Multi-medicament cross-presentation switching device
By designing a multi-agent cross-dosing conversion device, and utilizing dosing components and control panels to achieve automated and precise dosing of chemicals, the problem of inaccurate chemical dosing in existing technologies is solved, thereby improving the efficiency and practicality of seawater circulation treatment.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHENZHEN CM ELECTRIC TECH CORP LTD
- Filing Date
- 2025-06-09
- Publication Date
- 2026-06-30
Smart Images

Figure CN224429463U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of seawater cooling and utilization technology, and in particular relates to a device for cross-dispensing and converting multiple agents. Background Technology
[0002] With the development of industrial production, water consumption is increasing, and many regions have experienced water shortages. Therefore, rational and economical water use has become an important issue in industrial production. The industrial application of circulating cooling water has completely solved the water problem and achieved the goal of water conservation.
[0003] Current technologies for using seawater as circulating cooling water require controlling the growth of marine organisms. Common solutions involve manual or semi-automatic dosing of oxidizing agents, non-oxidizing agents, or electrolytic chlorination agents. This is time-consuming and labor-intensive, and the dosage cannot be precisely controlled, resulting in a limited and impractical treatment strategy for circulating seawater. To address these issues, we offer a multi-agent cross-dosing and switching device. Utility Model Content
[0004] The purpose of this invention is to provide a multi-agent cross-dispensing conversion device. Through the cooperation of the dispensing components and the control panel, it solves the problem in the prior art that the dosage of the agents is inaccurate, time-consuming, labor-intensive, and impractical due to the need for manual control of the dispensing.
[0005] To solve the above-mentioned technical problems, this utility model is achieved through the following technical solution.
[0006] This utility model relates to a device for cross-dispensing and converting multiple pharmaceutical agents, comprising a mounting box, a mounting assembly, and a dispensing assembly. The mounting assembly is located at the lower end of the mounting box, and the dispensing assembly is located on the side wall of the mounting box. A first storage battery is installed inside the mounting box. The dispensing assembly includes two No. 1 storage bins and two No. 2 storage bins. Each of the two No. 1 and two No. 2 storage bins has a feeding hole at its upper end, into which a feeding hopper is inserted. A dispensing frame is fixedly connected to the lower end of each of the two No. 1 and two No. 2 storage bins. Each of the lower end faces of each of the two No. 1 and two No. 2 storage bins has a discharge hole. A third electrically controlled valve is installed in each of the four discharge holes. The side walls of each of the four dispensing frames are provided with... The device has a discharge port with a discharge pipe inserted into it. A first electrically controlled valve and a second electrically controlled valve are respectively installed in the discharge pipes below the first and second storage tanks. A column is fixedly connected inside the mounting box, and a rotating disk is rotatably connected to the upper end of the column. A control panel is mounted on the rotating disk, and the control panel is signal-connected to four third electrically controlled valves, two first electrically controlled valves, and two second electrically controlled valves. Separate liquid level sensors are installed in each of the four delivery frames. A brake motor is fixedly mounted on the upper surface of the mounting box, and a drive gear is fixedly sleeved on the output shaft of the brake motor. A gear ring is fixedly connected to the inner wall of the rotating disk, and the drive gear meshes with the gear ring. The control panel is signal-connected to the brake motor.
[0007] The present invention is further configured such that the side walls of the two No. 1 storage tanks and the two No. 2 storage tanks are provided with through holes, and the four separate liquid level sensors are respectively inserted into the four through holes, and the four separate liquid level sensors are all connected to the control panel for signal transmission.
[0008] The present invention is further configured such that four external plates are fixedly connected to the side wall of the rotating disk, and the four external plates are respectively fixedly connected to the side walls of the two No. 1 storage bins and the two No. 2 storage bins.
[0009] The present invention is further configured such that a second battery is fixedly installed on the side wall of each of the four delivery frames, and the four second batteries respectively power the two first electrically controlled valves, the two second electrically controlled valves, the four third electrically controlled valves, and the four separate liquid level sensors.
[0010] The present invention is further configured such that a matching remote control panel is provided outside the control panel, and the remote control panel and the control panel are connected by a signal.
[0011] The present invention is further configured such that the mounting component includes a base column, the lower end of the base column is fixedly connected to a base, the lower end of the mounting box is fixedly connected to the upper end of the base column, and a plurality of mounting bolts are provided on the base.
[0012] The present invention is further configured such that the first storage battery supplies power to both the brake motor and the control panel.
[0013] The present invention is further configured such that the inclined angle of the bottom slope of the inner wall of the delivery frame is 10°.
[0014] The present invention has the following beneficial effects.
[0015] 1. This utility model, by setting up a dispensing component and a control panel, allows non-oxidizing and oxidizing bactericides to be injected into two No. 1 storage tanks through the feed hopper, while dispersants and defoamers are injected into two No. 2 storage tanks. Then, the third electrically controlled valve is opened through the control panel to allow the agents to enter the dispensing frame. After the discharge pipe faces the water surface, the agents, whose dosage is monitored by a separate liquid level sensor, are discharged into the circulating seawater through the discharge pipe to inhibit microbial growth. This eliminates the need for manual control of agent dispensing. The separate liquid level sensor can monitor changes in the liquid level in the No. 1 and No. 2 storage tanks to determine the dosage of agents, resulting in better practical effects.
[0016] 2. By setting up a brake motor, a drive gear, and a gear ring, when it is necessary to turn the delivery frame to the side of the water surface, the brake motor can be started and its output shaft can drive the drive gear to rotate. The drive gear, through meshing with the gear ring, drives the rotating disk to rotate on the column, thereby realizing the control of the delivery direction of the four delivery frames.
[0017] 3. This utility model, by setting up a first electrically controlled valve, a second electrically controlled valve, a control panel, and a remote control panel, allows the operator to control the control panel via the remote control panel. The control panel then uses signals to open and close the two first and second electrically controlled valves, thereby controlling the discharge of the medicine in the No. 1 and No. 2 storage tanks. Attached Figure Description
[0018] To more clearly illustrate the technical solutions of the embodiments of this utility model, the accompanying drawings used in the description of the embodiments will be briefly introduced below.
[0019] Figure 1 This is a three-dimensional diagram of a device for cross-dispensing and converting multiple drugs.
[0020] Figure 2 This is a diagram showing the unpacked structure of the dispensing and installation components in a multi-pharmaceutical cross-dispensing conversion device.
[0021] Figure 3 This is a schematic diagram of the bottom structure of the rotating disk in a multi-drug cross-dispensing conversion device.
[0022] Figure 4This is a three-dimensional structural diagram of the No. 1 storage tank and the delivery frame in a multi-drug cross-dispensing conversion device.
[0023] Figure 5 This is a side structural cross-sectional view of the No. 1 storage tank, No. 2 storage tank, and delivery frame in a multi-pharmaceutical cross-dispensing conversion device.
[0024] In the attached diagram: 1. Mounting box; 2. Column; 3. Rotating disc; 4. Gear ring; 5. Brake motor; 6. Drive gear; 7. External plate; 8-1. Storage tank No. 1; 8-2. Storage tank No. 2; 9. Feed hopper; 10. Separate liquid level sensor; 11. Feed hole; 12. Through hole; 13. Dispensing frame; 14. Discharge pipe; 15-1. First electrically controlled valve; 15-2. Second electrically controlled valve; 16. Control panel; 17. Base column; 18. Base; 19. Third electrically controlled valve; 20. Second battery. Detailed Implementation
[0025] The technical solutions of the present invention will be described below with reference to the accompanying drawings of the embodiments of the present invention. The described embodiments are only some embodiments of the present invention, and not all embodiments.
[0026] Example 1
[0027] Please see Figure 1-5This utility model is a device for cross-dispensing and converting multiple drugs, including a mounting box 1, a mounting assembly, and a dispensing assembly. The mounting assembly is located at the lower end of the mounting box 1, and the dispensing assembly is located on the side wall of the mounting box 1. A first storage battery is installed inside the mounting box 1. The dispensing assembly includes two No. 1 storage tanks 8-1 and two No. 2 storage tanks 8-2. Each of the two No. 1 storage tanks 8-1 and two No. 2 storage tanks 8-2 has a feeding hole 11 at its upper end, and a feeding hopper 9 is inserted into the feeding hole 11. Each of the two No. 1 storage tanks 8-1 and two No. 2 storage tanks 8-2 has a dispensing frame 13 fixedly connected to its lower end. Each of the two No. 1 storage tanks 8-1 and two No. 2 storage tanks 8-2 has a discharge hole on its lower end face, and a third electrically controlled valve 19 is installed in each of the four discharge holes. Each of the four dispensing frames 13 has a discharge hole on its side wall for dispensing. A discharge pipe 14 is inserted into the hole. A first electrically controlled valve 15-1 and a second electrically controlled valve 15-2 are respectively installed in the discharge pipe 14 below the No. 1 storage tank 8-1 and the No. 2 storage tank 8-2. A column 2 is fixedly connected inside the mounting box 1. A rotating disk 3 is rotatably connected to the upper end of the column 2. A control panel 16 is set on the rotating disk 3. The control panel 16 is connected to four third electrically controlled valves 19, two first electrically controlled valves 15-1, and two second electrically controlled valves 15-2. A separate liquid level sensor 10 is set in each of the four delivery frames 13. A brake motor 5 is fixedly installed on the upper end face of the mounting box 1. A drive gear 6 is fixedly sleeved on the output shaft of the brake motor 5. A gear ring 4 is fixedly connected to the inner wall of the rotating disk 3. The drive gear 6 and the gear ring 4 are meshed and connected. The control panel 16 is connected to the brake motor 5.
[0028] Specifically: Non-oxidizing and oxidizing bactericides are injected into two No. 1 storage tanks 8-1 through feed hopper 9. Dispersants and defoamers are injected into two No. 2 storage tanks 8-2 through the same feed hopper 9. Then, the installation box 1 is installed near the circulating seawater using the installation components. At this time, the third electrically controlled valve 19 in the two No. 1 storage tanks 8-1 and the two No. 2 storage tanks 8-2 can be controlled via control panel 16. The agents to be added are first fed into the dispensing frame 13 through the discharge hole and await dispensing. When the discharge pipe 14 on the side wall of the dispensing frame 13 faces the water surface, the dispensing can be... Controlling and opening the first electrically controlled valve 15-1 or the second electrically controlled valve 15-2 allows the reagent in the dosing box 13, whose dosage has been monitored by the separate liquid level sensor 10, to enter the circulating water through the discharge pipe 14, eliminating the need for manual control of the reagent dispensing. At the same time, the separate liquid level sensor 10 can monitor the changes in the liquid level in the first storage tank 8-1 and the second storage tank 8-2 to determine the dosage of the reagent, resulting in better practical effect. In actual use, it is forbidden to add oxidizing and non-oxidizing reagents to the two first storage tanks 8-1 at the same time.
[0029] Example 2
[0030] Please see Figure 1-5Based on Embodiment 1, through holes 12 are provided on the side walls of the two No. 1 storage tanks 8-1 and the two No. 2 storage tanks 8-2. Four separate liquid level sensors 10 are respectively inserted into the four through holes 12. The four separate liquid level sensors 10 are all connected to the control panel 16. Four external plates 7 are fixedly connected to the side wall of the rotating disk 3. The four external plates 7 are respectively fixedly connected to the side walls of the two No. 1 storage tanks 8-1 and the two No. 2 storage tanks 8-2. Second batteries 20 are fixedly installed on the side walls of the four delivery frames 13. The four second batteries 20 are respectively connected to the two first electronically controlled valves. 15-1, two second electrically controlled valves 15-2, four third electrically controlled valves 19, and four separate liquid level sensors 10 are powered. A matching remote control panel is provided outside the control panel 16. The remote control panel and the control panel 16 are connected by signal. The mounting components include a base column 17. The lower end of the base column 17 is fixedly connected to a base 18. The lower end of the mounting box 1 is fixedly connected to the upper end of the base column 17. Multiple mounting bolts are provided on the base 18. The first battery powers the brake motor 5 and the control panel 16 respectively. The inclined angle of the bottom slope of the inner wall of the delivery frame 13 is 10°.
[0031] Specifically: Four through holes 12 allow four separate liquid level sensors 10 to enter storage tank 8-1 and storage tank 8-2 respectively to monitor their internal liquid levels. The four separate liquid level sensors 10 are connected to the control panel 16, enabling the control panel 16 to receive the liquid level data transmitted by the four separate liquid level sensors 10. Four external plates 7 are provided, allowing both storage tanks 8-1 and 8-2 to be connected to the mounting box 1 while maintaining a distance to ensure the lower discharge pipe 14 does not contact the mounting box 1. A second battery 20 is provided to power the two first electrically controlled valves 15-1, two second electrically controlled valves 15-2, four third electrically controlled valves 19, and the four separate liquid level sensors 10, enabling these components to operate on the dispensing assembly. The second battery 20 provides power to ensure normal operation. By setting up a remote control panel and connecting it to the control panel 16, the liquid level data collected by the control panel 16 can be transmitted to the remote control panel. The operator can observe the liquid level data in the first storage tank 8-1 and the second storage tank 8-2 and then remotely control the control panel 16 via the signal to operate the opening and closing of the two first electric valves 15-1, the two second electric valves 15-2, and the four third electric valves 19. By setting up the installation components, the installation box 1 can be installed on the shore or the hull via the base column 17 and the base 18. Multiple mounting bolts can further increase the connection between the base 18 and the installation surface. By setting up the first battery, the brake motor 5 and the control panel 16 can work normally on the installation box 1 with the power of the first battery. By setting the inclination angle of the bottom slope of the inner wall of the delivery frame 13 to 10°, the medicine in the delivery frame 13 can enter the discharge pipe 14 along its slope, which can avoid the medicine residue in the delivery frame 13.
[0032] The working principle of this utility model is as follows: Non-oxidizing and oxidizing bactericides are injected into two No. 1 storage tanks 8-1 through the feed hopper 9. Dispersants and defoamers are injected into two No. 2 storage tanks 8-2 through the same feed hopper 9. Then, the installation box 1 is installed near the circulating seawater using the installation components. At this time, the third electrically controlled valve 19 in the two No. 1 storage tanks 8-1 and the two No. 2 storage tanks 8-2 can be controlled via the control panel 16. The required agents are first fed into the dispensing frame 13 through the discharge hole, awaiting dispensing. When the discharge pipe 14 on the side wall of the dispensing frame 13 faces the water... The first electrically controlled valve 15-1 or the second electrically controlled valve 15-2 can be controlled and opened, allowing the agent in the dosing box 13, whose dosage has been monitored by the separate liquid level sensor 10, to enter the circulating water through the discharge pipe 14. This eliminates the need for manual control of the agent dispensing. At the same time, the separate liquid level sensor 10 can monitor the changes in the liquid level in the first storage tank 8-1 and the second storage tank 8-2 to determine the dosage of the agent, resulting in better practical effect. In actual use, oxidizing and non-oxidizing agents should be added to the two first storage tanks 8-1 respectively, and simultaneous addition is prohibited.
[0033] The preferred embodiments of the present utility model disclosed above are only used to help illustrate the present utility model. The preferred embodiments do not describe all the details in detail, nor do they limit the present utility model to the specific implementation methods described. The present specification selects and specifically describes these embodiments in order to better explain the principle and practical application of the present utility model, so that those skilled in the art can better understand and utilize the present utility model.
Claims
1. A multi-medicine cross-throwing device, comprising a mounting box (1), a mounting assembly and a throwing assembly, characterized in that: The installation component is located at the lower end of the installation box (1), the delivery component is located on the side wall of the installation box (1), and a first storage battery is installed inside the installation box (1); The feeding assembly includes two No. 1 storage bins (8-1) and two No. 2 storage bins (8-2). Each of the two No. 1 storage bins (8-1) and the two No. 2 storage bins (8-2) has a feeding hole (11) at its upper end, into which a feeding hopper (9) is inserted. Each of the two No. 1 storage bins (8-1) and the two No. 2 storage bins (8-2) is fixedly connected to a feeding frame (13). Each of the two No. 1 storage bins (8-1) and the two No. 2 storage bins (8-2) has a discharge hole on its lower end face. Each of the four discharge holes is equipped with a third electrically controlled valve (19). Each of the four feeding frames (13) has a discharge hole on its side wall. A discharge pipe (14) is inserted into the discharge hole. A first electrically controlled valve (15-1) and a second electrically controlled valve (15-2) are respectively installed in the discharge pipe (14) below the first storage tank (8-1) and the second storage tank (8-2). A column (2) is fixedly connected in the mounting box (1). A rotating disk (3) is rotatably connected to the upper end of the column (2). A control panel (16) is provided on the rotating disk (3). The control panel (16) is connected to four third electrically controlled valves (19), two first electrically controlled valves (15-1) and two second electrically controlled valves (15-2). A separate liquid level sensor (10) is provided in each of the four delivery boxes (13). A brake motor (5) is fixedly installed on the upper end face of the mounting box (1). A drive gear (6) is fixedly sleeved on the output shaft of the brake motor (5). A gear ring (4) is fixedly connected to the inner wall of the rotating disk (3). The drive gear (6) meshes with the gear ring (4). The control panel (16) is signal connected to the brake motor (5).
2. The multi-drug cross-conversion device according to claim 1, wherein: The side walls of the two No. 1 storage tanks (8-1) and the two No. 2 storage tanks (8-2) are provided with through holes (12), and the four separate liquid level sensors (10) are respectively inserted into the four through holes (12). The four separate liquid level sensors (10) are all connected to the control panel (16) for signal transmission.
3. The multi-drug cross-conversion device according to claim 1, wherein: The rotating disk (3) has four external plates (7) fixedly connected to its side wall. The four external plates (7) are fixedly connected to the side walls of the two No. 1 storage bins (8-1) and the two No. 2 storage bins (8-2), respectively.
4. The multi-drug cross-dosing switching device according to claim 1, wherein: Each of the four delivery boxes (13) is fixedly equipped with a second battery (20), which supplies power to the two first electric valves (15-1), the two second electric valves (15-2), the four third electric valves (19), and the four separate liquid level sensors (10).
5. The multi-drug cross-dosing switching device according to claim 1, wherein: A matching remote control panel is provided outside the control panel (16), and the remote control panel and the control panel (16) are connected by a signal.
6. The multi-drug cross-conversion device according to claim 1, wherein: The mounting assembly includes a base column (17), the lower end of which is fixedly connected to a base (18), the lower end of the mounting box (1) is fixedly connected to the upper end of the base column (17), and the base (18) is provided with a plurality of mounting bolts.
7. The multi-drug cross-dispensing and conversion device according to claim 1, characterized in that: The first battery supplies power to the brake motor (5) and the control panel (16).
8. The multi-drug cross-dispensing and conversion device according to claim 1, characterized in that: The angle of inclination of the bottom slope of the inner wall of the delivery frame (13) is 10°.