Ion generation module and electronic equipment

By employing a structure in which an intermediate electrode plate abuts against the refrigeration component in the electrical appliance, and using a high-voltage power supply to cause condensate to migrate in a directional manner in an electromagnetic field, the problem of corrosion and aging of the refrigeration components is solved. This enables the simultaneous generation of water ions and negative ions, improving the performance of the device and extending its service life.

CN224438231UActive Publication Date: 2026-06-30ZHONGSHAN VTUNE TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ZHONGSHAN VTUNE TECH CO LTD
Filing Date
2025-07-15
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Existing water ion generators in electrical appliances suffer from corrosion and aging problems because the cooling components are directly used as discharge electrodes, affecting their service life and output.

Method used

An intermediate electrode plate is used to contact the refrigeration component. A high-voltage power supply is used to cause the condensate to migrate in a directional manner in an electromagnetic field, replacing the condenser to discharge and generate water ions and negative ions, thus avoiding direct discharge corrosion of the condenser.

Benefits of technology

It extends the lifespan of the cooling components, improves ion generation efficiency, ensures stable generation of negative ions, and saves hardware costs.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224438231U_ABST
    Figure CN224438231U_ABST
Patent Text Reader

Abstract

This utility model relates to an ion generating module and an electronic device. The ion generating module includes: a support; an electrode assembly including a first high-voltage electrode, a second high-voltage electrode, and an intermediate electrode plate, wherein the first high-voltage electrode and the second high-voltage electrode are respectively disposed on both sides of the support, and the intermediate electrode plate has a first end and a second end opposite to each other, the first end being close to the first high-voltage electrode and the second end being close to the second high-voltage electrode; a cooling assembly for forming condensate on the intermediate electrode plate; and a high-voltage power supply, the two ends of which are respectively connected to the first high-voltage electrode and the second high-voltage electrode and apply high voltage to drive the condensate to move along the intermediate electrode plate to the first end under the action of the electromagnetic field formed by the first high-voltage electrode and the second high-voltage electrode, thereby forming a high-voltage discharge between the first end and the first high-voltage electrode to ionize the condensate on the first end to generate water ions, and a high-voltage discharge between the second end and the second high-voltage electrode to ionize the air to generate negative ions.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the field of household appliance technology, and in particular to an ion generating module and electronic device. Background Technology

[0002] As people's quality of life continues to improve and scientific literature fully demonstrates the health benefits of water ions and negative ions, manufacturers of electrical appliances such as hair dryers and air purifiers are increasingly incorporating water ion and negative ion technologies into their products to provide users with a better product experience.

[0003] However, most water ion generators on the market currently use the cooling components directly as discharge electrodes. At the same time, in order to ensure the condensation effect, the cooling components are generally made of materials with good thermal conductivity, such as aluminum or copper. Therefore, long-term operation can lead to corrosion and aging of the cooling components, which shortens the service life of the water ion generator and reduces the amount of water ions generated. Utility Model Content

[0004] Therefore, it is necessary to provide an ion generation module and electronic device, addressing the issue that most water ion generators on the market currently use the cooling components directly as discharge electrodes, which leads to corrosion and aging of the cooling components over long-term operation.

[0005] An ion generating module includes: a support; an electrode assembly comprising a first high-voltage electrode, a second high-voltage electrode, and an intermediate electrode plate, wherein the first high-voltage electrode and the second high-voltage electrode are respectively disposed on both sides of the support, and the intermediate electrode plate is located between the first high-voltage electrode and the second high-voltage electrode, the intermediate electrode plate having a first end and a second end opposite to each other, the first end of the intermediate electrode plate being close to the first high-voltage electrode, and the second end of the intermediate electrode plate being close to the second high-voltage electrode; a cooling assembly abutting against the intermediate electrode plate for condensing moisture in the air onto the intermediate electrode plate to form condensate; and a high-voltage power supply, the two ends of which are respectively connected to the first high-voltage electrode and the second high-voltage electrode and apply high voltage to drive the condensate to move along the intermediate electrode plate to the first end under the action of the electromagnetic field formed by the first high-voltage electrode and the second high-voltage electrode, wherein a high-voltage discharge is formed between the first end and the first high-voltage electrode to ionize the condensate on the first end to generate water ions, and a high-voltage discharge is formed between the second end and the second high-voltage electrode to ionize the air to generate negative ions.

[0006] This application provides an ion generating module, in which an intermediate electrode plate is provided between a first high-voltage electrode and a second high-voltage electrode, and the intermediate electrode plate abuts against a refrigeration component. When the refrigeration component is working, moisture in the air can condense into condensate and accumulate on the intermediate electrode plate. At the same time, the two ends of the high-voltage power supply are connected to the first high-voltage electrode and the second high-voltage electrode respectively, and a high voltage is applied, causing the condensate on the intermediate electrode plate to be polarized in the electromagnetic field formed by the first high-voltage electrode and the second high-voltage electrode and to undergo electrophoretic movement, migrating directionally to the first end of the intermediate electrode plate. Thus, a high-voltage discharge is formed between the first end and the first high-voltage electrode. The high-voltage electric field ionizes the condensate on the first end to generate water ions, while a high-voltage discharge is formed between the second end and the second high-voltage electrode to ionize the air and generate negative ions. The ion generation module of this application achieves both water ion generation and negative ion generation functions simultaneously by employing a simplified electrode assembly. This not only improves device performance but also saves hardware costs. Furthermore, compared to existing technologies that directly discharge the condenser of the cooling component, this device utilizes the first end of the intermediate electrode plate to discharge instead of the condenser during water ion generation. This avoids the corrosion and aging problems associated with the condenser, extending its lifespan. Moreover, the condensate at the second end of the intermediate electrode plate can rapidly migrate to the first end under the influence of the electromagnetic field, thus keeping the air at the second end dry and effectively ensuring stable negative ion generation. The generated negative ions are also rapidly guided to the first end under the influence of the electromagnetic field to mix with water ions for output.

[0007] In one embodiment, the refrigeration assembly includes a condenser and a Peltier, the Peltier being used to cool the condenser. An intermediate electrode plate is disposed on the side of the condenser away from the Peltier, and the condenser is used to condense moisture in the air onto the intermediate electrode plate to form condensate. By employing this structure, the device utilizes the first end of the intermediate electrode plate to perform discharge instead of the condenser during water ion generation. Specifically, the intermediate electrode plate is made of a discharge-resistant corrosion-resistant material such as stainless steel or titanium alloy, thereby avoiding the corrosion and aging problems of the refrigeration assembly and extending its lifespan.

[0008] In one embodiment, the condenser is disposed within the support. The inner side of the top wall of the support is in close contact with the top wall of the condenser and / or the intermediate electrode plate and has a vent hole communicating with the outside. The vent hole is positioned opposite to the middle of the condenser and the intermediate electrode plate. By adopting the above structure, the condenser can be better protected by the support, preventing the first high-voltage electrode from directly discharging to the condenser. Furthermore, the condenser and / or the intermediate electrode plate are in close contact with the top wall of the support and are in contact with the outside air through the vent hole. As a result, the condensate produced by the condenser will be contained and accumulated in the vent hole and fall onto the upper surface of the intermediate electrode plate.

[0009] In one embodiment, the top wall of the condenser is recessed to form a through groove opposite to the vent hole. The through groove extends horizontally, and the intermediate electrode plate is adapted to be inserted into the through groove. By providing a through groove on the top wall of the condenser for adaptation and installation with the intermediate electrode plate, a positioning function is provided to facilitate quick connection between the intermediate electrode plate and the condenser. Furthermore, it allows the height of the top wall of the intermediate electrode plate to be less than or equal to the top wall of the condenser, thereby enabling the condensate accumulated in the vent hole to more easily fall onto the upper surface of the intermediate electrode plate and migrate, which is beneficial for improving the water ion generation efficiency.

[0010] In one embodiment, the sidewall of the vent near the first end of the intermediate electrode plate has a first notch that communicates with the outside, allowing condensate accumulated in the vent to pass through and move along the intermediate electrode plate to the first end of the intermediate electrode plate. When the intermediate electrode plate is transversely connected to the vent, the first notch facilitates the outflow of condensate, which then migrates directionally along the intermediate electrode plate to the first end of the intermediate electrode plate under the influence of the electromagnetic field formed by the first and second high-voltage electrodes.

[0011] In one embodiment, the vent hole has a second notch on the sidewall near the second end of the intermediate electrode plate, allowing condensate on the second end of the intermediate electrode plate to pass through and enter the vent hole. With this structure, a small amount of condensate at the second end of the intermediate electrode plate will, under the influence of an electromagnetic field, pass through the second notch into the vent hole, and further migrate through the first notch to the first end of the intermediate electrode plate. This keeps the air at the second end dry, effectively ensuring the stable generation of negative ions. Furthermore, the generated negative ions can be quickly guided along this path to the first end under the influence of the electromagnetic field to mix with water ions and be output.

[0012] In one embodiment, the bracket includes a base plate and a mounting platform. The mounting platform protrudes from the base plate. The first high-voltage electrode and the second high-voltage electrode are respectively disposed on opposite outer sides of the mounting platform. The intermediate electrode plate is located on the mounting platform. The mounting platform has a mounting groove, and the condenser is located in the mounting groove and abuts against its bottom wall. The bottom wall of the mounting groove has the vent hole. By adopting the above structure, the condenser, disposed in the mounting groove of the mounting platform and abutting against the intermediate electrode plate, can effectively isolate itself from the first and second high-voltage electrodes located on the outer side of the mounting platform. Furthermore, the protrusion facilitates positioning and engagement with various components, allowing each component to automatically align when installed in a preset position on the protrusion.

[0013] In one embodiment, the bottom wall of the mounting groove protrudes to form a limiting ring, the limiting ring having a mounting hole opposite to the vent hole, and the condenser being adapted to be disposed in the mounting hole.

[0014] In one embodiment, the outer wall of the base plate or the mounting platform is provided with a first positioning post, and the first high-voltage electrode is formed with a first positioning hole adapted to be installed with the first positioning post.

[0015] In one embodiment, the outer wall of the base plate or the mounting platform is provided with a second positioning post, and the second high-voltage electrode is formed with a second positioning hole adapted to be installed with the second positioning post.

[0016] In one embodiment, the bracket has a first mounting channel on the side near the first high-voltage electrode. One end of the first mounting channel communicates with the vent hole, and the other end of the first mounting channel has a first opening. The first end of the intermediate electrode plate passes through the first mounting channel and extends out through the first opening, approaching the first high-voltage electrode. The first mounting channel provides a positioning support, ensuring that the first end of the intermediate electrode plate is automatically aligned with the first high-voltage electrode and securely installed after being inserted into the first mounting channel.

[0017] In one embodiment, the mounting platform is provided with the first mounting channel.

[0018] In one embodiment, the first mounting channel is connected to the vent hole via the first notch.

[0019] In one embodiment, the intermediate electrode plate and the inner wall of the first mounting channel form a first liquid passage, and the vent hole, the first liquid passage, and the first opening are sequentially connected. The formation of the first liquid passage better surrounds and guides the condensate moving on the upper surface of the intermediate electrode plate, ensuring that the condensate can move more accurately and quickly along the first liquid passage to the first end of the intermediate electrode plate.

[0020] In one embodiment, at least a portion of the first mounting channel is formed by a recess in the bottom wall of the mounting groove. This allows the intermediate electrode plate to more easily mate with the inner wall of the first mounting channel to form a first liquid passage. Furthermore, the first liquid passage communicates with the vent hole through the first notch.

[0021] In one embodiment, the diameter of the first opening gradually decreases towards the first high-voltage electrode, and the first end of the intermediate electrode plate is fitted and installed with the first opening. By adopting the above structure, the first opening can limit the first end of the intermediate electrode plate, so that the intermediate electrode plate can be accurately and quickly installed in a preset position, and the first end of the intermediate electrode plate can maintain an effective distance from the first high-voltage electrode.

[0022] In one embodiment, the first end of the intermediate electrode plate is triangular or conical.

[0023] In one embodiment, the bracket has a second mounting channel on the side near the second high-voltage electrode. One end of the second mounting channel communicates with the vent hole, and the other end of the second mounting channel has a second opening. The second end of the intermediate electrode plate passes through the second mounting channel and extends out through the second opening, approaching the second high-voltage electrode. The second mounting channel further enhances the positioning and support of the intermediate electrode plate, ensuring that after the intermediate electrode plate is inserted into the second mounting channel, its second end automatically aligns with the second high-voltage electrode and is securely installed.

[0024] In one embodiment, the second mounting channel is coaxially arranged with the first mounting channel.

[0025] In one embodiment, the intermediate electrode plate and the inner wall of the second mounting channel enclose each other to form a second liquid passage, and the second liquid passage, the vent hole, the first notch and the first liquid passage are sequentially connected.

[0026] In one embodiment, at least a portion of the second mounting channel is formed by a recess in the bottom wall of the mounting groove. This allows the intermediate electrode plate to more easily mate with the inner wall of the second mounting channel to form a second liquid passage. Furthermore, the second liquid passage communicates with the vent hole through the second notch.

[0027] In one embodiment, the mounting platform is provided with the second mounting channel and the second opening.

[0028] In one embodiment, the cooling assembly further includes a heat sink, and the Peltier has opposing heat dissipation and cooling ends. The cooling end of the Peltier abuts against the condenser, and the heat dissipation end of the Peltier abuts against the heat sink. By providing the heat sink, the heat generated at the heat dissipation end of the Peltier can be dissipated, thereby maintaining and improving the cooling effect of the cooling end.

[0029] In one embodiment, the bracket is positioned above the heat sink, and the bracket and the heat sink together form a mounting cavity, in which the condenser and the Peltier are disposed. Through the cooperation of the bracket and the heat sink, the heat sink not only dissipates heat but also provides support and protection for the condenser and the Peltier. The mounting cavity formed by the two isolates external moisture, ensuring the stable operation of the Peltier.

[0030] In one embodiment, the heat sink is disposed on the side of the base plate away from the mounting platform, and surrounds the inner wall of the mounting groove to form the mounting cavity.

[0031] In one embodiment, the bracket is provided with a first connection hole, and the heat sink is provided with a second connection hole. The first connection hole and the second connection hole are connected by fasteners.

[0032] In one embodiment, the first high-voltage electrode and the second high-voltage electrode are electrically connected to the positive and negative terminals of the high-voltage power supply, respectively. The condensed water on the intermediate electrode plate becomes negatively charged after being polarized in the electromagnetic field formed by the first and second high-voltage electrodes. Under the influence of the electric field, it migrates towards the first end of the intermediate electrode plate, where it is further ionized to generate water ions.

[0033] In one embodiment, the first high-voltage electrode includes an annular body and a connecting portion. The annular body is connected to the support via the connecting portion. A high-voltage discharge is formed between the annular body and the first end of the intermediate electrode plate to ionize the condensed water on the first end and generate water ions. By adopting the above structure, the annular body, after being connected and fitted to the support via the connecting portion, can be aligned and fixed with the first end of the intermediate electrode plate. Simultaneously, the annular structure provides a more uniform high-voltage electric field. Further, the first end of the intermediate electrode plate is coaxially arranged with the annular body.

[0034] A second aspect of this application provides an electronic device.

[0035] An electronic device comprising the aforementioned ion generating module. Attached Figure Description

[0036] Figure 1 A perspective view of an ion generating module according to one embodiment;

[0037] Figure 2 An exploded view of an ion generating module according to one embodiment;

[0038] Figure 3 This is a cross-sectional view of an ion generating module according to one embodiment;

[0039] Figure 4 A first perspective view of a bracket according to one embodiment;

[0040] Figure 5 A second perspective view of a bracket according to one embodiment;

[0041] Figure 6 This is a cross-sectional view of a bracket according to one embodiment.

[0042] The correspondence between the reference numerals and the component names is as follows:

[0043] 1. Bracket, 101. Vent hole, 102. First notch, 103. Second notch, 104. Mounting groove, 105. Mounting hole, 106. First mounting channel, 107. First opening, 108. Second mounting channel, 109. Second opening, 110. First connecting hole, 11. Base plate, 12. Mounting platform, 13. Limiting ring, 14. First positioning post, 15. Second positioning post;

[0044] 2. Electrode assembly, 201 first positioning hole, 202 second positioning hole, 203 first liquid passage, 204 second liquid passage, 21 first high-voltage electrode, 211 annular body, 212 connecting part, 22 second high-voltage electrode, 23 intermediate electrode plate, 231 first end, 232 second end;

[0045] 3 Refrigeration components, 301 through slot, 302 second connection hole, 31 condenser, 32 Peltier, 33 heat dissipation components;

[0046] 4. Fasteners. Detailed Implementation

[0047] To better understand the above-mentioned objectives, features, and advantages of the present invention, the present invention will be further described in detail below with reference to the accompanying drawings and specific embodiments. It should be noted that, unless otherwise specified, the embodiments and features described in these embodiments can be combined with each other.

[0048] Many specific details are set forth in the following description in order to provide a full understanding of the invention. However, the invention may also be practiced in other ways different from those described herein, and therefore the scope of protection of the invention is not limited to the specific embodiments disclosed below.

[0049] The ion generating module of some embodiments of the present invention is described below with reference to the accompanying drawings.

[0050] like Figures 1 to 6As shown, this embodiment discloses an ion generating module, including: a support 1; an electrode assembly 2, which includes a first high-voltage electrode 21, a second high-voltage electrode 22, and an intermediate electrode plate 23. The first high-voltage electrode 21 and the second high-voltage electrode 22 are respectively disposed on both sides of the support 1, and the intermediate electrode plate 23 is located between the first high-voltage electrode 21 and the second high-voltage electrode 22. The intermediate electrode plate 23 has a first end 231 and a second end 232 facing each other. The first end 231 of the intermediate electrode plate 23 is close to the first high-voltage electrode 21, and the second end 232 of the intermediate electrode plate 23 is close to the second high-voltage electrode 22; and a cooling assembly 3. Component 3 abuts against the intermediate electrode plate 23 to condense moisture in the air onto the intermediate electrode plate 23 to form condensate. A high-voltage power supply is connected at both ends to the first high-voltage electrode 21 and the second high-voltage electrode 22 respectively and applies high voltage to drive the condensate to move along the intermediate electrode plate 23 to the first end 231 under the action of the electromagnetic field formed by the first high-voltage electrode 21 and the second high-voltage electrode 22. A high-voltage discharge is formed between the first end 231 and the first high-voltage electrode 21 to ionize the condensate on the first end 231 to generate water ions. A high-voltage discharge is formed between the second end 232 and the second high-voltage electrode 22 to ionize the air to generate negative ions.

[0051] This application provides an ion generating module, in which an intermediate electrode plate 23 is provided between a first high-voltage electrode 21 and a second high-voltage electrode 22, and the intermediate electrode plate 23 abuts against a cooling component 3. When the cooling component 3 is working, moisture in the air can condense into condensate and accumulate on the intermediate electrode plate 23. At the same time, the two ends of the high-voltage power supply are connected to the first high-voltage electrode 21 and the second high-voltage electrode 22 respectively, and a high voltage is applied, so that the condensate on the intermediate electrode plate 23 is polarized in the electromagnetic field formed by the first high-voltage electrode 21 and the second high-voltage electrode 22 and undergoes electrophoretic movement, and migrates directionally to the first end 231 of the intermediate electrode plate 23. Thus, a high-voltage discharge is formed between the first end 231 and the first high-voltage electrode 21. The high-voltage electric field ionizes the condensate on the first end 231 to generate water ions, while a high-voltage discharge is formed between the second end 232 and the second high-voltage electrode 22 to ionize the air and generate negative ions. The ion generation module of this application can simultaneously achieve water ion generation and negative ion generation functions by using a simplified electrode assembly 2. This not only improves device performance but also saves hardware costs. Furthermore, compared to existing technologies that directly discharge the condenser 31 of the cooling assembly 3, this device uses the first end 231 of the intermediate electrode plate 23 to discharge instead of the condenser 31 during water ion generation, thereby avoiding the problem of discharge corrosion and aging of the condenser 31 and extending its lifespan. Further, the condensate at the second end 232 of the intermediate electrode plate 23 can also rapidly migrate to the first end 231 under the influence of the electromagnetic field, thus keeping the air at the second end 232 dry and effectively ensuring the stable generation of negative ions. The generated negative ions can also be rapidly guided to the first end 231 under the influence of the electromagnetic field to mix with water ions for output.

[0052] like Figure 2 and Figure 3 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the refrigeration component 3 includes a condenser 31 and a Peltier 32, the Peltier 32 is used to cool the condenser 31, and the intermediate electrode plate 23 is disposed on the side of the condenser 31 away from the Peltier 32. The condenser 31 is used to condense moisture in the air onto the intermediate electrode plate 23 to form condensate. By adopting the above structure, this device uses the first end 231 of the intermediate electrode plate 23 to replace the condenser 31 for discharge during the water ion generation process. Specifically, the intermediate electrode plate 23 is also made of a discharge corrosion resistant material such as stainless steel or titanium alloy, thereby avoiding the problem of corrosion and aging of the refrigeration component 3 and extending the life of the refrigeration component 3.

[0053] like Figure 2 and Figure 3As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the condenser 31 is disposed in the support 1, the inner side of the top wall of the support 1 is in close contact with the top wall of the condenser 31 and / or the intermediate electrode plate 23 and is provided with a vent hole 101 communicating with the outside, the vent hole 101 being disposed opposite to the middle of the condenser 31 and the intermediate electrode plate 23. By adopting the above structure, the condenser 31 can be better protected under the shielding of the support 1, avoiding direct discharge of the first high voltage electrode 21 to the condenser 31, and the condenser 31 and / or the intermediate electrode plate 23 are in close contact with the top wall of the support 1 and are in contact with the outside air through the vent hole 101, so that the condensate produced by the condenser 31 will be surrounded and accumulated in the vent hole 101 and fall onto the upper surface of the intermediate electrode plate 23.

[0054] like Figure 2 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the top wall of the condenser 31 is recessed to form a through groove 301 opposite to the vent hole 101, the through groove 301 extends horizontally, and the intermediate electrode plate 23 is adapted to be inserted into the through groove 301. By providing a through groove 301 on the top wall of the condenser 31 for adaptation and installation with the intermediate electrode plate 23, on the one hand, it can form a positioning function, which facilitates the quick connection between the intermediate electrode plate 23 and the condenser 31; on the other hand, it makes it easier to make the height of the top wall of the intermediate electrode plate 23 less than or equal to the top wall of the condenser 31, so that the condensate accumulated in the vent hole 101 can more easily fall onto the upper surface of the intermediate electrode plate 23 and migrate, which is beneficial to improving the water ion generation efficiency.

[0055] like Figures 3 to 6 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the side wall of the vent 101 near the first end 231 of the intermediate electrode plate 23 is provided with a first notch 102 communicating with the outside, so as to allow the condensate water accumulated in the vent 101 to pass through and move along the intermediate electrode plate 23 to the first end 231 of the intermediate electrode plate 23. When the intermediate electrode plate 23 is arranged to pass through the vent 101, the first notch 102 facilitates the outflow of condensate water, which then migrates directionally along the intermediate electrode plate 23 to the first end 231 of the intermediate electrode plate 23 under the action of the electromagnetic field formed by the first high-voltage electrode 21 and the second high-voltage electrode 22.

[0056] like Figures 3 to 6As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the side wall of the vent 101 near the second end 232 of the intermediate electrode plate 23 is provided with a second notch 103 communicating with the outside, so as to allow condensate on the second end 232 of the intermediate electrode plate 23 to pass through and enter the vent 101. By adopting the above structure, a small amount of condensate at the second end 232 of the intermediate electrode plate 23 will pass through the second notch 103 and enter the vent 101 under the action of the electromagnetic field, and further migrate through the first notch 102 to the first end 231 of the intermediate electrode plate 23. This allows the air at the second end 232 to remain dry, effectively ensuring that negative ions can be stably generated, and the generated negative ions can also be quickly guided to the first end 231 to mix with water ions and be output under the action of the electromagnetic field.

[0057] like Figures 1 to 3 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the bracket 1 includes a base plate 11 and a mounting platform 12. The mounting platform 12 protrudes from the base plate 11. The first high-voltage electrode 21 and the second high-voltage electrode 22 are respectively disposed on opposite outer sides of the mounting platform 12. The intermediate electrode plate 23 is located on the mounting platform 12. The mounting platform 12 is provided with a mounting groove 104. The condenser 31 is located in the mounting groove 104 and abuts against its bottom wall. The bottom wall of the mounting groove 104 is provided with a vent hole 101. By adopting the above structure, the condenser 31 is disposed in the mounting groove 104 of the mounting platform 12 and abuts against the intermediate electrode plate 23, which can effectively block the first high-voltage electrode 21 and the second high-voltage electrode 22 located on the outer side of the mounting platform 12. Furthermore, the protrusion can be used to facilitate positioning and cooperation with each component, so that when each component is installed on the protrusion in a preset position, each component can automatically correspond.

[0058] like Figure 2 and Figure 5 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the bottom wall of the mounting groove 104 protrudes to form a limiting ring 13, the limiting ring 13 forms a mounting hole 105 opposite to the vent hole 101, and the condenser 31 is adapted to be disposed in the mounting hole 105.

[0059] like Figure 1 and Figure 2 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the outer wall of the base plate 11 or the mounting platform 12 is provided with a first positioning post 14, and the first high voltage electrode 21 is formed with a first positioning hole 201 adapted to be installed with the first positioning post 14.

[0060] like Figure 1 and Figure 2As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the outer wall of the base plate 11 or the mounting platform 12 is provided with a second positioning post 15, and the second high voltage electrode 22 is formed with a second positioning hole 202 adapted to be installed with the second positioning post 15.

[0061] like Figures 2 to 6 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: a first mounting channel 106 is provided on the side of the bracket 1 near the first high-voltage electrode 21, one end of the first mounting channel 106 is connected to the vent 101, and the other end of the first mounting channel 106 is provided with a first opening 107. The first end 231 of the intermediate electrode plate 23 passes through the first mounting channel 106 and extends out through the first opening 107 to approach the first high-voltage electrode 21. The first mounting channel 106 provides a positioning support, ensuring that after the intermediate electrode plate 23 is inserted into the first mounting channel 106, its first end 231 can automatically align with the first high-voltage electrode 21 and be securely installed.

[0062] like Figure 5 and Figure 6 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the mounting platform 12 is provided with a first mounting channel 106 and a first opening 107.

[0063] like Figure 6 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the first installation channel 106 is connected to the vent hole 101 via the first notch 102.

[0064] like Figure 3 and Figure 6 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the intermediate electrode plate 23 and the inner wall of the first mounting channel 106 enclose a first liquid passage 203, and the vent 101, the first liquid passage 203, and the first opening 107 are sequentially connected. Through the formation of the first liquid passage 203, the condensate moving on the upper surface of the intermediate electrode plate 23 can be better surrounded and guided, ensuring that the condensate can move more accurately and quickly along the first liquid passage 203 to the first end 231 of the intermediate electrode plate 23.

[0065] like Figure 2 , Figure 5 and Figure 6 As shown, in addition to the features of the above embodiments, this embodiment further specifies that at least a portion of the first mounting channel 106 is formed by a recess in the bottom wall of the mounting groove 104. This allows the intermediate electrode plate 23 to more easily mate with the inner wall of the first mounting channel 106 to form the first liquid passage 203. Furthermore, the first liquid passage 203 communicates with the vent hole 101 through the first notch 102.

[0066] like Figure 2 and Figure 4 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the diameter and length of the first opening 107 gradually decrease towards the first high-voltage electrode 21, and the first end 231 of the intermediate electrode plate 23 is adapted to be installed with the first opening 107. By adopting the above structure, the first opening 107 can limit the first end 231 of the intermediate electrode plate 23, so that the intermediate electrode plate 23 can be accurately and quickly installed in a preset position, and the first end 231 of the intermediate electrode plate 23 can maintain an effective distance from the first high-voltage electrode 21.

[0067] like Figure 2 and Figure 3 As shown, in addition to the features of the above embodiments, this embodiment further specifies that the first end 231 of the intermediate electrode plate 23 is triangular or conical.

[0068] like Figure 5 and Figure 6 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: a second mounting channel 108 is provided on the side of the bracket 1 near the second high-voltage electrode 22, one end of the second mounting channel 108 is connected to the vent 101, and the other end of the second mounting channel 108 is provided with a second opening 109. The second end 232 of the intermediate electrode plate 23 passes through the second mounting channel 108 and extends out through the second opening 109 to approach the second high-voltage electrode 22. The provision of the second mounting channel 108 can further enhance the positioning and support of the intermediate electrode plate 23, ensuring that after the intermediate electrode plate 23 is inserted into the second mounting channel 108, its second end 232 can automatically align with the second high-voltage electrode 22 and be securely installed.

[0069] like Figure 5 and Figure 6 As shown, in addition to the features of the above embodiments, this embodiment further specifies that the second mounting channel 108 is coaxially arranged with the first mounting channel 106.

[0070] like Figures 2 to 6 As shown, in addition to the features of the above embodiments, this embodiment further defines that: the intermediate electrode plate 23 and the inner wall of the second mounting channel 108 enclose a second liquid passage 204, and the second liquid passage 204, the vent hole 101, the first notch 102 and the first liquid passage 203 are sequentially connected.

[0071] like Figure 2 , Figure 5 and Figure 6As shown, in addition to the features of the above embodiments, this embodiment further specifies that at least a portion of the second mounting channel 108 is formed by a recess in the bottom wall of the mounting groove 104. This allows the intermediate electrode plate 23 to more easily mate with the inner wall of the second mounting channel 108 to form the second liquid passage 204. Furthermore, the second liquid passage 204 communicates with the vent hole 101 through the second notch 103.

[0072] like Figure 5 and Figure 6 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the mounting platform 12 is provided with a second mounting channel 108 and a second opening 109.

[0073] like Figure 2 and Figure 3 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the refrigeration assembly 3 also includes a heat sink 33, the Peltier 32 has opposing heat dissipation end and refrigeration end, the refrigeration end of the Peltier 32 abuts against the condenser 31, and the heat dissipation end of the Peltier 32 abuts against the heat sink 33. Through the arrangement of the heat sink 33, the heat generated at the heat dissipation end of the Peltier 32 can be dissipated to maintain and improve the refrigeration effect of the refrigeration end.

[0074] like Figure 3 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the bracket 1 is disposed above the heat sink 33, and the bracket 1 and the heat sink 33 enclose a mounting cavity, in which the condenser 31 and the Peltier 32 are disposed. Through the cooperation of the bracket 1 and the heat sink 33, the heat sink 33 not only dissipates heat but also provides support and protection for the condenser 31 and the Peltier 32. The mounting cavity formed by the two can isolate external moisture, ensuring that the Peltier 32 can work stably.

[0075] like Figure 2 and Figure 5 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the heat sink 33 is disposed on the side of the base plate 11 away from the mounting platform 12, and surrounds the inner wall of the mounting groove 104 to form a mounting cavity.

[0076] like Figure 2 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the bracket 1 is provided with a first connecting hole 110, the heat sink 33 is provided with a second connecting hole 302, and the first connecting hole 110 and the second connecting hole 302 are connected by fastener 4 to connect the bracket 1 and the heat sink 33.

[0077] In addition to the features of the above embodiments, this embodiment further specifies that: the first high-voltage electrode 21 and the second high-voltage electrode 22 are electrically connected to the positive and negative terminals of the high-voltage power supply, respectively. The condensed water on the intermediate electrode plate 23, after being polarized in the electromagnetic field formed by the first high-voltage electrode 21 and the second high-voltage electrode 22, carries a negative charge. Under the action of the electric field force, it will migrate towards the first end 231 of the intermediate electrode plate 23, which carries a positive charge, to be further ionized to generate water ions.

[0078] like Figure 2 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the first high-voltage electrode 21 includes an annular body 211 and a connecting portion 212. The annular body 211 is connected to the support 1 through the connecting portion 212. A high-voltage discharge is formed between the annular body 211 and the first end 231 of the intermediate electrode plate 23 to ionize the condensed water on the first end 231 to generate water ions. By adopting the above structure, the annular body 211 can be aligned and fixed with the first end 231 of the intermediate electrode plate 23 after being connected and engaged with the support 1 through the connecting portion 212. At the same time, the annular structure provides a more uniform high-voltage electric field. Furthermore, the first end 231 of the intermediate electrode plate 23 is coaxially arranged with the annular body 211.

[0079] A second aspect of this application provides an electronic device.

[0080] This embodiment discloses an electronic device, including the ion generating module described above.

[0081] The technical features of the above embodiments can be combined in any way. For the sake of brevity, not all possible combinations of the technical features in the above embodiments are described. However, as long as there is no contradiction in the combination of these technical features, they should be considered to be within the scope of this specification.

[0082] The embodiments described above are merely illustrative of several implementations of this utility model, and while the descriptions are relatively specific and detailed, they should not be construed as limiting the scope of the utility model patent. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of this utility model, and these all fall within the protection scope of this utility model. Therefore, the protection scope of this utility model patent should be determined by the appended claims.

Claims

1. An ion generation module, characterized by, include: Support (1); Electrode assembly (2), the electrode assembly (2) includes a first high voltage electrode (21), a second high voltage electrode (22) and an intermediate electrode plate (23). The first high voltage electrode (21) and the second high voltage electrode (22) are respectively disposed on both sides of the bracket (1). The intermediate electrode plate (23) is located between the first high voltage electrode (21) and the second high voltage electrode (22). The intermediate electrode plate (23) has a first end (231) and a second end (232) opposite to each other. The first end (231) of the intermediate electrode plate (23) is close to the first high voltage electrode (21), and the second end (232) of the intermediate electrode plate (23) is close to the second high voltage electrode (22). A refrigeration component (3) is in contact with the intermediate electrode plate (23) to condense moisture in the air onto the intermediate electrode plate (23) to form condensate. A high-voltage power supply is provided, with its two ends connected to the first high-voltage electrode (21) and the second high-voltage electrode (22) respectively, and high voltage is applied to drive the condensed water to move along the intermediate electrode plate (23) to the first end (231) under the action of the electromagnetic field formed by the first high-voltage electrode (21) and the second high-voltage electrode (22). A high-voltage discharge is formed between the first end (231) and the first high-voltage electrode (21) to ionize the condensed water on the first end (231) and generate water ions. A high-voltage discharge is formed between the second end (232) and the second high-voltage electrode (22) to ionize the air and generate negative ions.

2. The ion generation module of claim 1, wherein, The refrigeration component (3) includes a condenser (31) and a Peltier (32). The Peltier (32) is used to refrigerate the condenser (31). The intermediate electrode plate (23) is disposed on the side of the condenser (31) away from the Peltier (32). The condenser (31) is used to condense moisture in the air onto the intermediate electrode plate (23) to form condensate.

3. The ion generation module of claim 2, wherein, The condenser (31) is disposed in the bracket (1). The inner side of the top wall of the bracket (1) is in close contact with the top wall of the condenser (31) and / or the intermediate electrode plate (23) and is provided with a vent (101) that connects to the outside. The vent (101) is disposed opposite to the middle of the condenser (31) and the intermediate electrode plate (23).

4. The ion generating module according to claim 3, characterized in that, The top wall of the condenser (31) is recessed to form a through groove (301) opposite to the vent (101), the through groove (301) extends horizontally, and the intermediate electrode plate (23) is adapted to be inserted into the through groove (301); and / or The vent (101) has a first notch (102) on the side wall near the first end (231) of the intermediate electrode plate (23) to communicate with the outside, so as to allow condensate water accumulated in the vent (101) to pass through and move along the intermediate electrode plate (23) to the first end (231) of the intermediate electrode plate (23); and / or The vent (101) has a second notch (103) on the side wall near the second end (232) of the intermediate electrode plate (23) to allow condensate on the second end (232) of the intermediate electrode plate (23) to pass through and enter the vent (101); and / or The bracket (1) includes a base plate (11) and a mounting platform (12). The mounting platform (12) is protruding from the base plate (11). The first high-voltage electrode (21) and the second high-voltage electrode (22) are respectively disposed on the two opposite outer sides of the mounting platform (12). The intermediate electrode plate (23) is located on the mounting platform (12). The mounting platform (12) is provided with a mounting groove (104). The condenser (31) is located in the mounting groove (104) and abuts against its bottom wall. The bottom wall of the mounting groove (104) is provided with the vent hole (101).

5. The ion generating module according to claim 3, characterized in that, The bracket (1) has a first mounting channel (106) on the side near the first high voltage electrode (21). One end of the first mounting channel (106) is connected to the vent (101), and the other end of the first mounting channel (106) has a first opening (107). The first end (231) of the intermediate electrode plate (23) passes through the first mounting channel (106) and extends through the first opening (107) to approach the first high voltage electrode (21).

6. The ion generating module according to claim 5, characterized in that, The intermediate electrode plate (23) and the inner wall of the first mounting channel (106) enclose a first liquid passage (203), and the vent (101), the first liquid passage (203), and the first opening (107) are sequentially connected; and / or The diameter of the first opening (107) gradually decreases towards the first high-voltage electrode (21), and the first end (231) of the intermediate electrode plate (23) is adapted to be installed with the first opening (107); and / or The bracket (1) has a second mounting channel (108) on the side near the second high voltage electrode (22). One end of the second mounting channel (108) is connected to the vent (101), and the other end of the second mounting channel (108) has a second opening (109). The second end (232) of the intermediate electrode plate (23) passes through the second mounting channel (108) and extends through the second opening (109) to approach the second high voltage electrode (22).

7. The ion generating module according to claim 2, characterized in that, The refrigeration component (3) further includes a heat sink (33), and the Peltier (32) has a heat sink end and a refrigeration end opposite to each other. The refrigeration end of the Peltier (32) abuts against the condenser (31), and the heat sink end of the Peltier (32) abuts against the heat sink (33).

8. The ion generating module according to claim 7, characterized in that, The bracket (1) is disposed above the heat sink (33), and the bracket (1) and the heat sink (33) enclose a mounting cavity, in which the condenser (31) and the Peltier (32) are disposed; and / or The bracket (1) is provided with a first connection hole (110), and the heat sink (33) is provided with a second connection hole (302). The first connection hole (110) and the second connection hole (302) are connected by fasteners (4).

9. The ion generating module according to any one of claims 1 to 8, characterized in that, The first high-voltage electrode (21) and the second high-voltage electrode (22) are electrically connected to the positive and negative terminals of the high-voltage power supply, respectively; and / or The first high-voltage electrode (21) includes an annular body (211) and a connecting part (212). The annular body (211) is connected to the bracket (1) through the connecting part (212). A high-voltage discharge is formed between the annular body (211) and the first end (231) of the intermediate electrode plate (23) to ionize the condensed water on the first end (231) to generate water ions.

10. An electronic device, characterized in that, Includes the ion generating module as described in any one of claims 1 to 9.