An auxiliary device for processing a coating of a titanium electrode of the type in which the coating is inhibited by an anion
By combining heating, cooling, and temperature monitoring structures in the titanium electrode coating process, precise segmented temperature control is achieved, solving the problem of inaccurate temperature control in electromagnetic heating equipment and improving the density and stability of the coating.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 杭州长鸿景盛窗饰有限公司
- Filing Date
- 2025-07-01
- Publication Date
- 2026-06-09
AI Technical Summary
Existing electromagnetic heating equipment lacks precise temperature control in the processing of titanium electrode coatings, resulting in reduced coating density and poor inhibition of sulfate ion erosion.
It adopts a combination of heating structure, cooling structure and temperature monitoring structure to achieve precise segmented temperature control. Through the cooperation of water-cooled coil and segmented heating mechanism, the temperature is monitored and adjusted in real time.
Precise segmented temperature control of the titanium electrode coating was achieved, which improved the density and stability of the coating and inhibited the erosion of sulfate ions.
Smart Images

Figure CN224332635U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of titanium electrode coating processing technology, and in particular to an auxiliary device for titanium electrode coating processing with an acid radical ion suppression type. Background Technology
[0002] During the processing of titanium electrode coatings, sulfate ions are needed to inhibit the erosion of the titanium electrode coating and improve its stability and durability. The erosion principle of sulfate ions is as follows: Chemical dissolution and corrosion: Sulfate ions enter the interstices of the coating lattice through adsorption, participate in the charge transfer of the oxygen evolution reaction, destroy the stable structure of the metal oxide, and accelerate the peeling of the coating. Local current concentration: Sulfate ions accumulate at coating defects (such as microcracks and pores), forming local high current density areas, which can cause pitting or coating peeling. Crystallization expansion stress: In high temperature or high concentration sulfate environments, sulfate ions crystallize in the micropores of the coating (such as forming gypsum), and the volume expansion leads to cracking of the coating.
[0003] To inhibit the corrosion of titanium electrode coatings by sulfate ions, electromagnetic heating equipment (such as induction cookers and high-frequency induction heating equipment) is used. However, electromagnetic heating equipment lacks precise temperature control, which reduces the density of the coating.
[0004] Therefore, in response to the above problems, a new auxiliary device for processing titanium electrode coatings with anodizing ion suppression is proposed. Utility Model Content
[0005] To overcome the problems existing in related technologies, this utility model provides an auxiliary device for processing titanium electrode coatings with an acid radical suppression type, which can achieve precise segmented temperature control by using a combination of heating structure, cooling structure and temperature monitoring structure.
[0006] To achieve the above objectives, the first aspect of this utility model provides an auxiliary device for processing titanium electrode coatings with anodized ion suppression, comprising:
[0007] Protective casing, control cabinet, heat conduction plate, water-cooled coil, segmented heating mechanism and temperature monitoring mechanism;
[0008] A control cabinet is fixedly installed on one side of the protective shell. A heat-conducting plate is fixedly installed on the inner wall of the protective shell. A water-cooling coil is installed at the top inside the protective shell, and the input end of the water-cooling coil is connected to a circulating pump. A segmented heating mechanism for heating is installed below the heat-conducting plate. The segmented heating mechanism is located inside the protective shell and is electrically connected to the control cabinet via a circuit. A temperature monitoring mechanism for real-time temperature monitoring is installed inside the protective shell. The temperature monitoring mechanism is located above the heat-conducting plate and is electrically connected to the control cabinet via a circuit.
[0009] Furthermore, the segmented heating mechanism includes a mounting rack, a mounting slot, and a ceramic heating tube;
[0010] The protective housing contains a mounting rack located below the heat-conducting plate. The upper surface of the mounting rack has equidistant mounting slots, and ceramic heating tubes are installed inside the mounting slots. The ceramic heating tubes are electrically connected to the control cabinet via wiring.
[0011] Furthermore, the mounting slot is designed to be angled.
[0012] Furthermore, the temperature monitoring mechanism includes a first thermocouple sensor and a second thermocouple sensor;
[0013] The protective housing has a first thermocouple sensor symmetrically installed on its inner wall. A second thermocouple sensor connected to the inner wall of the protective housing is provided on one side of the first thermocouple sensor. The first thermocouple sensor is located above the heat-conducting plate, and the second thermocouple sensor is located above the heat-conducting plate. The first thermocouple sensor is electrically connected to the control cabinet via a circuit, and the second thermocouple sensor is electrically connected to the control cabinet via a circuit.
[0014] Furthermore, the temperature monitoring device also includes redundant sensors;
[0015] The heat-conducting plate has a redundant sensor installed on its inner center wall, and the redundant sensor is electrically connected to the control cabinet via a circuit.
[0016] Furthermore, water-cooling coils are symmetrically installed on the inner wall of the protective shell, and the water-cooling coils are located above the temperature monitoring mechanism.
[0017] Furthermore, heat dissipation fins are installed at equal intervals on the upper surface of the protective shell.
[0018] The technical solution provided by this utility model can include the following beneficial effects:
[0019] In this example, by installing a water-cooled coil, a segmented heating mechanism, and a temperature monitoring mechanism, a coated titanium electrode material is placed on the surface of a heat-conducting plate. The control cabinet controls the segmented heating mechanism to start heating. When the temperature monitoring mechanism detects that the temperature in the central area is too high, the circulating pump increases the coolant flow rate of the top water-cooled coil inside the protective shell. When the temperature in the left area is too low, the control cabinet increases the output power of the left side of the segmented heating mechanism. This structure can monitor the temperature changes in each area in real time and adjust the temperature as needed to achieve precise segmented temperature control.
[0020] It should be understood that the above general description and the following detailed description are exemplary and explanatory only, and do not limit the present invention. Attached Figure Description
[0021] The above and other objects, features and advantages of the present invention will become more apparent from the accompanying drawings, in which like reference numerals generally represent like parts.
[0022] Figure 1 This is a schematic diagram of the overall structure from one angle shown in one embodiment of this utility model;
[0023] Figure 2 This is a schematic diagram of the overall structure from another angle, as shown in an embodiment of the present invention;
[0024] Figure 3 This is a schematic diagram of the interior of the protective shell shown in an embodiment of the present invention;
[0025] Figure 4 This is a schematic diagram of the segmented heating mechanism structure shown in an embodiment of the present invention;
[0026] Figure 5 This is a schematic diagram of one of the angle temperature monitoring mechanisms shown in this embodiment of the utility model;
[0027] Figure 6 This is a schematic diagram of another angle temperature monitoring mechanism structure shown in an embodiment of this utility model.
[0028] The correspondence between the labels and component names in the attached figures is as follows:
[0029] 1. Protective shell; 2. Control cabinet; 3. Heat-conducting plate; 4. Water-cooling coil; 5. Segmented heating mechanism; 51. Placement rack; 52. Mounting slot; 53. Ceramic heating tube; 6. Temperature monitoring mechanism; 61. First thermocouple sensor; 62. Second thermocouple sensor; 63. Redundant sensor; 7. Heat dissipation fins. Detailed Implementation
[0030] To make the objectives, technical solutions, and advantages of this utility model clearer, the technical solutions of the embodiments of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only a part of the embodiments of this utility model, and not all of them. All other embodiments obtained by those skilled in the art without creative effort are within the protection scope of this utility model. The preferred embodiments of this utility model will now be described in more detail with reference to the accompanying drawings. Although the preferred embodiments of this utility model are shown in the drawings, it should be understood that this utility model can be implemented in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided to make this utility model more thorough and complete, and to fully convey the scope of this utility model to those skilled in the art.
[0031] The terminology used in this invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular forms “a,” “the,” and “the” used in this invention and the appended claims are also intended to include the plural forms unless the context clearly indicates otherwise. It should also be understood that the term “and / or” as used herein refers to and includes any or all possible combinations of one or more of the associated listed items.
[0032] It should be understood that although the terms "first," "second," "third," etc., may be used in this invention to describe various information, this information should not be limited to these terms. These terms are only used to distinguish information of the same type from one another. For example, without departing from the scope of this invention, first information may also be referred to as second information, and similarly, second information may also be referred to as first information. Thus, features defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of this invention, "a plurality of" means two or more, unless otherwise explicitly specified.
[0033] Designing heating equipment with precise segmented temperature control is currently the primary technical problem that technicians need to solve.
[0034] To address the aforementioned problems, this utility model provides an auxiliary device for processing titanium electrode coatings with an acid radical suppression mechanism. This structure utilizes a combination of a heating structure, a cooling structure, and a temperature monitoring structure to achieve precise segmented temperature control.
[0035] The technical solution of the present invention (Embodiment 1) is described in detail below with reference to the accompanying drawings.
[0036] Figure 1 This is a schematic diagram of the overall structure from one angle shown in one embodiment of this utility model; Figure 2 This is a schematic diagram of the overall structure from another angle, as shown in an embodiment of the present invention; Figure 3 This is a schematic diagram of the interior of the protective shell shown in an embodiment of the present invention; Figure 4 This is a schematic diagram of the segmented heating mechanism structure shown in an embodiment of the present invention; Figure 5 This is a schematic diagram of one of the angle temperature monitoring mechanisms shown in this embodiment of the utility model; Figure 6 This is a schematic diagram of another angle temperature monitoring mechanism structure shown in an embodiment of this utility model.
[0037] See Figure 1 , Figure 2 , Figure 3 , Figure 4 , Figure 5 and Figure 6The auxiliary device for processing titanium electrode coating with an anion-suppressing type specifically includes:
[0038] 1. Protective shell; 2. Control cabinet; 3. Heat conduction plate; 4. Water cooling coil; 5. Segmented heating mechanism; and 6. Temperature monitoring mechanism.
[0039] A control cabinet 2 is fixedly installed on one side surface of the protective shell 1. A heat-conducting plate 3 is fixedly installed on the inner wall of the protective shell 1. A water-cooling coil 4 is installed at the top inside the protective shell 1. The input end of the water-cooling coil 4 is connected to a circulating pump. A segmented heating mechanism 5 for heating is installed below the heat-conducting plate 3. The segmented heating mechanism 5 is located inside the protective shell 1. The segmented heating mechanism 5 is electrically connected to the control cabinet 2 via a circuit. A temperature monitoring mechanism 6 for real-time temperature monitoring is installed inside the protective shell 1. The temperature monitoring mechanism 6 is located above the heat-conducting plate 3. The temperature monitoring mechanism 6 is electrically connected to the control cabinet 2 via a circuit.
[0040] Specifically, the segmented heating mechanism 5 includes a placement rack 51, a mounting groove 52, and a ceramic heating tube 53;
[0041] The protective shell 1 is equipped with a placement rack 51 located below the heat-conducting plate 3. The upper surface of the placement rack 51 is provided with mounting grooves 52 at equal intervals. A ceramic heating tube 53 is installed inside the mounting groove 52. The ceramic heating tube 53 is electrically connected to the control cabinet 2 via a circuit.
[0042] Specifically, the mounting groove 52 is designed to be inclined.
[0043] Specifically, the temperature monitoring mechanism 6 includes a first thermocouple sensor 61 and a second thermocouple sensor 62;
[0044] A first thermocouple sensor 61 is symmetrically installed on the inner wall of the protective shell 1. A second thermocouple sensor 62 connected to the inner wall of the protective shell 1 is provided on one side of the first thermocouple sensor 61. The first thermocouple sensor 61 is located above the heat-conducting plate 3, and the second thermocouple sensor 62 is located above the heat-conducting plate 3. The first thermocouple sensor 61 and the control cabinet 2 are electrically connected by a circuit. The second thermocouple sensor 62 and the control cabinet 2 are electrically connected by a circuit.
[0045] Specifically, the temperature monitoring mechanism 6 also includes redundant sensors 63;
[0046] A redundant sensor 63 is installed on the inner wall of the center of the heat-conducting plate 3, and the redundant sensor 63 is electrically connected to the control cabinet 2 via a circuit.
[0047] Specifically, water-cooled coils 4 are symmetrically installed on the inner wall of the protective shell 1, and the water-cooled coils 4 are located above the temperature monitoring mechanism 6.
[0048] Specifically, heat dissipation fins 7 are installed at equal intervals on the upper surface of the protective shell 1.
[0049] In this embodiment, how to achieve precise segmented temperature control, combined with Figures 1 to 3 The specific implementation method is as follows: a titanium electrode material with a coating is placed on the upper surface of the heat-conducting plate 3. The control cabinet 2 controls the segmented heating mechanism 5 to start heating. When the temperature monitoring mechanism 6 detects that the temperature in the central area is too high, the circulating pump increases the coolant flow of the water-cooling coil 4 at the top inside the protective shell 1. When the temperature in the left area is too low, the control cabinet 2 increases the output power of the left side of the segmented heating mechanism 5. The air energy generated by the blower passes through the heat dissipation fins 7 and can cool the upper surface of the protective shell 1. In conjunction with the water-cooling coil 4, the cooling efficiency can be improved. This structure can monitor the temperature changes of each area in real time and adjust the temperature as needed to achieve the effect of precise segmented temperature control.
[0050] For example: How does the segmented heating mechanism 5 perform segmented heating, combined with... Figure 4 The specific implementation method is as follows: the control cabinet 2 controls the ceramic heating tube 53 inside the mounting slot 52 to start. When the temperature on the left side is too low, the output power of the ceramic heating tube 53 on the left side is increased, which can achieve the effect of segmented heating. After the ceramic heating tube 53 is tilted, the direction of heat radiation forms an angle with the mounting slot 52, and the radiation field is "conical", which can expand the coverage area and the radiation field gathers towards the center.
[0051] In this embodiment, how to monitor the temperature of each area in real time, combined with Figure 5 and Figure 6 The specific implementation method is as follows: two first thermocouple sensors 61 monitor the right area in real time, two second thermocouple sensors 62 monitor the left area in real time, and redundant sensors 63 monitor the middle area in real time. The flow rate of water-cooled coils 4 at different positions is controlled according to the temperature changes in each area to perform segmented cooling, increase the power of segmented heating mechanisms 5 in different areas, and perform reverse segmented heating to achieve the effect of precise segmented temperature control.
[0052] The present invention has been described in detail above with reference to the accompanying drawings. In the above embodiments, the descriptions of each embodiment have different focuses; for parts not described in detail in a certain embodiment, please refer to the relevant descriptions of other embodiments. Those skilled in the art should also understand that the actions and modules involved in the specification are not necessarily essential to the present invention. Furthermore, it is understood that the steps in the method of the present invention embodiments can be adjusted, combined, and deleted according to actual needs, and the structure in the device of the present invention embodiments can be combined, divided, and deleted according to actual needs.
[0053] The various embodiments of the present invention have been described above. These descriptions are exemplary and not exhaustive, nor are they limited to the disclosed embodiments. Many modifications and variations will be apparent to those skilled in the art without departing from the scope and spirit of the described embodiments. The terminology used herein is chosen to best explain the principles, practical application, or improvement of the technology in the market, or to enable others skilled in the art to understand the embodiments disclosed herein.
Claims
1. An auxiliary device for processing titanium electrode coatings with anodizing ion suppression, characterized in that, include: Protective shell (1), control cabinet (2), heat conduction plate (3), water cooling coil (4), segmented heating mechanism (5) and temperature monitoring mechanism (6); A control cabinet (2) is fixedly installed on one side surface of the protective shell (1). A heat-conducting plate (3) is fixedly installed on the inner wall of the protective shell (1). A water-cooling coil (4) is installed at the top inside the protective shell (1). The input end of the water-cooling coil (4) is connected to a circulating pump. A segmented heating mechanism (5) for heating is installed below the heat-conducting plate (3). The segmented heating mechanism (5) is located inside the protective shell (1). The segmented heating mechanism (5) is electrically connected to the control cabinet (2) through a circuit. A temperature monitoring mechanism (6) for real-time temperature monitoring is installed inside the protective shell (1). The temperature monitoring mechanism (6) is located above the heat-conducting plate (3). The temperature monitoring mechanism (6) is electrically connected to the control cabinet (2) through a circuit.
2. The auxiliary device for processing titanium electrode coating with an anion suppression type according to claim 1, characterized in that: The segmented heating mechanism (5) includes a placement rack (51), a mounting groove (52), and a ceramic heating tube (53); The protective shell (1) is equipped with a placement rack (51) located below the heat-conducting plate (3). The upper surface of the placement rack (51) is provided with mounting grooves (52) at equal intervals. The mounting grooves (52) are provided with ceramic heating tubes (53). The ceramic heating tubes (53) are electrically connected to the control cabinet (2) via wiring.
3. The auxiliary device for processing titanium electrode coating with an anion suppression type according to claim 2, characterized in that: The mounting slot (52) is designed to be inclined.
4. The auxiliary device for processing titanium electrode coating with an anion suppression type according to claim 1, characterized in that: The temperature monitoring mechanism (6) includes a first thermocouple sensor (61) and a second thermocouple sensor (62); The protective shell (1) is symmetrically equipped with a first thermocouple sensor (61) on its inner wall. A second thermocouple sensor (62) connected to the inner wall of the protective shell (1) is provided on one side of the first thermocouple sensor (61). The first thermocouple sensor (61) is located above the heat-conducting plate (3), and the second thermocouple sensor (62) is located above the heat-conducting plate (3). The first thermocouple sensor (61) is electrically connected to the control cabinet (2) through a line, and the second thermocouple sensor (62) is electrically connected to the control cabinet (2) through a line.
5. The auxiliary device for processing titanium electrode coating with an anion suppression type according to claim 4, characterized in that: The temperature monitoring mechanism (6) also includes redundant sensors (63). A redundant sensor (63) is installed on the inner wall of the center of the heat-conducting plate (3), and the redundant sensor (63) is electrically connected to the control cabinet (2) via a circuit.
6. The auxiliary device for processing titanium electrode coating with an anion suppression type according to claim 1, characterized in that: Water-cooled coils (4) are symmetrically installed on the inner wall of the protective shell (1), and the water-cooled coils (4) are located above the temperature monitoring mechanism (6).
7. The auxiliary device for processing titanium electrode coating with an anion suppression type according to claim 6, characterized in that: Heat dissipation fins (7) are installed at equal intervals on the upper surface of the protective shell (1).