An odor eliminator

By designing a deodorizer with multiple ozone generators and adopting a linkage control structure, the inconvenience and safety hazards of using multi-zone deodorizers have been solved, and simple and safe multi-zone deodorization operation has been achieved.

CN224470392UActive Publication Date: 2026-07-07

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Filing Date
2025-06-12
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing deodorizers are difficult to meet the needs of deodorizing multiple areas at the same time. They are inconvenient to use and pose safety hazards. For example, they need to be moved multiple times or multiple deodorizers need to be purchased. Manual operation is also prone to safety problems.

Method used

Design an odor deodorizer that includes multiple ozone generators. The deodorizer automatically switches between charging and operating states through a connection or disconnection structure. It adopts a magnetic, rotary, hinge, or sliding connection structure, combined with an electronic control structure to achieve linkage control, ensuring that the ozone generator stops working and charges when connected, and starts working when disconnected.

Benefits of technology

It enables simple operation to simultaneously deodorize multiple areas, reduces user costs, improves ease of use and safety, and avoids safety hazards such as ozone leakage and spontaneous combustion.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

The utility model provides an odor remover, including two or more than two and can be mutually connected or mutually separate arrangement's ozone generator, the connecting structure for the connection or separation between each ozone generator, the energy supplement structure for the electric connection between each ozone generator and the connection of external power supply, and the electric control structure for controlling the opening and closing of each ozone generator, the utility model provides an odor remover, it has a plurality of ozone generators, through the connection or separation between each ozone generator, automatic switching energy supplement state and working state, has improved the use safety and the convenience of odor remover.
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Description

Technical Field

[0001] This utility model belongs to the technical field of air purification equipment, specifically relating to an odor remover. Background Technology

[0002] As people's living standards continue to improve, they are paying more and more attention to their living environment, especially spaces such as car interiors, shoe cabinets, wardrobes, bathrooms, and refrigerators. These spaces are characterized by poor ventilation and poor air circulation, which can produce odors during use. Odor removers, as a common air purification device, remove odors by generating ozone to decompose odor molecules, and are loved and valued by users.

[0003] Some deodorizers use a single main structure. The problem is that deodorizers with this structure cannot meet the needs of deodorizing multiple areas at the same time (such as the trunk and driver's cabin of a car, or the bedroom and the bathroom). In order to meet the deodorization needs of multiple areas, users need to move the deodorizer multiple times, which makes the deodorization operation very cumbersome. Alternatively, users need to purchase multiple deodorizers, which increases the user's living costs and affects the user's experience of using the deodorizer.

[0004] Alternatively, some deodorizers use a multi-unit structure. The problem is that in these structures, each unit has an independent on / off switch, requiring manual operation by the user to turn each unit on or off. This makes the deodorizer inconvenient to use. During manual operation, users may forget to turn off a unit, causing it to continue working while connected to a charger, potentially leading to ozone leakage. Furthermore, having multiple units connected to a charger while working can cause overheating, spontaneous combustion, short circuits, and other safety issues, posing a safety hazard to the deodorizer.

[0005] Therefore, further improvements are needed. Utility Model Content

[0006] The purpose of this utility model is to overcome at least one of the shortcomings of the prior art and to provide a deodorizer with multiple ozone generators. By connecting or separating the ozone generators, the deodorizer can automatically switch between the power replenishment state and the working state, thereby improving the safety and convenience of using the deodorizer.

[0007] To achieve the above objectives, the technical solution provided by this utility model embodiment is as follows:

[0008] An odor deodorizer includes two or more ozone generators that can be connected or separated from each other, a connection structure for connecting or separating the ozone generators, a power supply structure for electrically connecting the ozone generators and connecting them to an external power source for power replenishment, and an electrical control structure for controlling the opening and closing of the ozone generators.

[0009] When the ozone generators are connected, each ozone generator is turned off and stops working, and the ozone generators are powered on and connected to an external power source for recharging; when the ozone generators are separated, the ozone generators are powered off and the external power source is disconnected to stop recharging, and each ozone generator is started and begins working.

[0010] There are two ozone generators, and when the two ozone generators are connected, the connection end faces of the two ozone generators abut against each other.

[0011] The connection structure is a magnetic connection structure, which includes a first magnetic component disposed on the connection end face of one of the ozone generators and a second magnetic component disposed on the connection end face of the other ozone generator. The first magnetic component is disposed corresponding to the second magnetic component. When the first magnetic component and the second magnetic component attract each other, the two ozone generators are connected.

[0012] Alternatively, the connection structure is a snap-fit ​​connection structure, which includes a first screw-fit part disposed on the outer edge of the connection end face of one of the ozone generators and a second screw-fit part disposed on the outer edge of the connection end face of the other ozone generator. The first screw-fit part is disposed corresponding to the second screw-fit part. When the first screw-fit part and the second screw-fit part are screwed together, the two ozone generators are connected.

[0013] Alternatively, the connection structure is a hinge-locking connection structure, which includes a first hinge component and a first locking component disposed opposite to each other on both sides of the connection end face of one of the ozone generators, and a second hinge component and a second locking component disposed opposite to each other on both sides of the connection end face of the other ozone generator. The first hinge component is disposed corresponding to the second hinge component and the two are hinged to each other. The first locking component is disposed corresponding to the second locking component. When the first hinge component rotates relative to the second hinge component and the first locking component and the second locking component are locked to each other, the two ozone generators are connected.

[0014] Alternatively, the connection structure is a sliding groove connection structure, which includes a first groove portion disposed on the connection end face of one of the ozone generators and a second groove portion disposed on the connection end face of the other ozone generator. The first groove portion is disposed corresponding to the second groove portion. When the first groove portion is inserted from the beginning of the second groove portion and slides along the end of the second groove portion, the two ozone generators are connected.

[0015] The first magnetic attraction component and the second magnetic attraction component are both multiple and are evenly arranged in a circumferential direction. At least one first magnetic attraction component is set as the reverse pole and at least one second magnetic attraction component is set as the positive pole. Each first magnetic attraction component and each second magnetic attraction component correspond to each other. When the first magnetic attraction component of the reverse pole corresponds to the second magnetic attraction component of the positive pole, the two ozone generators are positioned and connected to each other.

[0016] Alternatively, there may be several first magnetic components and second magnetic components arranged unequally in the circumferential direction, with each first magnetic component corresponding to each second magnetic component, so that the two ozone generators are mutually positioned and connected.

[0017] The energy replenishment structure includes a charging component disposed on any ozone generator and connected to an external power source, a first energy replenishment electrode component disposed on one of the ozone generators, and a second energy replenishment electrode component disposed on the other ozone generator. The first energy replenishment electrode component and the second energy replenishment electrode component are disposed correspondingly. The first energy replenishment electrode component or the second energy replenishment electrode component is electrically connected to the charging component. When the two ozone generators are connected, the first energy replenishment electrode component and the second energy replenishment electrode component are electrically connected, and the external power source is electrically connected to the charging component, so that the two ozone generators are energized and connected to the external power source for energy replenishment.

[0018] The deodorizer also includes a positioning structure, which includes a positioning protrusion disposed on the connection end face of one of the ozone generators and a positioning recess disposed on the connection end face of the other ozone generator and corresponding to the positioning protrusion. A first energy replenishing electrode component is disposed on the positioning protrusion and a second energy replenishing electrode component is disposed on the positioning recess. When the two ozone generators are connected, the positioning protrusion extends into the positioning recess, so that the first energy replenishing electrode component is aligned with the second energy replenishing electrode component.

[0019] The electrical control structure is a contact electrical control structure, which includes a first control electrode component disposed on one of the ozone generators and a second control electrode component disposed on the other ozone generator. The first control electrode component is disposed corresponding to the second control electrode component. When the first control electrode component and the second control electrode component are electrically connected, the ozone generator is turned off and stops working.

[0020] Alternatively, the electronic control structure is a reed switch electronic control structure, which includes a reed switch component disposed on one of the ozone generators and a magnetic component disposed on the other ozone generator. The reed switch component and the magnetic component are disposed correspondingly. When the reed switch component senses the magnetic field of the magnetic component, it causes the ozone generator to turn off and stop working.

[0021] Alternatively, the electronic control structure is a Hall sensor electronic control structure, which includes a Hall element component disposed on one of the ozone generators and a magnetic component disposed on the other ozone generator. The Hall element component and the magnetic component are disposed correspondingly. When the Hall element component senses the magnetic field of the magnetic component, it causes the ozone generator to turn off and stop working.

[0022] Alternatively, the electronic control structure is a micro switch electronic control structure, which includes a micro switch disposed on the ozone generator. The micro switch of one ozone generator acts on the connection end face of the other ozone generator and opens it, so that the ozone generator is turned off and stops working.

[0023] Alternatively, the electronic control structure is an electromagnetic induction electronic control structure, which includes an electromagnetic transmitting component disposed on one of the ozone generators and an electromagnetic receiving component disposed on the other ozone generator. The electromagnetic transmitting component and the electromagnetic receiving component are disposed correspondingly. When the two ozone generators are connected, the electromagnetic receiving component receives the magnetic field of the electromagnetic transmitting component, causing the two ozone generators to turn off and stop working.

[0024] Alternatively, the electronic control structure is an infrared sensing electronic control structure, which includes an infrared emitting component disposed on one of the ozone generators and an infrared receiving component disposed on the other ozone generator. The infrared emitting component and the infrared receiving component are disposed correspondingly. When the two ozone generators are connected, the infrared receiving component receives the infrared signal from the infrared emitting component, causing the two ozone generators to turn off and stop working.

[0025] Alternatively, the electronic control structure is a radar sensing electronic control structure, which includes a microwave transmitting component disposed on one of the ozone generators and a microwave receiving component disposed on the other ozone generator. The microwave transmitting component and the microwave receiving component are disposed correspondingly. When the two ozone generators are connected, the microwave receiving component receives the microwave signal from the microwave transmitting component, causing the two ozone generators to turn off and stop working.

[0026] Alternatively, the electronic control structure is a photoelectric sensing electronic control structure, which includes a photoelectric emitting component disposed on one of the ozone generators and a photoelectric receiving component disposed on the other ozone generator. The photoelectric emitting component and the photoelectric receiving component are disposed correspondingly. When the two ozone generators are connected, the photoelectric receiving component receives the photoelectric signal from the photoelectric emitting component, causing the two ozone generators to turn off and stop working.

[0027] The ozone generator includes a housing, a cover, and an ozone generating mechanism. The housing has a cavity and an opening communicating with the cavity. The ozone generating mechanism includes a support frame, a high-voltage module, a power module, a control board module, and a discharge module, all housed within the cavity. The cover is fitted onto the opening. The support frame is located within the cavity. The high-voltage module, power module, and discharge module are electrically connected to the control board module. The energy replenishment structure and the electrical control structure are located between the covers of the two ozone generators and are electrically connected to the control board modules of the two ozone generators.

[0028] The high-voltage module, power module, control board module and discharge module are all mounted on the mechanism support. The housing is also provided with a charging opening, which is located on the side wall of the housing. The power receiving end of the energy replenishment structure extends out of the housing through the charging opening.

[0029] Alternatively, the control board module is mounted on the cover, and the high voltage module, power module, and discharge module are all mounted on the mechanism support. The housing is also provided with a charging slot, which is located on the opening of the housing. The power receiving end of the energy replenishment structure extends out of the housing through the charging slot.

[0030] When the mechanism support is set inside the shell cavity, the mechanism support divides the shell cavity into an electrical cavity, an air inlet cavity, and an air outlet cavity. The electrical cavity and the air inlet cavity are located on the left and right sides of the air outlet cavity, respectively. The high voltage module, the power supply module, and the control board module are located inside the electrical cavity, and the discharge module is located inside the air outlet cavity. The cover is provided with an air inlet that connects to the air inlet cavity and an air outlet that connects to the air outlet cavity.

[0031] The ozone generating mechanism also includes a fan module, which is mounted on the mechanism support and located at the air inlet of the air outlet cavity. The fan module is electrically connected to the control board module.

[0032] The ozone generating mechanism also includes an indicator light module, which is mounted on the control board module. The indicator light module emits red and / or green and / or blue light.

[0033] The deodorizer also includes a connecting rope, the two ends of which are respectively connected to the housings of the two ozone generators. The connecting rope is made of flexible material and has wires inside. The two ends of the wires are respectively connected to the control board module wires of the two ozone generators.

[0034] The beneficial effects of this utility model are as follows:

[0035] This utility model, through the deodorizer using the above-mentioned technical solution, has multiple ozone generators. It can meet the deodorization needs of multiple areas simultaneously without the need to move the deodorizer multiple times or purchase multiple deodorizers. The deodorization operation of different areas is simple for users, reduces the user's living costs, and improves the user experience.

[0036] The deodorizer employing the above-mentioned technical solution has a connection structure, a power replenishment structure, and an electrical control structure between each ozone generator. The connection mechanism, power replenishment structure, and electrical control structure of each ozone generator adopt a linkage control mechanism. When each ozone generator is connected, each ozone generator is turned off and stops working, and each ozone generator is powered on and connected to an external power source for charging and power replenishment. When each ozone generator is separated, each ozone generator starts and begins working, and the power between each ozone generator is turned off and the external power source is disconnected to stop power replenishment. Therefore, the start-up and shutdown process of each ozone generator does not require manual intervention from the user, improving the ease of use of the deodorizer.

[0037] By adopting the above-mentioned technical solution, the deodorizer uses a linkage control mechanism with the connection mechanism, energy replenishment structure, and electrical control structure of each ozone generator. This means that when connected, the ozone generator stops working and is powered on, and when disconnected, it starts working and is powered off. No manual operation is required. This avoids the ozone generators from continuing to work and produce ozone when connected, and avoids the safety problems of continuing to replenish energy and causing spontaneous combustion or short circuits when disconnected. This improves the safety of the deodorizer. Attached Figure Description

[0038] Figure 1 This is a schematic diagram of the deodorizer according to the first embodiment of this utility model.

[0039] Figure 2 This is an exploded view of the deodorizer according to the first embodiment of this utility model.

[0040] Figure 3 This is an exploded view of one of the ozone generators in the first embodiment of this utility model.

[0041] Figure 4 This is an exploded view of another ozone generator according to the first embodiment of this utility model.

[0042] Figure 5 This is a cross-sectional view of the ozone generator according to the first embodiment of this utility model.

[0043] Figure 6 This is an exploded view of the ozone generating mechanism according to the first embodiment of this utility model.

[0044] Figure 7 This is a schematic diagram of the airflow in the ozone generator according to the first embodiment of this utility model.

[0045] Figure 8 This is a circuit diagram of the deodorizer according to the first embodiment of this utility model.

[0046] Figure 9 This is an exploded view of one of the ozone generators in the second embodiment of this utility model.

[0047] Figure 10This is an exploded view of another ozone generator according to the second embodiment of this utility model.

[0048] Figure 11 This is an exploded view of the control board module and the cover of the second embodiment of this utility model. Detailed Implementation

[0049] To make the objectives, technical solutions, and advantages of the embodiments 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 some embodiments of this utility model, but not all embodiments.

[0050] First embodiment:

[0051] See Figure 1-8 In this embodiment, the deodorizer is lemon-shaped, but different shapes can be designed according to market demand. The deodorizer includes two ozone generators 1, a connecting structure, a power supply structure, and an electrical control structure. The connecting structure, power supply structure, and electrical control structure are located between the two ozone generators 1. The connecting structure allows the two ozone generators 1 to be connected or separated. The power supply structure electrically connects the two ozone generators 1 and allows them to be powered by an external power source. The electrical control structure controls the opening and closing of the two ozone generators 1. The two ozone generators 1 can meet the simultaneous deodorization needs of different areas without the need to move the deodorizer multiple times or purchase multiple deodorizers. The deodorization operation is simple, reduces user living costs, and improves the user experience. The connecting mechanism of the two ozone generators 1, the power supply structure, and the electrical control structure adopt a linkage control mechanism. When the two ozone generators 1 are connected, the two ozone generators 1 are turned off and... The system stops working, and the two ozone generators 1 are energized and connected to an external power source for charging. When the two ozone generators 1 are separated, they start working and disconnect from the external power source to stop charging. After working for a period of time, the two ozone generators 1 automatically shut down and stop working. This prevents the deodorizer from working for a long time due to accidental separation of the two ozone generators 1, thus extending the deodorizer's lifespan. Therefore, the start-up and shutdown process of the two ozone generators 1 does not require manual intervention from the user, improving the ease of use of the deodorizer. Moreover, the two ozone generators 1 of this deodorizer stop working and are energized when connected, and start working and are de-energized when separated, without the need for manual operation. This avoids the ozone generators 1 continuing to work and generate ozone when connected, and avoids the safety problems of spontaneous combustion and short circuits caused by the ozone generators 1 continuing to charge when separated, thus improving the safety of the deodorizer.

[0052] Furthermore, in this embodiment, the connection structure is preferably a magnetic connection structure. Specifically, the magnetic connection structure includes a first magnetic component 101 and a second magnetic component 102. The first magnetic component 101 is preferably a magnet and is disposed on the connection end face of one of the ozone generators 1. The number of the first magnetic component 101 is preferably three and they are evenly arranged in a circumferential direction. One of the first magnetic components 101 is set as a reverse magnet. The second magnetic component 102 is preferably a magnet and is disposed on the connection end face of the other ozone generator 1. The number of the second magnetic component 102 is preferably three and they are evenly arranged in a circumferential direction. One of the second magnetic components 102 is set as a positive magnet. Each first magnetic component 101 is set corresponding to each second magnetic component 102. When the connection end faces of the two ozone generators 1 are close, each first magnetic component 101 and each second magnetic component 102 correspond to each other and attract each other. The reverse first magnetic component 101 and the positive second magnetic component 102 make the two ozone generators 1 mutually positioned and connected.

[0053] Alternatively, the number of first magnetic components 101 is preferably three, arranged circumferentially unevenly, and the number of second magnetic components 102 is preferably three, also arranged circumferentially unevenly. Specifically, the included angle between two adjacent first magnetic components 101 and the included angle between two adjacent second magnetic components 102 are not the same. When the connecting end faces of the two ozone generators 1 are close to each other, and each first magnetic component 101 and each second magnetic component 102 correspond one-to-one, the two ozone generators 1 are positioned and connected to each other.

[0054] Through the above technical solutions, the magnetic connection structure enables the two ozone generators 1 to be quickly adsorbed, and the two ozone generators 1 can be quickly connected or separated, as can be understood by those skilled in the art.

[0055] Alternatively, the connection structure can also be a screw-on connection structure. Specifically, the screw-on connection structure includes a first screw-on part and a second screw-on part. The first screw-on part is preferably internally threaded and disposed on the outer edge of the connection end face of one of the ozone generators 1. The second screw-on part is preferably externally threaded and disposed on the outer edge of the connection end face of the other ozone generator 1. The first screw-on part is disposed corresponding to the second screw-on part. When the connection end faces of the two ozone generators 1 are close together, the first screw-on part and the second screw-on part screw on each other to connect the two ozone generators 1. The screw-on connection structure adopts a mechanical locking structure, which enhances the structural stability of the connection structure, as can be understood by those skilled in the art.

[0056] Alternatively, the connection structure can also be a hinge-locking connection structure. Specifically, the hinge-locking connection structure includes a first hinge component, a first locking component, a second hinge component, and a second locking component. The first hinge component and the first locking component are disposed opposite to each other on the outer edge of the connection end face of one of the ozone generators 1, and the second hinge component and the second locking component are disposed opposite to each other on the outer edge of the connection end face of the other ozone generator 1. The first hinge component is disposed corresponding to the second hinge component, and the two are hinged together by a pivot. The first locking component is disposed corresponding to the second locking component. When the first hinge component rotates relative to the second hinge component, the connection end faces of the two ozone generators 1 are brought closer, and the first locking component and the second locking component are locked together, thus connecting the two ozone generators 1. The hinge-locking connection structure enables the opening and closing angle of the two ozone generators 1 to be adjusted, allowing the deodorizer to be placed in a confined space. This is understandable to those skilled in the art.

[0057] Alternatively, the connection structure can also be a grooving connection structure. Specifically, the grooving connection structure includes a first groove and a second groove. The first groove includes two L-shaped slide rails that are disposed opposite each other on the connection end face of one of the ozone generators 1. The second groove includes two 7-shaped slide rails that are disposed opposite each other on the connection end face of the other ozone generator 1. The first groove is disposed corresponding to the second groove. When the connection end faces of the two ozone generators 1 are close together, the first groove is inserted from the first end of the second groove and slides along the end direction of the second groove, thereby connecting the two ozone generators 1. The grooving connection structure guides the two ozone generators 1 to slide linearly in the radial direction, avoiding radial errors of the two ozone generators 1 and ensuring the electrode docking accuracy of the two ozone generators 1. This is understood by those skilled in the art.

[0058] Further, in this embodiment, the energy replenishment structure includes a charging component 103, a first energy replenishment electrode component 104, and a second energy replenishment electrode component 105. Specifically, the charging component 103 is preferably a Type-C charging port and is disposed on any ozone generator 1 and connected to an external power source to provide power to the deodorizer. The first energy replenishment electrode component 104 is preferably an electrode head and is provided with a positive terminal and a negative terminal. The first energy replenishment electrode component 104 is disposed on one of the ozone generators 1 and extends out of its connection end face. The second energy replenishment electrode component 105 is preferably an electrode head and is provided with a positive terminal and a negative terminal. The second energy replenishment electrode component 105 is provided with... The charging component 103 is placed on another ozone generator 1 and extends out of its connection end face. It is electrically connected to the first energy replenishing electrode component 104. When the two ozone generators 1 are connected, the positive terminal of the first energy replenishing electrode component 104 is electrically connected to the positive terminal of the second energy replenishing electrode component 105, and the negative terminal of the first energy replenishing electrode component 104 is electrically connected to the negative terminal of the second energy replenishing electrode component 105. An external power supply is plugged into the charging component 103 and the two are electrically connected, so that the two ozone generators 1 are energized and connected to the external power supply for energy replenishment. The large contact area of ​​the electrode post reduces the contact resistance and improves the charging efficiency, which can be understood by those skilled in the art.

[0059] Furthermore, the deodorizer also includes a positioning structure. Specifically, in this embodiment, the positioning structure includes a positioning protrusion 106 and a positioning recess 107. The positioning protrusion 106 is elliptical and is disposed on the connection end face of one of the ozone generators 1. The positioning recess 107 is elliptical and is disposed on the connection end face of the other ozone generator 1, corresponding to the positioning protrusion 106. A first supplementary electrode component 104 is disposed on the positioning protrusion 106, and a second supplementary electrode component 105 is disposed on the positioning recess 107. When the two ozone generators 1 are connected, the positioning protrusion 106 extends into the positioning recess 107, so that the first supplementary electrode component 104 is aligned with the second supplementary electrode component 105, ensuring that the first supplementary electrode component 104 and the second supplementary electrode component 105 can be accurately connected, ensuring the correct connection of the supplementary structure, which can be understood by those skilled in the art.

[0060] Furthermore, in this embodiment, the electronic control structure is preferably a contact electronic control structure. Specifically, the contact electronic control structure includes a first control electrode component 108 and a second control electrode component 109. The first control electrode component 108 is preferably an electrode head with four electrode posts. The first control electrode component 108 is disposed on one of the ozone generators 1 and extends out of its connection end face. The second control electrode component 109 is preferably an electrode head with four electrode posts. The second control electrode component 109 is disposed on the other ozone generator 1 and extends out of its connection end face. The first control electrode component 108 is disposed corresponding to the second control electrode component 109. When the two ozone generators 1 are connected, the four electrode heads of the first control electrode component 108 are electrically connected to the four electrode heads of the second control electrode component 109, so that the control circuits of the two ozone generators 1 are connected, causing the two ozone generators 1 to turn off and stop working. The contact electronic control structure is triggered by mechanical contact. Its structure is simple, reliable, and low in cost, which can be understood by those skilled in the art.

[0061] Alternatively, the electronic control structure can also be a reed switch electronic control structure. Specifically, the reed switch electronic control structure includes a reed switch component and a magnetic component. The magnetic component is preferably a magnet. Both ozone generators 1 are provided with a reed switch component and a magnetic component. The reed switch component and the magnetic component are staggered on the connection end face of the same ozone generator 1. The reed switch component of one ozone generator 1 is correspondingly set with the magnetic component of the other ozone generator 1. When the two ozone generators 1 are connected, the reed switch component closes its two internal reeds under the magnetic field of the magnetic component, so that the control circuits of the two ozone generators 1 are connected respectively, causing the two ozone generators 1 to turn off and stop working. The reed switch electronic control structure is triggered by magnetic contact, which has no mechanical wear, strong anti-interference ability, and enables the electronic control structure to be quickly connected or disconnected. This is understood by those skilled in the art.

[0062] Alternatively, the electronic control structure can also be a Hall effect sensor electronic control structure. Specifically, the Hall effect sensor electronic control structure includes a Hall element component and a magnetic component. The magnetic component is preferably a magnet. Both ozone generators 1 are provided with Hall element components and magnetic components. The Hall element components and magnetic components are staggered on the connection end face of the same ozone generator 1. The Hall element component of one ozone generator 1 is correspondingly set with the magnetic component of the other ozone generator 1. When the two ozone generators 1 are connected, the Hall element component connects its internal circuit under the magnetic field of the magnetic component, which connects the control circuits of the two ozone generators 1 respectively, causing the two ozone generators 1 to turn off and stop working. The Hall effect sensor electronic control structure is triggered by magnetic contact, which has no mechanical wear, strong anti-interference ability, and enables the electronic control structure to be quickly connected or disconnected. This is understood by those skilled in the art.

[0063] Alternatively, the electronic control structure can also be a micro-switch electronic control structure. Specifically, the micro-switch electronic control structure includes a micro-switch. Both ozone generators 1 are equipped with micro-switches, which are staggered. When the two ozone generators 1 are connected, the micro-switch of one ozone generator 1 acts on the connection end face of the other ozone generator 1 and opens, connecting the control circuits of the two ozone generators 1 and causing the two ozone generators 1 to close and stop working. The micro-switch electronic control structure is triggered by physical compression, making the feedback when the electronic control structure is connected or closed more intuitive and easier for users to understand the working condition of the electronic control structure. This is understandable to those skilled in the art.

[0064] Alternatively, the electronic control structure can also be an electromagnetic induction electronic control structure. Specifically, the electromagnetic induction electronic control structure includes an electromagnetic transmitting component and an electromagnetic receiving component. The electromagnetic transmitting component is preferably a magnet, and the electromagnetic receiving component is preferably a drive coil. Both ozone generators 1 are equipped with electromagnetic transmitting and receiving components. The electromagnetic transmitting and receiving components are staggered and set on the connection end face of the same ozone generator 1. The electromagnetic transmitting component of one ozone generator 1 is correspondingly set with the electromagnetic receiving component of the other ozone generator 1. When the two ozone generators 1 are connected, the electromagnetic receiving component of one ozone generator 1 receives the magnetic field emitted by the electromagnetic transmitting component of the other ozone generator 1, which connects the control circuits of the two ozone generators 1 respectively, causing the two ozone generators 1 to turn off and stop working. The electromagnetic induction electronic control structure is triggered by signal transmission, without mechanical wear, so that the electronic control structure can be quickly connected or disconnected, which can be understood by those skilled in the art.

[0065] Alternatively, the electronic control structure can also be an infrared sensing electronic control structure. Specifically, the infrared sensing electronic control structure includes an infrared emitting component and an infrared receiving component. Both ozone generators 1 are equipped with infrared emitting components and infrared receiving components. The infrared emitting components and infrared receiving components are staggered and arranged on the connection end face of the same ozone generator 1. The infrared emitting component of one ozone generator 1 is correspondingly arranged with the infrared receiving component of the other ozone generator 1. When the two ozone generators 1 are connected, the infrared receiving component of one ozone generator 1 receives the infrared signal emitted by the infrared emitting component of the other ozone generator 1, which connects the control circuits of the two ozone generators 1 respectively, causing the two ozone generators 1 to turn off and stop working. The infrared sensing electronic control structure is triggered by signal transmission, without mechanical wear, so that the electronic control structure can be quickly connected or disconnected, which can be understood by those skilled in the art.

[0066] Alternatively, the electronic control structure can also be a radar-sensing electronic control structure. Specifically, the radar-sensing electronic control structure includes a microwave transmitting component and a microwave receiving component. Both ozone generators 1 are equipped with microwave transmitting components and microwave receiving components. The microwave transmitting components and microwave receiving components are staggered and set on the connection end face of the same ozone generator 1. The microwave transmitting component of one ozone generator 1 is correspondingly set with the microwave receiving component of the other ozone generator 1. When the two ozone generators 1 are connected, the microwave receiving component of one ozone generator 1 receives the microwave signal emitted by the microwave transmitting component of the other ozone generator 1, which connects the control circuits of the two ozone generators 1 respectively, causing the two ozone generators 1 to turn off and stop working. The radar-sensing electronic control structure is triggered by signal transmission, without mechanical wear, so that the electronic control structure can be quickly connected or disconnected, which can be understood by those skilled in the art.

[0067] Alternatively, the electronic control structure can also be a photoelectric sensing electronic control structure. Specifically, the photoelectric sensing electronic control structure includes a photoelectric emitting component and a photoelectric receiving component. Both ozone generators 1 are equipped with photoelectric emitting components and photoelectric receiving components. The photoelectric emitting components and photoelectric receiving components are staggered and arranged on the connection end face of the same ozone generator 1. The photoelectric emitting component of one ozone generator 1 is correspondingly arranged with the photoelectric receiving component of the other ozone generator 1. When the two ozone generators 1 are connected, the photoelectric receiving component of one ozone generator 1 receives the photoelectric signal emitted by the photoelectric emitting component of the other ozone generator 1, which connects the control circuits of the two ozone generators 1 respectively, causing the two ozone generators 1 to turn off and stop working. The photoelectric sensing electronic control structure is triggered by signal transmission, without mechanical wear, so that the electronic control structure can be quickly connected or disconnected, which can be understood by those skilled in the art.

[0068] Further, in this embodiment, the ozone generator 1 includes a housing 110, a cover 111, and an ozone generating mechanism. Specifically, the housing 110 is provided with a cavity 1101, a port 1102, and a charging opening 1103. The port 1102 is located at the end of the housing 110 and communicates with the cavity 1101. The charging opening 1103 is located on the side wall of the housing 110. The ozone generating mechanism is installed in the cavity 1101 through the port 1102. It includes a mechanism support 201, a high-voltage module 202, a power module 203, a control board module 204, and a discharge module 205. Block 205 is mounted on the mechanism bracket 201 via a snap-fit ​​installation structure and a fastener installation structure. The mechanism bracket 201 is embedded in the housing cavity 1101 and divides the housing cavity 1101 into an electrical cavity 1106, an air inlet cavity 1107, and an air outlet cavity 1105. The electrical cavity 1106 and the air inlet cavity 1107 are located on the left and right sides of the air outlet cavity 1105, respectively. The high-voltage module 202, the power supply module 203, and the control board module 204 are located in the electrical cavity 1106. The discharge module 205 is located in the air outlet cavity 1105 and, under the action of the high-voltage module 202, ionizes the oxygen in the air outlet cavity 1105 to produce ozone. The high-voltage module 202 and the power supply module 205... The discharge module 205 and the power supply module 205 are electrically connected to the control board module 204. The power supply structure and the electrical control structure are located between the covers 111 of the two ozone generators 1 and are electrically connected to the control board modules 204 of the two ozone generators 1. The power supply terminal of the power supply structure extends out of the housing 110 through the charging opening 1103. The cover 111 is installed on the opening of the housing 110 through a snap-fit ​​structure and has an air inlet 1111 that connects to the air inlet cavity 1107 and an air outlet 1112 that connects to the air outlet cavity 1105. Through the above technical solution, air enters the housing 110 through the air inlet 1111 and passes through the air inlet cavity 1107, the electrical cavity 1106 and the air outlet cavity in sequence. 1105 and the air outlet 1112 is discharged outside the housing 110. The air outlet 1105 separates the electrical cavity 1106 from the air inlet cavity 1107, so that the heat generated by the high voltage module 202 can be discharged outside the housing 110 in a timely manner through the air outlet 1105 and the air outlet 1112, and the impact on the air temperature in the air inlet cavity 1107 is reduced. This allows the temperature inside the housing 110 to be discharged in a timely manner, improving the heat dissipation effect of the ozone generator 1. In addition, an airflow circulation path from the outside to the inside is formed inside the housing 110, which optimizes the airflow path in the housing 110, allowing the air to circulate quickly inside the housing 110, thereby improving the ozone generation efficiency. This is something that those skilled in the art can understand.

[0069] Furthermore, the ozone generating mechanism also includes a fan module 206. Specifically, in this embodiment, the fan module 206 is mounted on the mechanism bracket 201 via a fastener mounting structure and is located at the air inlet end of the air outlet cavity 1105. The fan module 206 is electrically connected to the control board module 204. Through the above technical solutions, the fan module 206 further enhances the flow velocity in the housing 110, forces convection to accelerate ozone diffusion, and further enhances the deodorization effect of the deodorizer, which can be understood by those skilled in the art.

[0070] Furthermore, the ozone generating mechanism also includes an indicator light module 207. Specifically, in this embodiment, the indicator light module 207 is disposed on the control board module 204 and located on the side of the charging component 103. The light color of the indicator light module 207 is preferably red and green. When the ozone generator 1 is stationary, the indicator light module 207 is off. When the ozone generator 1 is charging, the light of the indicator light module 207 is red. When the ozone generator 1 is fully charged, the light of the indicator light module 207 is green. Through the above technical solution, the ozone generator 1 can intuitively display its charging status through the light color of the indicator light module 207, which can be understood by those skilled in the art.

[0071] Furthermore, the deodorizer also includes a connecting rope 3. Specifically, in this embodiment, the two ends of the connecting rope 3 are respectively fastened to the housings 110 of the two ozone generators 1 to prevent the two ozone generators 1 from being lost when separated, making it convenient for users to use the deodorizer outdoors. Specifically, the connecting rope 3 is preferably made of flexible materials such as silicone or rubber, allowing the two ozone generators 1 to move within a certain range when separated. The connecting rope 3 is provided with wires. Specifically, the two ends of the wires are respectively connected to the control board module 204 wires of the two ozone generators 1, so that the deodorizer can keep the charging circuit of the two ozone generators 1 connected without the need for a recharging structure, which will be understood by those skilled in the art.

[0072] Furthermore, the deodorizer's control circuit includes a main control MCU module, an ozone generation control circuit module, a lithium battery management module, and a fan switch circuit module. The main control MCU module, ozone generation control circuit module, and fan switch circuit module are each present in two sets and are respectively installed on two ozone generators 1. The lithium battery management module is present in one set and is installed on the ozone generator 1 with the charging component 103. For the ozone generator 1 with the lithium battery management module, its main control MCU module is electrically connected to the ozone generation control module, the fan switch circuit module, the first energy replenishment electrode component 104, the first control electrode component 108, and the lithium battery management module, respectively. The lithium battery management module is electrically connected to the charging component 103 and the power module 203, respectively. For the ozone generator 1 without the lithium battery management module, its main control MCU module is electrically connected to the ozone generation control module, the fan switch circuit module, the second energy replenishment electrode component 105, the second control electrode component 109, and the power module 203, respectively.

[0073] The deodorizer's circuit principle is as follows: When the two ozone generators 1 are connected to each other, the first energy-generating electrode component 104 and the second energy-generating electrode component 105 are electrically connected, and the first control electrode component 108 and the second control electrode component 109 are electrically connected and connected to the signal. The signal is transmitted to the main control MCU module of the two ozone generators 1 respectively. After receiving the signal, the main control MCU module shuts down the ozone generation control module and the fan switch circuit module and turns on the lithium battery management module. When the two ozone generators 1 are separated from each other, the first energy-generating electrode component 104 and the second energy-generating electrode component 105 are separated, and the first control electrode component 108 and the second control electrode component 109 are separated and disconnected from the signal. After losing the signal, the main control MCU module turns on the ozone generation control module and the fan switch circuit module and turns off the lithium battery management module.

[0074] Second embodiment:

[0075] See Figure 9-11 The difference between this deodorizer and the first embodiment is that the housing 110 is provided with a cavity 1101, a port 1102, and a charging slot 1104. The port 1102 is located at the end of the housing 110 and communicates with the cavity 1101. The charging slot 1104 is located on the port 1102. The control board module 204 is installed on the cover 111 through a snap-fit ​​installation structure. The high voltage module 202, the power module 203, and the discharge module 205 are respectively installed on the mechanism bracket 201 through snap-fit ​​installation structure and fastener installation structure. The power connection end of the energy replenishment structure extends out of the housing 110 through the charging slot 1104. Through the above technical solutions, the structure of the housing 110 is simpler, the number of inserts in the production mold is reduced, the design cost and manufacturing cost of the production mold are reduced, and the production cost of the housing 110 is reduced, which can be understood by those skilled in the art.

[0076] Other parts not described herein are the same as in the first embodiment and will not be repeated.

[0077] The above describes the preferred embodiments of this utility model, illustrating and describing its basic principles, main features, and advantages. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of this utility model. Various changes and modifications can be made without departing from the spirit and scope of this utility model, and all such changes and modifications fall within the scope of protection of this utility model as defined by the appended claims and their equivalents.

Claims

1. A deodorizer, characterized in that, It includes two or more ozone generators (1) that can be connected or separated from each other, a connection structure for connecting or separating each ozone generator (1), a power supply structure for electrically connecting each ozone generator (1) and connecting to an external power supply for power supply, and an electrical control structure for controlling the opening and closing of each ozone generator (1). When the ozone generators (1) are connected, each ozone generator (1) is turned off and stops working, and the ozone generators (1) are powered on and connected to an external power source for energy replenishment; when the ozone generators (1) are separated, the ozone generators (1) are powered off and the external power source is disconnected to stop energy replenishment, and the ozone generators (1) are started and begin working.

2. The deodorizer according to claim 1, characterized in that, There are two ozone generators (1). When the two ozone generators (1) are connected, the connection end faces of the two ozone generators (1) abut against each other. The connection structure, energy replenishment structure and electrical control structure are set between the two ozone generators (1).

3. The deodorizer according to claim 2, characterized in that, The connection structure is a magnetic connection structure, which includes a first magnetic component (101) disposed on the connection end face of one of the ozone generators (1) and a second magnetic component (102) disposed on the connection end face of the other ozone generator (1). The first magnetic component (101) is disposed corresponding to the second magnetic component (102). When the first magnetic component (101) and the second magnetic component (102) are attracted to each other, the two ozone generators (1) are connected. Alternatively, the connection structure is a screw-on connection structure, which includes a first screw-on part disposed on the outer edge of the connection end face of one of the ozone generators (1) and a second screw-on part disposed on the outer edge of the connection end face of the other ozone generator (1). The first screw-on part is disposed corresponding to the second screw-on part. When the first screw-on part and the second screw-on part are screwed together, the two ozone generators (1) are connected. Alternatively, the connection structure is a hinge-locking connection structure, which includes a first hinge component and a first locking component disposed opposite to each other on both sides of the connection end face of one of the ozone generators (1), and a second hinge component and a second locking component disposed opposite to each other on both sides of the connection end face of the other ozone generator (1). The first hinge component is disposed corresponding to the second hinge component and the two are hinged together. The first locking component is disposed corresponding to the second locking component. When the first hinge component rotates relative to the second hinge component and the first locking component and the second locking component are locked together, the two ozone generators (1) are connected. Alternatively, the connection structure is a grooving connection structure, which includes a first groove on the connection end face of one of the ozone generators (1) and a second groove on the connection end face of the other ozone generator (1). The first groove is provided corresponding to the second groove. When the first groove is inserted from the beginning of the second groove and slides along the end of the second groove, the two ozone generators (1) are connected.

4. The deodorizer according to claim 3, characterized in that, The first magnetic attraction component (101) and the second magnetic attraction component (102) are a plurality of each and are evenly arranged in a circumferential direction. At least one first magnetic attraction component (101) is set as the reverse pole and at least one second magnetic attraction component (102) is set as the positive pole. Each first magnetic attraction component (101) and each second magnetic attraction component (102) corresponds to each other. When the first magnetic attraction component (101) of the reverse pole corresponds to the second magnetic attraction component (102) of the positive pole, the two ozone generators (1) are positioned and connected to each other. Alternatively, the first magnetic attraction component (101) and the second magnetic attraction component (102) are both a number and are arranged unequally in the circumferential direction. When each of the first magnetic attraction components (101) and each of the second magnetic attraction components (102) corresponds one-to-one, the two ozone generators (1) are positioned and connected to each other.

5. The deodorizer according to claim 2, characterized in that, The energy replenishment structure includes a charging component (103) disposed on any ozone generator (1) and connected to an external power source, a first energy replenishment electrode component (104) disposed on one of the ozone generators (1), and a second energy replenishment electrode component (105) disposed on the other ozone generator (1). The first energy replenishment electrode component (104) and the second energy replenishment electrode component (105) are disposed correspondingly. The first energy replenishment electrode component (104) or the second energy replenishment electrode component (105) is electrically connected to the charging component (103). When the two ozone generators (1) are connected, the first energy replenishment electrode component (104) and the second energy replenishment electrode component (105) are electrically connected, and the external power source is electrically connected to the charging component (103), so that the two ozone generators (1) are energized and connected to the external power source for energy replenishment.

6. The deodorizer according to claim 4, characterized in that, The deodorizer also includes a positioning structure, which includes a positioning protrusion (106) disposed on the connecting end face of one of the ozone generators (1) and a positioning recess (107) disposed on the connecting end face of the other ozone generator (1) and corresponding to the positioning protrusion (106). A first energy-boosting electrode component (104) is disposed on the positioning protrusion (106) and a second energy-boosting electrode component (105) is disposed on the positioning recess (107). When the two ozone generators (1) are connected, the positioning protrusion (106) extends into the positioning recess (107) so that the first energy-boosting electrode component (104) is aligned with the second energy-boosting electrode component (105).

7. The deodorizer according to claim 2, characterized in that, The electrical control structure is a contact electrical control structure, which includes a first control electrode component (108) disposed on one of the ozone generators (1) and a second control electrode component (109) disposed on the other ozone generator (1). The first control electrode component (108) is disposed corresponding to the second control electrode component (109). When the first control electrode component (108) and the second control electrode component (109) are electrically connected, the ozone generator (1) is turned off and stops working. Alternatively, the electronic control structure is a reed switch electronic control structure, which includes a reed switch component disposed on one of the ozone generators (1) and a magnetic component disposed on the other ozone generator (1). The reed switch component and the magnetic component are disposed correspondingly. When the reed switch component senses the magnetic field of the magnetic component, it causes the ozone generator (1) to turn off and stop working. Alternatively, the electrical control structure is a Hall sensor electrical control structure, which includes a Hall element component disposed on one of the ozone generators (1) and a magnetic component disposed on the other ozone generator (1). The Hall element component and the magnetic component are disposed correspondingly. When the Hall element component senses the magnetic field of the magnetic component, it causes the ozone generator (1) to turn off and stop working. Alternatively, the electrical control structure is a micro switch electrical control structure, which includes a micro switch disposed on the ozone generator (1). The micro switch of one of the ozone generators (1) acts on the connection end face of the other ozone generator (1) and opens, so that the ozone generator (1) is turned off and stops working. Alternatively, the electronic control structure is an electromagnetic induction electronic control structure, which includes an electromagnetic transmitting component disposed on one of the ozone generators (1) and an electromagnetic receiving component disposed on the other ozone generator (1). The electromagnetic transmitting component and the electromagnetic receiving component are disposed correspondingly. When the two ozone generators (1) are connected, the electromagnetic receiving component receives the magnetic field of the electromagnetic transmitting component, causing the two ozone generators (1) to turn off and stop working. Alternatively, the electronic control structure is an infrared sensing electronic control structure, which includes an infrared emitting component disposed on one of the ozone generators (1) and an infrared receiving component disposed on the other ozone generator (1). The infrared emitting component and the infrared receiving component are disposed correspondingly. When the two ozone generators (1) are connected, the infrared receiving component receives the infrared signal from the infrared emitting component, causing the two ozone generators (1) to turn off and stop working. Alternatively, the electronic control structure is a radar sensing electronic control structure, which includes a microwave transmitting component installed on one of the ozone generators (1) and a microwave receiving component installed on the other ozone generator (1). The microwave transmitting component and the microwave receiving component are correspondingly installed. When the two ozone generators (1) are connected, the microwave receiving component receives the microwave signal from the microwave transmitting component, causing the two ozone generators (1) to turn off and stop working. Alternatively, the electronic control structure is a photoelectric sensing electronic control structure, which includes a photoelectric emitting component disposed on one of the ozone generators (1) and a photoelectric receiving component disposed on the other ozone generator (1). The photoelectric emitting component and the photoelectric receiving component are disposed correspondingly. When the two ozone generators (1) are connected, the photoelectric receiving component receives the photoelectric signal from the photoelectric emitting component, causing the two ozone generators (1) to turn off and stop working.

8. The deodorizer according to any one of claims 2-7, characterized in that, The ozone generator (1) includes a housing (110), a cover (111), and an ozone generating mechanism. The housing (110) has a cavity (1101) and a port (1102) communicating with the cavity (1101). The ozone generating mechanism includes a support bracket (201), a high-voltage module (202), a power supply module (203), a control board module (204), and a discharge module (205) and is disposed in the cavity (1101). The cover (1101) is located in the cavity (1101). 11) The cover is installed on the shell opening (1102), the mechanism bracket (201) is set in the shell cavity (1101), the high voltage module (202), the power supply module (203) and the discharge module (205) are electrically connected to the control board module (204) respectively, the energy replenishment structure and the electrical control structure are set between the covers (111) of the two ozone generators (1), and the energy replenishment structure and the electrical control structure are electrically connected to the control board module (204) of the two ozone generators (1) respectively; The high-voltage module (202), power module (203), control board module (204) and discharge module (205) are all mounted on the mechanism bracket (201). The housing (110) is also provided with a charging opening (1103), which is located on the side wall of the housing (110). The power connection end of the energy replenishment structure extends out of the housing (110) through the charging opening (1103). Alternatively, the control board module (204) is mounted on the cover (111), and the high voltage module (202), power supply module (203), and discharge module (205) are all mounted on the mechanism bracket (201). The housing (110) is also provided with a charging slot (1104), which is located on the opening (1102). The power connection end of the energy replenishment structure extends out of the housing (110) through the charging slot (1104). When the mechanism support (201) is set in the shell cavity (1101), the mechanism support (201) divides the shell cavity (1101) into an electrical cavity (1106), an air inlet cavity (1107) and an air outlet cavity (1105). The electrical cavity (1106) and the air inlet cavity (1107) are located on the left and right sides of the air outlet cavity (1105), respectively. The high voltage module (202), the power supply module (203) and the control board module (204) are located in the electrical cavity (1106), and the discharge module (205) is located in the air outlet cavity (1105). The cover (111) is provided with an air inlet (1111) that connects to the air inlet cavity (1107) and an air outlet (1112) that connects to the air outlet cavity (1105).

9. The deodorizer according to claim 8, characterized in that, The ozone generating mechanism also includes a fan module (206), which is mounted on the mechanism support (201) and located at the air inlet of the air outlet cavity (1105). The fan module (206) is electrically connected to the control board module (204). The ozone generating mechanism also includes an indicator light module (207), which is mounted on the control board module (204). The indicator light module (207) has a light color of red and / or green and / or blue.

10. The deodorizer according to claim 8, characterized in that, The deodorizer also includes a connecting rope (3), the two ends of which are connected to the housings (110) of the two ozone generators (1). The connecting rope (3) is made of flexible material and has wires inside. The two ends of the wires are connected to the control board modules (204) of the two ozone generators (1).