Electrochemical pipe descaler

By combining and securing the titanium electrode mesh plate with the inner mesh plate, the problems of unstable structure and insufficient electrode contact area in existing electrochemical pipeline descaling devices are solved, achieving efficient descaling and convenient maintenance.

CN224321994UActive Publication Date: 2026-06-05HWASU +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HWASU
Filing Date
2025-06-18
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

Existing electrochemical pipeline descaling devices suffer from structural design flaws such as unstable component connections, inconvenient installation and disassembly, and limited contact area between electrodes and fluids, resulting in descaling efficiency that fails to meet actual needs.

Method used

The design combines a titanium electrode mesh plate and an inner mesh plate for suction, and increases the contact area between the electrode and the fluid by welding fixing blocks and bolts. The electromagnetic block is precisely controlled by a controller to achieve a stable connection and easy disassembly.

Benefits of technology

It improves the completeness of the electrochemical descaling reaction, enhances descaling efficiency, reduces maintenance and time costs, and ensures stable operation of the device and efficient removal of scale from pipelines.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses an electrochemical pipeline descaler, specifically relates to pipeline descaling technical field, including scale suction titanium electrode net board, scale suction titanium electrode net board top and bottom all are fixedly installed with first fixed block through welding, the upside vertical insertion and the connection of first fixed block have connecting screw rod, the bottom detachable mounting of scale suction titanium electrode net board has support plate, this electrochemical pipeline descaler adopts scale suction titanium electrode net board and inner net board combination design, and the contact area of electrode and fluid is increased greatly, makes electrochemical descaling reaction more fully, and promotes descaling efficiency, can remove pipeline dirt quickly and completely, solves the problem that the effect of existing descaling method is poor, simultaneously, using first fixed block, second fixed block, third fixed block, cooperate connecting screw rod, locating nut, realize the stable connection and convenient disassembly of scale suction titanium electrode net board, support plate and cover plate, and the inside component maintenance replacement is convenient, effectively reduces maintenance and time cost.
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Description

Technical Field

[0001] This utility model relates to the field of pipeline descaling technology, and more specifically, to an electrochemical pipeline descaling device. Background Technology

[0002] In industrial production and daily life, pipeline systems are critical infrastructure for transporting various fluid media such as water, oil, and gas. They are widely used in industrial production, municipal water supply, and various fluid transport systems, and their normal operation is of paramount importance.

[0003] A search revealed that patent publication number CN204752268U discloses a pipeline-type sterilizer and descaling device, designed to address the problem of ineffective water purification during urban water transportation. The device comprises a pipeline shell, with a sterilization and descaling mechanism housed within the inner cavity of the shell. An external drive mechanism connected to this mechanism is located on the outside of the shell. The ultrasonic waves and microwaves emitted by the ultrasonic transducer and microwave transmitter in this device have both sterilization and descaling effects on the liquid medium within the pipeline. This pipeline-type sterilizer and descaling device is applied in water supply pipelines. During the development of this invention, the inventors discovered the following problems with the existing technology:

[0004] While existing electrochemical pipeline descaling devices have certain advantages in terms of environmental protection, they have shortcomings in structural design, such as unstable component connections, inconvenient installation and disassembly, and limited contact area between electrodes and fluids, which makes it difficult to meet actual needs for descaling efficiency.

[0005] Therefore, an electrochemical pipeline descaling device is proposed to address the above problems. Summary of the Invention

[0006] In order to overcome the above-mentioned defects of the prior art, the present invention provides an electrochemical pipeline descaling device to solve the problems mentioned in the background art.

[0007] To achieve the above objectives, this utility model provides the following technical solution: an electrochemical pipeline descaling device, comprising a descaling titanium electrode mesh plate, with first fixing blocks fixedly installed at the top and bottom of the descaling titanium electrode mesh plate by welding, a support plate detachably installed at the bottom of the descaling titanium electrode mesh plate, a second fixing block fixedly installed at the edge of the support plate by welding, an inner mesh plate placed inside the descaling titanium electrode mesh plate, a cover plate detachably placed at the top of the descaling titanium electrode mesh plate, a third fixing block fixedly installed at the edge of the cover plate by welding, an electrode rod fixedly installed above the cover plate, the electrode rod penetrating the cover plate and extending into the interior of the inner mesh plate, an electromagnetic block fixedly installed at the top of the electrode rod, a wire fixedly connected to the top of the electromagnetic block, and a controller connected to the end of the wire away from the electromagnetic block.

[0008] Preferably, the first fixing blocks located at both ends of the titanium electrode mesh plate for adsorption are respectively vertically arranged, and a connecting screw is vertically inserted and connected to the upper side of the first fixing block.

[0009] Preferably, the connecting screw will penetrate the second fixing block vertically from above. During the penetration process, the connecting screw will be tightly engaged with the second fixing block, and the connecting screw will penetrate the second fixing block and extend to the bottom of the second fixing block.

[0010] Preferably, the inner mesh plate structure inside the titanium electrode mesh plate has an internal threaded through hole. A positioning bolt is installed inside the internal threaded through hole. When installed, the positioning bolt will penetrate the support plate from the bottom of the inner mesh plate downwards, and a fastening nut is also fitted on the outer thread of the positioning bolt extending to the support plate.

[0011] Preferably, when the cover plate and the titanium electrode mesh plate are installed, the titanium electrode mesh plate and the cover plate need to overlap. The third fixing block fixed at the edge of the cover plate will overlap with the first fixing block installed on the titanium electrode mesh plate. The connecting screw passes through the third fixing block and continues to extend upward until it reaches the top of the cover plate. Positioning nuts are threaded on the top and bottom of the connecting screw.

[0012] Preferably, a handle is fixedly installed on the top of the controller, and the handle is located in the center of the controller.

[0013] Preferably, a control switch is movably mounted on the front side of the controller, and a display screen is also fixedly mounted on the front side of the controller, with the display screen located in the upper left corner of the controller.

[0014] The technical effects and advantages of this utility model are as follows:

[0015] Compared with existing technologies, this electrochemical pipeline descaling device, through the combination design of the descaling titanium electrode mesh plate and the inner mesh plate, greatly increases the contact area between the electrode and the fluid, making the electrochemical descaling reaction more complete and effectively improving the descaling efficiency. It can remove the dirt in the pipeline more quickly and thoroughly, solving the problem of poor descaling effect of existing descaling methods.

[0016] Compared with existing technologies, this electrochemical pipeline descaling device achieves a stable connection and convenient disassembly of the titanium electrode mesh plate, support plate and cover plate through the cooperation of the first fixing block, the second fixing block, the third fixing block and the connecting screw and the positioning nut. This facilitates the maintenance and replacement of internal components and reduces maintenance and time costs. Attached Figure Description

[0017] Figure 1 This is a schematic diagram of the overall three-dimensional structure of this utility model.

[0018] Figure 2This is a front view structural diagram of the present utility model.

[0019] Figure 3 This is a schematic diagram of the titanium electrode mesh plate structure for adsorption of dirt according to this utility model.

[0020] Figure 4 This is a schematic diagram of the bottom structure of the titanium electrode mesh plate for adsorption of dirt in this utility model.

[0021] Figure 5 This is a schematic diagram of the inner mesh plate structure of this utility model.

[0022] The attached diagram is labeled as follows: 1. Titanium electrode mesh plate for suction; 2. First fixing block; 3. Connecting screw; 4. Support plate; 5. Second fixing block; 6. Inner mesh plate; 7. Internal threaded through hole; 8. Positioning bolt; 9. Cover plate; 10. Third fixing block; 11. Positioning nut; 12. Electrode rod; 13. Electromagnetic block; 14. Wire; 15. Controller; 16. Handle; 17. Control switch; 18. Display screen. Detailed Implementation

[0023] 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. Example 1

[0024] As attached Figures 1 to 5 An electrochemical pipe descaling device is shown, comprising a descaling titanium electrode mesh plate 1, with first fixing blocks 2 fixedly installed at the top and bottom of the descaling titanium electrode mesh plate 1 by welding, a support plate 4 detachably installed at the bottom of the descaling titanium electrode mesh plate 1, a second fixing block 5 fixedly installed at the edge of the support plate 4 by welding, an inner mesh plate 6 placed inside the descaling titanium electrode mesh plate 1, a cover plate 9 detachably placed at the top of the descaling titanium electrode mesh plate 1, a third fixing block 10 fixedly installed at the edge of the cover plate 9 by welding, an electrode rod 12 fixedly installed above the cover plate 9, the electrode rod 12 penetrating the cover plate 9 and extending into the interior of the inner mesh plate 6, an electromagnetic block 13 fixedly installed at the top of the electrode rod 12, a wire 14 fixedly connected to the top of the electromagnetic block 13, and a controller 15 connected to the end of the wire 14 away from the electromagnetic block 13.

[0025] The titanium electrode mesh plate 1 for adsorption is designed as follows: First fixing blocks 2 are welded to the top and bottom of the plate, and screws 3 are connected to them. A support plate 4 is detachably installed at the bottom, and a second fixing block 5 is welded to the edge of the support plate 4. This design facilitates the installation and removal of the titanium electrode mesh plate 1 for adsorption, making subsequent maintenance and replacement easier and improving work efficiency. Second, an inner mesh plate 6 is placed inside the titanium electrode mesh plate 1 for adsorption, which enhances structural stability and improves adsorption effect. Third, a cover plate 9 is detachably placed on the top, and a third fixing block 10 is welded to the edge of the cover plate 9, which facilitates opening the cover plate 9 to inspect and clean the inner mesh plate 6 and other components. Fourth, an electrode rod 12 is fixed above the cover plate 9, which extends through the cover plate 9 into the inner mesh plate 6. An electromagnetic block 13 is fixed on the top, and the electromagnetic block 13 is connected to a controller 15 through a wire 14. The controller 15 can precisely control the operation of the electromagnetic block 13, thereby controlling the electrode rod 12, achieving precise control of the adsorption process, improving adsorption efficiency and quality, and ensuring stable operation of the equipment. Example 2

[0026] Based on Embodiment 1, the solution in Embodiment 1 will be further described in detail below with reference to the specific working method, such as... Figures 1 to 5 As shown below, see details:

[0027] In a preferred embodiment, the first fixing blocks 2 located at both ends of the titanium electrode mesh plate 1 are respectively vertically arranged, which can ensure that the first fixing blocks 2 at both ends can better cooperate with the connecting screws 3 and other components during the installation and use of the entire device. The connecting screws 3 are vertically inserted and connected to the upper side of the first fixing blocks 2, so that the device remains stable when subjected to force, and avoids affecting the descaling effect and the overall performance of the device due to tilting or displacement.

[0028] In a preferred embodiment, the second fixing block 5 and the first fixing block 2 are arranged in an overlapping manner, making the connection between the components more compact and reasonable, reducing space waste, and facilitating the installation and placement of the device. The connecting screw 3 will pass vertically through the second fixing block 5 from above. During the penetration process, the connecting screw 3 and the second fixing block 5 are tightly engaged, which can ensure the connection between the second fixing block 5 and related components is stable, effectively transmit force, and avoid affecting the stability and reliability of the device due to loose connection. The connecting screw 3 passes through the second fixing block 5 and extends to the bottom of the second fixing block 5, which can further enhance the firmness of the connection, provide protection for the device to withstand various external forces during operation, and extend the service life of the device.

[0029] In a preferred embodiment, the inner mesh plate 6 placed inside the titanium electrode mesh plate 1 has an internally threaded through hole 7, which provides an installation base for the positioning bolt 8. This design provides a clear positioning point for the connection between the inner mesh plate 6 and subsequent components, facilitating installation and improving installation efficiency. The positioning bolt 8 is installed inside the internally threaded through hole 7. During installation, the positioning bolt 8 penetrates the support plate 4 from the bottom of the inner mesh plate 6, effectively fixing the inner mesh plate 6 and the support plate 4 and preventing relative displacement between them during operation, thus ensuring the stability of the device structure. Furthermore, the positioning bolt 8 extends to the outer thread of the support plate 4 and is fitted with a fastening nut, which enhances the firmness of the connection and effectively prevents loosening due to vibration or other reasons, ensuring normal descaling operation of the device.

[0030] In a preferred embodiment, when the cover plate 9 is installed with the titanium electrode mesh plate 1, the titanium electrode mesh plate 1 and the cover plate 9 need to overlap to ensure a tight fit. This makes the overall structure of the device compact, reduces space occupation, and facilitates the integration and stable operation of the device. The third fixing block 10 fixed at the edge of the cover plate 9 will overlap with the first fixing block 2 installed on the titanium electrode mesh plate 1, providing precise positioning for the connecting screw 3, enhancing connection stability, and ensuring a firm connection between the cover plate 9 and the titanium electrode mesh plate 1. The connecting screw 3 passes through the third fixing block 10 and continues to extend upward until it reaches the top of the cover plate 9. Positioning nuts 11 are threaded on the top and bottom of the connecting screw 3 to effectively fix the cover plate 9, prevent it from loosening, and ensure the normal operation of the device.

[0031] As a preferred embodiment, a handle 16 is fixedly installed on the top of the controller 15. The handle 16 is located in the center of the controller 15, which is convenient for the operator to grip. Moreover, when the controller 15 is moved or transported, the force is evenly distributed, which can prevent damage to the internal components of the controller 15 due to uneven force. The handle 16 is made of a sturdy and durable material and has an anti-slip surface, which further improves the convenience and safety of operation.

[0032] In a preferred embodiment, a control switch 17 is movably installed on the front side of the controller 15. The operator can flexibly operate the control switch 17 according to actual needs to adjust the operating status of the descaling device, such as turning the device on or off or switching different working modes. At the same time, a display screen 18 is also fixedly installed on the front side of the controller 15. The display screen 18 is located in the upper left corner of the controller 15. The display screen 18 can display various operating parameters of the descaling device in real time, such as current, voltage, and descaling progress, so that the operator can keep track of the device's operating status at any time.

[0033] The working process of this utility model is as follows: When in use, firstly, place the titanium electrode mesh plate 1 for suction in a suitable position, and the support plate 4 can be detachably installed at its bottom. At this time, the top and bottom of the titanium electrode mesh plate 1 are respectively set vertically by welding the first fixing block 2, and the second fixing block 5 welded to the edge of the support plate 4 coincides with the first fixing block 2. The connecting screw 3 is vertically inserted through the second fixing block 5 from above, and the connecting screw 3 fits tightly with the second fixing block 5. It continues to extend downward to the bottom of the second fixing block 5. An inner mesh plate 6 is placed inside the titanium electrode mesh plate 1. The inner mesh plate 6 has an internally threaded through hole 7. The positioning bolt 8 is inserted downward through the support plate 4 from the bottom of the inner mesh plate 6. A fastening nut is fitted on the thread of the positioning bolt 8 extending to the outside of the support plate 4 to complete the installation and fixation of the inner mesh plate 6. Next, the cover plate 9 is detachably placed on top of the titanium electrode mesh plate 1 so that the two overlap. The third fixing block 10, which is welded and fixed at the edge of the cover plate 9, overlaps with the first fixing block 2 on the titanium electrode mesh plate 1. The connecting screw 3 passes through the third fixing block 10 and continues to extend upward to the top of the cover plate 9. Positioning nuts 11 are threaded on the top and bottom of the connecting screw 3 to complete the installation of the cover plate 9. After installation, the electrode rod 12 is fixedly installed above the cover plate 9. The electrode rod 12 passes through the cover plate 9 and extends into the interior of the inner mesh plate 6. An electromagnetic block 13 is fixedly installed on the top of the electrode rod 12. The end of the wire 14 fixedly connected to the top of the electromagnetic block 13 away from the electromagnetic block 13 is connected to the controller 15. Finally, the controller 15 is placed in a suitable position by using the handle 16 fixedly installed on the top of the controller 15 in the middle position. The control switch 17 movable on the front side of the controller 15 is operated to start the equipment. During the operation of the equipment, the working parameters can be monitored in real time by using the display screen 18 fixedly installed in the upper left corner of the controller 15, and adjustments can be made accordingly based on the actual situation.

Claims

1. An electrochemical pipeline descaling device, comprising a titanium electrode mesh plate for descaling (1), characterized in that: The top and bottom of the titanium electrode mesh plate (1) are fixedly installed with a first fixing block (2) by welding. The bottom of the titanium electrode mesh plate (1) is detachably installed with a support plate (4). The edge of the support plate (4) is fixedly installed with a second fixing block (5) by welding. An inner mesh plate (6) is placed inside the titanium electrode mesh plate (1). The top of the titanium electrode mesh plate (1) is detachably installed with a cover plate (9). The edge of the cover plate (9) is fixedly installed with a third fixing block (10) by welding. An electrode rod (12) is fixedly installed above the cover plate (9). The electrode rod (12) passes through the cover plate (9) and extends into the interior of the inner mesh plate (6). An electromagnetic block (13) is fixedly installed on the top of the electrode rod (12). A wire (14) is fixedly connected to the top of the electromagnetic block (13). The end of the wire (14) away from the electromagnetic block (13) is connected to a controller (15).

2. The electrochemical pipeline descaling device according to claim 1, characterized in that: The first fixing blocks (2) located at both ends of the titanium electrode mesh plate (1) are respectively vertically set, and the upper side of the first fixing block (2) is vertically inserted and connected to the connecting screw (3).

3. The electrochemical pipeline descaling device according to claim 2, characterized in that: The connecting screw (3) will penetrate the second fixing block (5) vertically from above. During the penetration process, the connecting screw (3) and the second fixing block (5) are closely matched. The connecting screw (3) penetrates the second fixing block (5) and extends to the bottom of the second fixing block (5).

4. An electrochemical pipeline descaling device according to claim 2, characterized in that: The inner mesh plate (6) inside the titanium electrode mesh plate (1) has an internal threaded through hole (7). A positioning bolt (8) is installed inside the internal threaded through hole (7) by thread. When the positioning bolt (8) is installed, it will penetrate the support plate (4) from the bottom of the inner mesh plate (6). The positioning bolt (8) extends to the outside of the support plate (4) and a fastening nut is also fitted on the thread.

5. An electrochemical pipeline descaling device according to claim 4, characterized in that: When the cover plate (9) is installed with the titanium electrode mesh plate (1), the titanium electrode mesh plate (1) and the cover plate (9) need to overlap. The third fixing block (10) fixed at the edge of the cover plate (9) will overlap with the first fixing block (2) installed on the titanium electrode mesh plate (1). The connecting screw (3) passes through the third fixing block (10) and continues to extend upward until it reaches the top of the cover plate (9). Positioning nuts (11) are threaded on the top and bottom of the connecting screw (3).

6. An electrochemical pipeline descaling device according to claim 4, characterized in that: A handle (16) is fixedly installed on the top of the controller (15), and the handle (16) is located in the center of the controller (15).

7. An electrochemical pipeline descaling device according to claim 4, characterized in that: A control switch (17) is movably provided on the front side of the controller (15). At the same time, a display screen (18) is fixedly placed on the front side of the controller (15), and the display screen (18) is located in the upper left corner of the controller (15).