07
- Publication Date
- 2026-06-09
AI Technical Summary
During the transfer of volatile materials in stainless steel tanks, vibration and temperature changes cause gas volatilization, increasing the pressure inside the tank, resulting in material compression and agglomeration, poor flowability, easy blockage, and affecting material quality.
A connecting pipe and a connecting shaft are installed on the top of the material tank, equipped with a pressure sensor and an electromagnet to control the slider, so as to realize the pressure relief in the material tank, and drive the screw rod to stir the material through the connecting shaft, so as to maintain the pressure stability and material dispersion in the material tank.
Effectively control the pressure inside the tank, prevent material from clumping, ensure uniform material dispersion, avoid blockage, and maintain stable material quality.
Smart Images

Figure CN224336293U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of stainless steel material tank technology, specifically a tool for transferring stainless steel material tanks. Background Technology
[0002] Stainless steel material tanks are specialized equipment for material storage and transportation. They are usually made of stainless steel and have good corrosion resistance, sealing and hygiene properties, making them suitable for the transportation of various industries and materials.
[0003] When the material stored in the tank is volatile, it will continuously release gas during the transfer process under the influence of vibration and external temperature. The gas will expand under the influence of temperature, which will increase the pressure inside the tank. The pressure will also compress the material, making it denser and reducing its flowability. This can easily cause blockages during unloading, and the material may also be affected by being under compression for a long time. Utility Model Content
[0004] The purpose of this utility model is to provide a tool for transferring stainless steel material tanks, in order to solve the problems mentioned in the background art. When loading or transferring volatile materials, the vibration or temperature of the tank will cause the material to continuously release gas. At the same time, the temperature will cause the gas to condense, thereby increasing the pressure inside the tank. The high pressure inside the tank will squeeze the material, causing it to compact and clump together and reduce its fluidity. This will easily cause blockages during unloading, and prolonged high pressure will easily cause the material to be damaged and deteriorated.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a tool for transferring stainless steel material tanks, including a material tank, wherein an exhaust assembly for depressurizing the material tank is provided inside the material tank, the exhaust assembly includes a connecting pipe provided at the top of the material tank, a through hole provided inside the connecting pipe, and a receiving groove provided on both sides of the inner wall of the through hole, an electromagnet and a slider provided on the inner wall of each of the two receiving grooves, a magnetic plate provided on one side of the slider and a docking groove provided on the other side, and a sealing gasket provided on the inner wall of the docking groove;
[0006] The material tank is equipped with a connecting shaft inside. One end of the connecting shaft is equipped with a spiral rod, and the outer wall of the other end is equipped with an embedded groove. One end of the connecting pipe is equipped with a mounting frame. The mounting frame is equipped with a ring frame inside, and the ring frame is equipped with blades inside.
[0007] Preferably, a pressure sensor is installed inside the material tank, one end of the connecting pipe is located inside the material tank, and the other end extends to the outside. The through hole penetrates the connecting pipe, and the two receiving slots are distributed in a ring on both sides of the connecting pipe.
[0008] Preferably, the electromagnet is connected to the inner wall of the receiving trough and electrically connected to the pressure sensor inside the material tank, and the slider is located inside the receiving trough and is slidably connected to the inner wall of the receiving trough.
[0009] Preferably, the mating groove on one side of the slider faces the through hole side, the sealing gasket is embedded and connected to the inner wall of the mating groove, the magnetic plate is connected to the side of the slider near the inside of the receiving groove, and is magnetically connected to the electromagnet.
[0010] Preferably, one end of the connecting shaft is rotatably connected to the inner wall of the material tank via a bearing bracket, and the other end passes through the through hole of the connecting pipe and extends into the mounting frame. The spiral rod is coaxially connected to the outer wall of the connecting shaft, and the embedded groove at the other end of the connecting shaft corresponds to the position of the receiving groove in the through hole.
[0011] Preferably, the mounting frame is connected to the top of the connecting pipe and communicates with the through hole inside the connecting pipe. The ring frame is located inside the mounting frame and is rotatably connected to the inner wall of the mounting frame via a bearing. The blade is located inside the ring frame and is rotatably connected to the inner wall of the ring frame via a fixed shaft. One end of the connecting shaft is connected to the blade.
[0012] Compared with the prior art, the beneficial effects of this utility model are:
[0013] 1. A connecting pipe is installed on the top of the material tank. The inside of the material tank is connected to the other end of the connecting pipe through a through hole. A connecting shaft is installed inside the material tank and passes through the connecting pipe. A slider inside the connecting pipe slides and engages with the embedded groove on the outside of the connecting shaft to seal the through hole. Under normal conditions, this ensures the sealing of the material tank. The pressure sensor inside the material tank detects the pressure. When the pressure exceeds the set value, the slider can be controlled to contract and close the through hole to release pressure inside the material tank and ensure the stability of the pressure inside the material tank.
[0014] 2. When the pressure inside the tank is released, the gas enters the mounting frame through the through hole and comes into contact with the blades, causing the blades to rotate. As the blades rotate, they work in conjunction with the connecting shaft to drive the screw rod to rotate, thereby stirring and dispersing the material inside the tank, preventing the material from piling up and compacting, and ensuring that the material is evenly dispersed. At the same time, the material above and below can be switched by the screw conveyor to keep the material state consistent and ensure the quality of the material.
[0015] This invention detects the pressure inside the material tank and controls the depressurization process to ensure a stable pressure, reducing the impact of pressure on the material. During depressurization, the discharged airflow is used to stir and disperse the material using a driving screw, ensuring uniform dispersion and guaranteeing the material's condition and quality. Attached Figure Description
[0016] Figure 1This is an overall isometric view of the present invention;
[0017] Figure 2 This is a structural diagram of the connecting shaft of this utility model;
[0018] Figure 3 This is a diagram showing the internal structure of the connecting pipe of this utility model;
[0019] Figure 4 This is an enlarged view of part A of this utility model.
[0020] In the diagram: 1. Material tank; 2. Connecting shaft; 201. Spiral rod; 202. Embedded groove; 3. Connecting pipe; 301. Through hole; 4. Mounting frame; 401. Ring frame; 402. Blade; 5. Storage groove; 501. Electromagnet; 6. Slider; 601. Magnetic plate; 7. Connecting groove; 701. Sealing gasket. Detailed Implementation
[0021] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0022] All devices in this application adopt conventional models in the prior art, and the control method is through a controller. The control circuit of the controller can be implemented by simple programming by those skilled in the art, which is common knowledge in the field, so this application will not explain it in detail.
[0023] Please see the appendix Figures 1-4As shown, a tool for transferring stainless steel material tanks includes a material tank 1. An venting assembly for depressurizing the material tank 1 is installed inside the material tank 1. The venting assembly includes a connecting pipe 3 located at the top of the material tank 1, penetrating the top of the material tank 1. A through hole 301 is provided inside the connecting pipe 3, allowing the material tank 1 to communicate with the outside. Storage grooves 5 are provided on both sides of the inner wall of the through hole 301 for storing a slider 6 and positioning the angle of the slider 6 during sliding. Electromagnets 501 and sliders 6 are installed on the inner walls of both storage grooves 5. The electromagnets 501 are electrically connected to a pressure sensor inside the material tank 1. After the pressure sensor detects that the pressure inside the material tank 1 exceeds the set value, it controls the electromagnet 501 to change its magnetic poles. In the normal state, the magnetic poles generated by the electromagnet 501 when it is energized repel the magnetic plate 601, thereby pushing the slider 6 to slide out of the receiving groove 5. The slider 6 is provided with a magnetic plate 601 on one side and a docking groove 7 on the other side. The docking groove 7 corresponds to the inner groove 202 outside the connecting shaft 2. After the docking groove 7 area of the slider 6 extends to the through hole 301, it can be fitted into the inner groove 202 outside the connecting shaft 2. A sealing gasket 701 is provided on the inner wall of the docking groove 7. The sealing gasket 701 can increase the sealing between the docking groove 7 and the inner groove 202.
[0024] A pressure sensor is installed inside the material tank 1. One end of the connecting pipe 3 is located inside the material tank 1, and the other end extends to the outside. The through hole 301 passes through the connecting pipe 3. Two receiving slots 5 are distributed in a ring on both sides of the connecting pipe 3. The electromagnet 501 is connected to the inner wall of the receiving slot 5 and is electrically connected to the pressure sensor inside the material tank 1. The slider 6 is located inside the receiving slot 5 and is slidably connected to the inner wall of the receiving slot 5. The docking slot 7 on one side of the slider 6 faces the through hole 301. The sealing gasket 701 is embedded and connected to the inner wall of the docking slot 7. The magnetic plate 601 is connected to the side of the slider 6 near the inside of the receiving slot 5 and is magnetically connected to the electromagnet 501.
[0025] In this embodiment: Under normal conditions, the magnetic poles generated by the electromagnet 501 repel the magnetic plate 601, thereby pushing the slider 6 to slide in the receiving groove 5 and extend to the through hole 301 area. At the same time, the other end of the connecting shaft 2 extends through the through hole 301 of the connecting pipe 3 into the mounting frame 4. When the slider 6 slides, the mating groove 7 on one side of the slider 6 fits with the inner groove 202 outside the connecting shaft 2, thereby sealing the through hole 301 and ensuring the sealing of the material tank 1 under normal conditions. The pressure sensor detects the pressure inside the material tank 1. When the pressure exceeds the set value, the magnetic poles of the electromagnet 501 are controlled to change and attract the magnetic plate 601, causing the slider 6 to retract into the receiving groove 5 and move away from the through hole 301, exposing the through hole 301. At the same time, the gas inside the material tank 1 can be transported through the through hole 301 through the mounting frame 4 and discharged to relieve the pressure inside the material tank 1, ensuring the stability of the pressure inside the material tank 1.
[0026] Example 2: This example is an improvement on Example 1. For details, please refer to [link / reference]. Figures 2-3 The material tank 1 is equipped with a connecting shaft 2. One end of the connecting shaft 2 is rotatably connected to the bottom of the material tank 1, and the other end passes through the connecting pipe 3 and extends into the mounting frame 4 and connects with the blade 402, so that the connecting shaft 2 and the blade 402 are linked. One end of the connecting shaft 2 is equipped with a screw rod 201. When the screw rod 201 rotates, it can stir the material in the material tank 1 and convey it upward, so as to achieve stirring and dispersion of the material and ensure the loosening effect of the material. At the same time, it can change the distribution position of the material. The outer wall of the other end is equipped with an embedded groove 202. One end of the connecting pipe 3 is equipped with a mounting frame 4. The mounting frame 4 is equipped with a ring frame 401. The ring frame 401 can position the blade 402 at the position and angle. The blade 402 is installed inside the ring frame 401. When the pressure is released, the gas passing through the mounting frame 4 can impact the blade 402 inside the ring frame 401, thereby driving the blade 402 to rotate.
[0027] One end of the connecting shaft 2 is rotatably connected to the inner wall of the material tank 1 through a bearing bracket, and the other end passes through the through hole 301 of the connecting pipe 3 and extends into the mounting frame 4. The spiral rod 201 is coaxially connected to the outer wall of the connecting shaft 2. The inner groove 202 at the other end of the connecting shaft 2 corresponds to the position of the receiving groove 5 in the through hole 301. The mounting frame 4 is connected to the top of the connecting pipe 3 and communicates with the through hole 301 inside the connecting pipe 3. The ring frame 401 is located inside the mounting frame 4 and is rotatably connected to the inner wall of the mounting frame 4 through a bearing. The blade 402 is located inside the ring frame 401 and is rotatably connected to the inner wall of the ring frame 401 through a fixed shaft. One end of the connecting shaft 2 is connected to the blade 402.
[0028] In this embodiment: when the pressure inside the material tank 1 is released, the airflow enters the mounting frame 4 through the through hole 301 and comes into contact with the blades 402 inside the mounting frame 4. The pressure of the airflow drives the blades 402 to rotate, which in turn drives the connecting shaft 2 to rotate synchronously. At the same time, the spiral rod 201 outside the connecting shaft 2 stirs the material inside the material tank 1, thereby dispersing the material inside the material tank 1, thus avoiding material accumulation and compaction, ensuring uniform material dispersion, and guaranteeing stable material quality. In addition, the mounting frame 4 and the blades 402 inside the mounting frame 4 can help reduce the probability of external impurities entering.
[0029] The contents not described in detail in this specification are existing technologies known to those skilled in the art.
[0030] Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.
Claims
1. A tool for transferring stainless steel material tanks, comprising a material tank (1), wherein the material tank (1) is provided with an venting assembly for depressurizing the material tank (1), characterized in that: The exhaust assembly includes a connecting pipe (3) disposed at the top of the material tank (1). The connecting pipe (3) has a through hole (301) inside. Both sides of the inner wall of the through hole (301) are provided with a storage groove (5). The inner walls of the two storage grooves (5) are provided with an electromagnet (501) and a slider (6). A magnetic plate (601) is provided on one side of the slider (6), and a docking groove (7) is provided on the other side. A sealing gasket (701) is provided on the inner wall of the docking groove (7). The material tank (1) is provided with a connecting shaft (2) inside. One end of the connecting shaft (2) is provided with a spiral rod (201), and the outer wall of the other end is provided with an embedded groove (202). One end of the connecting pipe (3) is provided with an installation frame (4). The installation frame (4) is provided with a ring frame (401) inside. The ring frame (401) is provided with a blade (402) inside.
2. The tool for transferring stainless steel material tanks according to claim 1, characterized in that: A pressure sensor is installed inside the material tank (1). One end of the connecting pipe (3) is located inside the material tank (1), and the other end extends to the outside. The through hole (301) penetrates the connecting pipe (3). The two receiving slots (5) are distributed in a ring on both sides of the connecting pipe (3).
3. A tool for transferring stainless steel material containers according to claim 2, characterized in that: The electromagnet (501) is connected to the inner wall of the receiving trough (5) and electrically connected to the pressure sensor in the material tank (1). The slider (6) is located in the receiving trough (5) and is slidably connected to the inner wall of the receiving trough (5).
4. A tool for transferring stainless steel material tanks according to claim 3, characterized in that: The docking groove (7) on one side of the slider (6) faces the through hole (301), the sealing gasket (701) is embedded and connected to the inner wall of the docking groove (7), the magnetic plate (601) is connected to the side of the slider (6) near the inside of the storage groove (5), and is magnetically connected to the electromagnet (501).
5. A tool for transferring stainless steel material tanks according to claim 1, characterized in that: One end of the connecting shaft (2) is rotatably connected to the inner wall of the material tank (1) through the bearing bracket, and the other end passes through the through hole (301) of the connecting pipe (3) and extends into the mounting frame (4). The spiral rod (201) is coaxially connected to the outer wall of the connecting shaft (2). The inner groove (202) at the other end of the connecting shaft (2) corresponds to the position of the storage groove (5) in the through hole (301).
6. A tool for transferring stainless steel material tanks according to claim 5, characterized in that: The mounting frame (4) is connected to the top of the connecting pipe (3) and communicates with the through hole (301) inside the connecting pipe (3). The ring frame (401) is located inside the mounting frame (4) and is rotatably connected to the inner wall of the mounting frame (4) through a bearing. The blade (402) is located inside the ring frame (401) and is rotatably connected to the inner wall of the ring frame (401) through a fixed shaft. One end of the connecting shaft (2) is connected to the blade (402).