Gas detector mounting structure and gas detector

By designing an installation structure with a receiving cavity and opening, combined with a liquid drainage method for the protective part, the problem of insufficient protection of gas detectors in outdoor environments is solved, achieving better protection, stability, and convenience.

CN224414847UActive Publication Date: 2026-06-26JIAOZHOU GAS BRANCH OF QINGDAO ENERGY CHINA RESOURCES GAS CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIAOZHOU GAS BRANCH OF QINGDAO ENERGY CHINA RESOURCES GAS CO LTD
Filing Date
2025-07-01
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Existing gas detector installation structures offer poor protection in outdoor environments, making them susceptible to corrosion from liquids such as snow, rain, watering cans, and cleaning water, thus affecting their lifespan.

Method used

A gas detector mounting structure is designed, including a mounting component and a connector. The mounting component has a receiving cavity and an opening, and is detachably connected to the detector body through the connector. The protective part guides liquid from the side of the opening to the target surface to ensure air circulation and protective effect.

Benefits of technology

This improves the protection of the gas detector, prevents liquid from entering the containment cavity, extends the life of the detector, and maintains the stability and ease of disassembly and assembly of the detector body.

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Abstract

The application provides a gas detector mounting structure and a gas detector, and belongs to the technical field of gas detector mounting. The gas detector mounting structure is used for being arranged on a target surface, and comprises a mounting piece and a connecting piece. The mounting piece comprises a mounting part and a protection part. One side of the mounting part is connected with the protection part, and the other side is used for being connected with the target surface. The mounting part has a containing cavity. At least one opening is formed in the mounting part and is in communication with the containing cavity. The containing cavity is used for containing a detector body. The protection part is used for guiding liquid from the side of the opening to the target surface. The mounting part is used for being detachably connected with the detector body through the connecting piece. The gas detector mounting structure provided by the application is convenient to use and has good protection effect on the gas detector.
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Description

Technical Field

[0001] This application relates to the field of gas detector installation technology, and in particular to a gas detector installation structure and a gas detector. Background Technology

[0002] Underground gas pipelines are a crucial component of urban gas supply systems, primarily used to deliver natural gas to various points of use within the city, such as residential areas, commercial facilities, and industrial users. Gas detectors can be used to detect leaks in gas pipelines, alerting users to take preventative measures to avoid accidents.

[0003] In related technologies, users fix a wall-mounted bracket to an indoor wall and then clip the gas detector onto the bracket, or they place the base of a column securely on the indoor floor and use the top of the column to fix the gas detector. In this way, the gas detector is fixed at an appropriate height, and when a leak occurs in the underground gas pipeline and the natural gas level rises, the gas concentration can be detected by the gas detector.

[0004] However, in some applications, the above-mentioned installation structure provides poor protection for the gas detector, which can affect the detector's service life. Utility Model Content

[0005] This application provides a gas detector mounting structure and a gas detector to address the shortcomings of related technologies.

[0006] On one hand, this application provides a gas detector mounting structure for mounting on a target surface, the gas detector mounting structure comprising:

[0007] The mounting component includes a mounting part and a protective part. One side of the mounting part is connected to the protective part, and the other side is used to connect to the target surface. The mounting part has a receiving cavity, and at least one opening communicating with the receiving cavity is provided on the mounting part. The receiving cavity is used to accommodate the detector body. The protective part is used to guide liquid from the side of the opening to the target surface.

[0008] The connector and mounting part are used for detachable connection with the detector body via the connector.

[0009] In one possible implementation, the gas detector mounting structure provided in this application includes a protective section comprising at least one protective segment located on the side of the opening away from the target surface. One side of the protective segment is connected to one side of the mounting section, and the other side of the protective segment extends in a direction away from the mounting section and close to the target surface.

[0010] In one possible implementation, the gas detector mounting structure provided in this application has a cover surface on the protective part that matches the mounting part. The cover surface is connected to the mounting part so that the protective part covers the mounting part. The projection of the protective part toward the target surface covers the mounting part.

[0011] In one possible implementation, the gas detector mounting structure provided in this application has a guide surface on the side of the protective part away from the mounting part, and the outline of the guide surface is V-shaped with the opening facing the mounting part.

[0012] In one possible implementation, the gas detector mounting structure provided in this application includes a connector comprising at least one first connecting portion and at least two second connecting portions; the first connecting portion is located within a receiving cavity and is used to abut against the detector body to support the detector body; the mounting portion is used to connect or disconnect from the first connecting portion via the second connecting portions to connect or disconnect from the detector body.

[0013] In one possible implementation, the gas detector mounting structure provided in this application includes a first connecting portion comprising a support section and a connecting section arranged sequentially; the support section is used to abut against the detector body to support the detector body; and the connecting section is used to connect or disconnect from the second connecting portion.

[0014] In one possible implementation, the gas detector mounting structure provided in this application includes a second connecting part comprising a bolt and a nut; a first through hole is provided on the mounting part, and a second through hole is provided on the connecting section; the bolt is used to pass through the first through hole and the second through hole in sequence, and to fit the nut to connect the mounting part and the detector body.

[0015] In one possible implementation, the gas detector mounting structure provided in this application has a second connecting part that is a screw; one of the mounting part and the connecting section has a through hole, and the other has a threaded hole that matches the screw. The screw is used to pass through the through hole and connect with the threaded hole to connect the mounting part and the detector body.

[0016] In one possible implementation, the gas detector mounting structure provided in this application has mounting components made of plastic or metal.

[0017] On the other hand, this application provides a gas detector, including a detector body and a gas detector mounting structure as described above connected to the detector body.

[0018] This application provides a gas detector installation structure and a gas detector. The gas detector installation structure is used to install on a target surface, which can be a structural surface above the ground, such as a marker post or railing in an outdoor courtyard. The gas detector installation structure includes a mounting part and a connecting part. The mounting part includes a mounting section and a protective section. One side of the mounting part is connected to the protective section, and the other side is connected to the target surface. The mounting part has a receiving cavity, and at least one opening communicating with the receiving cavity is provided on the mounting part. The detector body is placed in the receiving cavity. The mounting part is detachably connected to the detector body via the connecting part, ensuring that the relative position of the detector body and the mounting part remains stable during use and facilitating the disassembly and assembly of the detector body. The opening allows air circulation between the receiving cavity and the outside, facilitating the detector body's detection of gas concentration. The protective section is used to guide liquids from the side of the opening towards the target surface. The liquids can be snow, rainwater, watering cans, or cleaning water dripping onto the protective section, preventing liquids from flowing into the detector body inside the receiving cavity through the opening. The gas detector installation structure provided by this application is convenient to use and provides good protection for the gas detector. Attached Figure Description

[0019] The accompanying drawings, which are incorporated in and form part of this specification, illustrate embodiments consistent with this application and, together with the description, serve to explain the principles of this application.

[0020] Figure 1 A schematic diagram of the gas detector installation structure provided in the embodiments of this application. Figure 1 ;

[0021] Figure 2 A schematic diagram of the gas detector installation structure provided in the embodiments of this application. Figure 2 ;

[0022] Figure 3 An exploded view of a gas detector provided in an embodiment of this application;

[0023] Figure 4 for Figure 3 A schematic diagram of the structure of the first connecting part.

[0024] Explanation of reference numerals in the attached figures:

[0025] 100 - Gas detector mounting structure;

[0026] 110 - Mounting component; 111 - Mounting section; 1111 - Receiving cavity; 1112 - Opening; 1113 - First through hole; 112 - Protective section; 1121 - Protective segment; 1122 - Covering surface; 1123 - Guide surface;

[0027] 120 - Connector; 121 - First connecting part; 1211 - Support section; 1212 - Connecting section; 1213 - Second through hole; 1214 - Connecting hole; 122 - Second connecting part; 1221 - Bolt; 1222 - Nut;

[0028] 200-Gas Detector;

[0029] 210 - Detector body. Detailed Implementation

[0030] To make the objectives, technical solutions, and advantages of this application clearer, the technical solutions in the embodiments of this application will be described in more detail below with reference to the accompanying drawings. In the drawings, the same or similar reference numerals denote the same or similar components or components having the same or similar functions throughout. The described embodiments are some, but not all, embodiments of this application. The embodiments described below with reference to the accompanying drawings are exemplary and intended to explain this application, and should not be construed as limiting this application. All other embodiments obtained by those skilled in the art based on the embodiments of this application without creative effort are within the scope of protection of this application. The embodiments of this application will be described in detail below with reference to the accompanying drawings.

[0031] In the description of this application, it should be noted that, unless otherwise expressly specified and limited, the terms "installation," "connection," and "linking" should be interpreted broadly. For example, they can refer to a fixed connection, an indirect connection through an intermediate medium, or the internal communication of two components or the interaction between two components. Those skilled in the art can understand the specific meaning of the above terms in this application according to the specific circumstances.

[0032] In the description of this application, it should be understood that the terms "upper", "lower", "front", "rear", "left", "right", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are used only for the convenience of describing this application and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this application.

[0033] The terms "first," "second," "third," "fourth," etc., used in the specification, claims, and accompanying drawings of this application are used to distinguish similar objects and are not necessarily used to describe a specific order or sequence. It should be understood that such data can be interchanged where appropriate so that the embodiments of this application described herein can be implemented, for example, in a sequence other than those illustrated or described herein.

[0034] Furthermore, the terms “comprising” and “having”, and any variations thereof, are intended to cover non-exclusive inclusion, such that a process, method, system, product, or apparatus that includes a series of steps or units is not necessarily limited to those steps or units that are explicitly listed, but may include other steps or units that are not explicitly listed or that are inherent to such process, method, product, or apparatus.

[0035] Underground gas pipelines are a crucial component of urban gas supply systems, primarily used to deliver natural gas to various points of use within the city, such as residential areas, commercial facilities, and industrial users. Gas detectors can be used to detect leaks in underground gas pipelines, alerting users to take preventative measures to avoid accidents.

[0036] In related technologies, users fix a wall-mounted bracket to an indoor wall and then clip the gas detector onto the bracket, or they place the base of a column securely on the indoor floor and use the top of the column to fix the gas detector. In this way, the gas detector is fixed at an appropriate height, and when a leak occurs in the underground gas pipeline, the natural gas will rise, allowing the gas concentration to be detected by the gas detector.

[0037] However, in some application scenarios, such as with the increasing prevalence of gas use and the growing distribution of underground gas pipelines (which are installed not only indoors but also in outdoor courtyards), when the gas detector is installed in an outdoor courtyard using the aforementioned installation structure, snow and rainwater can drip into the detector, causing damage. Furthermore, improper handling of water from watering plants or cleaning can also damage the gas detector. Therefore, the aforementioned installation structure offers poor protection for the gas detector, affecting its lifespan.

[0038] In view of this, this application provides a gas detector mounting structure and a gas detector. The gas detector mounting structure is used to install on a target surface, which can be a structural surface above the ground, such as a marker post or railing in an outdoor courtyard. The gas detector mounting structure includes a mounting part and a connecting part. The mounting part includes a mounting section and a protective section. One side of the mounting part is connected to the protective section, and the other side is connected to the target surface. The mounting part has a receiving cavity, and at least one opening communicating with the receiving cavity is provided on the mounting part. The detector body is placed in the receiving cavity. The mounting part is detachably connected to the detector body through the connecting part, so that the relative position of the detector body and the mounting part remains stable during use and the detector body is easy to disassemble and assemble. The opening allows air circulation between the receiving cavity and the outside, facilitating the detector body to detect gas concentration. The protective section is used to guide liquid from the side of the opening to the target surface. The liquid can be snow, rainwater, watering can, or cleaning water dripping onto the protective section, to prevent liquid from flowing into the detector body in the receiving cavity through the opening. The gas detector mounting structure provided by this application is convenient to use and provides good protection for the gas detector.

[0039] The present application will now be described in detail with reference to the accompanying drawings and specific embodiments.

[0040] See Figures 1 to 3 The gas detector mounting structure 100 provided in this application embodiment is used to be installed on a target surface. The gas detector mounting structure 100 includes a mounting member 110 and a connecting member 120. The mounting member 110 includes a mounting part 111 and a protective part 112. One side of the mounting part 111 is connected to the protective part 112, and the other side is used to connect to the target surface. The mounting part 111 has a receiving cavity 1111. At least one opening 1112 communicating with the receiving cavity 1111 is provided on the mounting part 111. The receiving cavity 1111 is used to receive the detector body 210. The protective part 112 is used to guide liquid from the side of the opening 1112 to the target surface. The mounting part 111 is used to be detachably connected to the detector body 210 through the connecting member 120.

[0041] It should be noted that the gas detector installation structure 100 of this application embodiment can be applied in outdoor courtyards, connecting the detector body 210 to the mounting component 110 for detecting gas leaks in the courtyard. Here, the target surface can be a structural surface higher than the ground, such as a marker post or railing in the outdoor courtyard. Of course, the gas detector installation structure 100 can also be applied to other outdoor locations. In this case, other surfaces higher than the ground within the actual outdoor area where the underground gas pipeline is located can be used as the target surface. This application embodiment does not impose any limitations on this.

[0042] Specifically, the receiving cavity 1111 of the mounting part 111 is used to provide a relatively closed but well-ventilated space for the detector body 210; the connector 120 is used to realize a stable connection between the detector body 210 and the mounting part 111, while taking into account the convenience in actual operation, making the disassembly and assembly process simple and quick, and facilitating the regular inspection and maintenance of the detector body 210.

[0043] The design of the opening 1112 ensures good air circulation inside and outside the containment cavity 1111, enabling the detector body 210 to accurately and promptly detect potential gas leaks in the surrounding environment. The protective part 112 is used to keep liquid away from the detector body 210 inside the containment cavity 1111, preventing liquid from flowing directly into the detector and causing damage, and improving the durability and service life of the detector body 210 in outdoor environments. The liquid can be snow or rainwater, watering water, or cleaning water that drips onto the protective part.

[0044] For example, such as Figure 1 and Figure 2 As shown, the Z direction represents the direction from top to bottom, i.e., the direction of gravity. After connecting one side of the mounting part 111 to the protective part 112 and the other side to the target surface, one side and the other side of the mounting part 111 are located on opposite sides of the mounting part 111 along the Z direction.

[0045] Furthermore, the opening 1112 is provided on the peripheral side of the mounting part 111. In this way, the protective part 112 can block the opening 1112. When it rains, rainwater falls on the protective part 112 and is guided by the protective part 112 to fall from the side of the opening 1112 onto the target surface.

[0046] In this embodiment, the number and specific shape of the openings 1112 are not limited. For example, the opening 1112 can be one or more, and the opening 1112 can be rectangular, circular, etc. Figure 2 As shown, two or more openings 1112 can be spaced apart along the circumferential direction of the mounting portion 111, or they can be arranged along... Figure 1 The Z-direction spacing can be set, or they can be arranged in rows and columns on the mounting part 111.

[0047] The specific structure of the mounting part 111 is not limited in the embodiments of this application. For example, the mounting part 111 can be a cylindrical shell structure, an elliptical shell structure, or a polygonal shell structure.

[0048] In summary, the gas detector mounting structure 100 of this application embodiment is used to be installed on a target surface, which can be a structural surface above the ground, such as a marker post or railing in an outdoor courtyard. One side of the mounting part 111 is connected to the protective part 112, and the other side is connected to the target surface. The mounting part 111 has a receiving cavity 1111, and at least one opening 1112 communicating with the receiving cavity 1111 is provided on the mounting part 111. The detector body 210 is placed in the receiving cavity 1111. The mounting part 111 is detachably connected to the detector body 210 through the connector 120, so that the relative position of the detector body 210 and the mounting part 111 remains stable during use, and the detector body 210 is easy to assemble and disassemble. The opening 1112 allows airflow between the receiving cavity 1111 and the outside, facilitating the detector body 210's detection of gas concentration. The protective section 112 is used to guide liquid from the side of the opening 1112 towards the target surface. The liquid can be snow, rainwater, watering can, or cleaning water dripping onto the protective section, preventing liquid from flowing into the detector body 210 inside the receiving cavity 1111 through the opening 1112. This design is convenient to use and provides good protection for the detector body 210.

[0049] See Figure 2 In some embodiments, the protective portion 112 includes at least one protective segment 1121, the protective segment 1121 being located on the side of the opening 1112 away from the target surface, one side of the protective segment 1121 being connected to one side of the mounting portion 111, and the other side of the protective segment 1121 extending in a direction away from the mounting portion 111 and close to the target surface.

[0050] Thus, through the design of the protective section 1121, the liquid can be guided to flow naturally from the side of the opening 1112 to the target surface under the action of gravity, avoiding the liquid from dripping directly into the opening 1112 and entering the receiving cavity 1111, thus protecting the detector body 210 from water damage.

[0051] For example, by providing at least one protective segment 1121, the protective segment 1121 is located on the side of the opening 1112 facing away from the target surface. In practical applications, the specific number of protective segments 1121 can be adjusted according to the arrangement of the openings 1112, such as their number and position. For example, an opening 1112 is provided on the mounting part 111, or the upper edge of the mounting part 111... Figure 2 When two or more openings 1112 are spaced apart in the Z direction, only one protective section 1121 needs to be installed. The protective section 1121 is positioned on the side of the upper opening 1112 facing away from the target surface, and then the protective section 1121 is connected to the mounting part 111. Figure 2As shown, when two or more openings 1112 are spaced apart around the periphery of the mounting portion 111, the number of protective sections 1121 can be set to two or more, so that the protective sections 1121 correspond one-to-one with the openings 1112. In this way, the layout of the mounting component 110 can be optimized, which is conducive to making the structural design of the mounting component 110 more compact and simple.

[0052] The embodiments of this application do not limit the specific structure of the protective section 1121, for example, as Figure 2 As shown, the protective section 1121 can be designed as a sloping or inclined canopy according to the roof structure of the building, with the canopy extending from one side of the mounting part 111; or, the protective section 1121 can be designed in a semi-circular or arched shape, covering the opening 1112 to form an arc-shaped cover.

[0053] See Figure 3 In some examples, the protective part 112 has a covering surface 1122 that matches the mounting part 111. The covering surface 1122 is connected to the mounting part 111 so that the protective part 112 covers the mounting part 111. The projection of the protective part 112 toward the target surface covers the mounting part 111.

[0054] Thus, by matching the covering surface 1122 of the protective part 112 with the mounting part 111, the connection between the protective part 112 and the mounting part 111 becomes more reliable. The protective part 112 covers the mounting part 111, and the projection of the protective part 112 toward the target surface covers the mounting part 111, thereby allowing the protective part 112 to receive liquid more fully and providing better shielding for the mounting part 111 as a whole, thereby preventing liquid from entering the receiving cavity 1111 through the opening 1112 on the mounting part 111.

[0055] For example, the mounting portion 111 can be configured as the aforementioned cylindrical housing, wherein the cylindrical housing may include two parallel circular base surfaces and a side surface connecting the two circular base surfaces. Thus, the cover surface 1122 can be configured as a plane to fully contact and connect with one of the two circular base surfaces; or, as... Figure 3 As shown, the cylindrical shell is hollow, meaning that the cylindrical shell only includes the side surface and does not have two circular bottom surfaces. The cylindrical shell has a preset thickness, which can be understood as the difference between the diameter of the outer cylindrical surface and the diameter of the inner cylindrical surface.

[0056] Furthermore, both sides of the cylindrical shell along the axial direction can be planar annular surfaces. That is, the outer and inner cylindrical surfaces have the same height along the axial direction, and are connected by a planar transition. Thus, the cover surface 1122 can also be configured as the aforementioned planar surface, to fully contact and connect with one of the two planar annular surfaces. Additionally, the height of the outer cylindrical surface along the axial direction can be less than the height of the inner cylindrical surface, allowing for a circular arc transition at their ends on the same side, so that one side of the cylindrical shell along the axial direction is a planar annular surface, and the other is an arc-shaped annular surface. Thus, the cover surface 1122 can be configured as follows: Figure 3 The conical surface shown is in full contact with and connected to the arc-shaped annular surface.

[0057] Of course, the mounting part 111 can be configured as the aforementioned polygonal shell structure, such as a rectangular shell. One side of the rectangular shell can have a rectangular clearance opening communicating with the receiving cavity 1111, forming a planar annular surface or a sloping annular surface on one side of the rectangular shell. When one side of the rectangular shell is a planar annular surface, the covering surface 1122 can be a plane; when one side of the rectangular shell is a sloping annular surface, the covering surface 1122 can be a pyramidal surface.

[0058] It should be noted that when the mounting part 111 is of other structures, the cover surface 1122 can be adapted to match the mounting part 111 by referring to the process. This application embodiment will not elaborate on this further.

[0059] In a specific example, the protective part 112 has a guide surface 1123 on the side away from the mounting part 111, and the outline of the guide surface 1123 is V-shaped with the opening 1112 facing the mounting part 111.

[0060] This design optimizes the guide path on the guide surface 1123, ensuring that rainwater and other liquids dripping onto the guide surface 1123 can flow relatively quickly to the edge of the guide surface 1123 and drain onto the target surface, reducing the phenomenon of water accumulation and making the protective part 112 have a good water-draining effect.

[0061] For example, the guide surface 1123 can be as follows: Figure 1 The conical or umbrella-shaped surface shown is used to make the profile of the guide surface 1123 V-shaped.

[0062] See Figure 3In some embodiments, the connector 120 includes at least one first connecting portion 121 and at least two second connecting portions 122; the first connecting portion 121 is located in the receiving cavity 1111 and is used to abut against the detector body 210 to support the detector body 210; the mounting portion 111 is used to connect or disconnect from the first connecting portion 121 through the second connecting portions 122 to connect or disconnect from the detector body 210.

[0063] The first connecting part 121 is located inside the receiving cavity 1111 and abuts against the detector body 210 to provide a stable support point for the detector body 210 and reduce the displacement of the detector body 210 due to slight vibration or external force during use. By providing at least two second connecting parts 122, the mounting part 111 can be connected to or disconnected from the first connecting part 121 through the second connecting parts 122, which helps to increase the firmness of the connection between the mounting part 111 and the detector body 210.

[0064] In specific implementation, such as Figure 3 As shown, the mounting portion 111 is configured as a hollow cylindrical shell consisting only of the side surfaces. This facilitates the placement of the detector body 210 and the first connecting portion 121 within the receiving cavity 1111, reducing assembly complexity.

[0065] For example, the first connecting part 121 can be configured as one, and the size of the first connecting part 121 matches the size of the detector body 210 to ensure that the first connecting part 121 can fully support the detector body 210. The mounting part 111 is connected to or disconnected from the first connecting part 121 by two or more second connecting parts 122; or, as Figure 3 As shown, the first connecting part 121 can also be configured as two or more, and the detector body 210 can be supported by two or more first connecting parts 121. The first connecting part 121 and the second connecting part 122 can be configured to correspond one-to-one. The mounting part 111 can be connected or disconnected from the corresponding first connecting part 121 through each second connecting part 122.

[0066] In this application embodiment, the specific connection method of the first connecting part 121 and the second connecting part 122 is not limited. For example, the second connecting part 122 can be configured as a buckle with a spring lock. The mounting part 111 has a relief opening to avoid the buckle. The buckle is directly inserted into the corresponding slot of the first connecting part 121 through the relief opening and locked. Alternatively, the first connecting part 121 and the second connecting part 122 can each be equipped with a magnet and connected by magnetic force.

[0067] In some examples, the first connection portion 121 includes a support section 1211 and a connection section 1212 arranged sequentially; the support section 1211 is used to abut against the detector body 210 to support the detector body 210; the connection section 1212 is used to connect or disconnect from the second connection portion 122.

[0068] This makes the structural design of the first connecting part 121 more reasonable. When the supporting section 1211 abuts against the detector body 210 to support the detector body 210, the position of the detector body 210 can reduce the interference of the connection between the connecting section 1212 and the second connecting part 122, and ensure that the mounting part 111 can be detachably connected to the detector body 210 through the connector 120.

[0069] For example, such as Figure 4 As shown, both the support section 1211 and the connecting section 1212 are plate-shaped structures, and the first connecting part 121 is an L-shaped plate. The support section 1211 may be provided with a connecting hole 1214. When the support section 1211 abuts against the detector body 210, it is connected to the detector body 210 by screws through the connecting hole 1214.

[0070] See Figure 3 and Figure 4 In a specific implementation, the second connecting part 122 includes a bolt 1221 and a nut 1222; the mounting part 111 has a first through hole 1113, and the connecting section 1212 has a second through hole 1213. The bolt 1221 is used to pass through the first through hole 1113 and the second through hole 1213 in sequence, and to fit the nut 1222 to connect the mounting part 111 and the detector body 210.

[0071] This makes the cooperation between the second connecting part 122 and the first connecting part 121 relatively simple, making it easy for operators to operate and enabling the detector body 210 and the mounting part 111 to be detachably connected.

[0072] In some examples, the second connecting part 122 is a screw (not shown); one of the mounting part 111 and the connecting section 1212 has a through hole, and the other has a threaded hole that matches the screw. The screw is used to pass through the through hole and connect with the threaded hole to connect the mounting part 111 and the detector body 210.

[0073] Thus, by setting the screw to be threadedly connected to the threaded hole, the self-locking characteristic of the threaded connection is utilized to reduce the loosening of the connection between the second connection part 122 and the first connection part 121, thereby improving the stability of the detector body 210.

[0074] Specifically, screw connections are simple to operate; installation can be completed simply by passing the screw through the connecting hole and screwing it into the threaded hole, or by rotating the screw in the opposite direction to easily remove it from the threaded hole, simplifying the assembly and disassembly process.

[0075] In a specific example, the mounting component 110 is either a plastic part or a metal part.

[0076] When the mounting component 110 is made of plastic, the lightweight nature of plastic makes the entire gas detector mounting structure 100 easy to transport, install, and adjust, especially suitable for scenarios requiring frequent movement or installation on weak target surfaces, such as marker posts. In addition, plastic is a good electrical insulation material, avoiding electrical interference or safety hazards that may be caused by external environmental factors such as lightning strikes or static electricity, which helps improve the safety of the gas detector mounting structure 100. Furthermore, plastic components are low in cost and have a relatively simple processing technology, facilitating mass production and reducing manufacturing costs.

[0077] When the mounting component 110 is made of metal, it can be made of stainless steel, aluminum alloy, or similar materials, which have high mechanical strength and impact resistance, making the gas detector mounting structure 100 more stable during use. This ensures that the detector body 210 maintains a stable position during long-term use, reducing displacement or loosening caused by external factors such as strong winds or vibrations, and minimizing the impact on the detector body 210's detection efficiency due to deformation or damage to the mounting component 110.

[0078] In practice, the mounting part 111 and the protective part 112 can be connected by welding or integrally formed, and this application embodiment does not limit this.

[0079] See Figure 3 This application also provides a gas detector 200, including a detector body 210 and a gas detector mounting structure 100 as described in any of the foregoing embodiments connected to the detector body 210.

[0080] The overall structure and working principle of the gas detector mounting structure 100 are the same as those in the aforementioned embodiments, and will not be repeated here.

[0081] The gas detector 200 of this application embodiment includes a gas detector mounting structure 100, which is used to mount on a target surface. The target surface can be a structure higher than the ground, such as a marker post or railing in an outdoor courtyard. The gas detector mounting structure 100 includes a mounting part 110 and a connecting part 120. The mounting part 110 includes a mounting portion 111 and a protective portion 112. One side of the mounting portion 111 is connected to the protective portion 112, and the other side is connected to the target surface. The mounting portion 111 has a receiving cavity 1111, and at least one opening 1112 communicating with the receiving cavity 1111 is provided on the mounting portion 111. The detector body 210 is placed in the receiving cavity 1111. The mounting portion 111 is detachably connected to the detector body 210 through the connecting part 120, so that the relative position of the detector body 210 and the mounting portion 111 remains stable during use and the detector body 210 is easy to assemble and disassemble.

[0082] The opening 1112 allows airflow between the receiving cavity 1111 and the outside, facilitating the detector body 210's detection of gas concentration. The protective section 112 guides liquid from the side of the opening 1112 towards the target surface. The liquid can be snow, rainwater, watering cans, or cleaning water dripping onto the protective section, preventing rainwater from flowing into the detector body 210 inside the receiving cavity 1111 through the opening 1112. Overall, it is convenient to use and provides good protection for the detector body 210.

[0083] Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of this application, and are not intended to limit them. Although this application has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some or all of the technical features therein. Such modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the scope of the technical solutions of the embodiments of this application.

Claims

1. A gas detector mounting structure (100) for mounting on a target surface, characterized in that, The gas detector mounting structure (100) includes: Mounting component (110), comprising a mounting portion (111) and a protective portion (112), wherein one side of the mounting portion (111) is connected to the protective portion (112), and the other side is used to connect to the target surface; the mounting portion (111) has a receiving cavity (1111), and at least one opening (1112) communicating with the receiving cavity (1111) is provided on the mounting portion (111), the receiving cavity (1111) being used to receive the detector body (210); the protective portion (112) is used to guide liquid from the side of the opening (1112) to the target surface; The connector (120) and the mounting part (111) are used to be detachably connected to the detector body (210) via the connector (120).

2. The gas detector mounting structure (100) according to claim 1, characterized in that, The protective part (112) includes at least one protective section (1121), the protective section (1121) is located on the side of the opening (1112) away from the target surface, one side of the protective section (1121) is connected to one side of the mounting part (111), and the other side of the protective section (1121) extends in a direction away from the mounting part (111) and close to the target surface.

3. The gas detector mounting structure (100) according to claim 1, characterized in that, The protective part (112) has a cover surface (1122) that matches the mounting part (111), the cover surface (1122) is connected to the mounting part (111) so that the protective part (112) covers the mounting part (111); The projection of the protective part (112) toward the target surface covers the mounting part (111).

4. The gas detector mounting structure (100) according to claim 3, characterized in that, The protective part (112) has a guide surface (1123) on the side opposite to the mounting part (111), and the outline of the guide surface (1123) is V-shaped with an opening (1112) facing the mounting part (111).

5. The gas detector mounting structure (100) according to any one of claims 1 to 4, characterized in that, The connector (120) includes at least one first connecting part (121) and at least two second connecting parts (122). The first connecting part (121) is located inside the receiving cavity (1111) and is used to abut against the detector body (210) to support the detector body (210); the mounting part (111) is used to connect or disconnect from the first connecting part (121) through the second connecting part (122) to connect or disconnect from the detector body (210).

6. The gas detector mounting structure (100) according to claim 5, characterized in that, The first connecting part (121) includes a support section (1211) and a connecting section (1212) arranged sequentially. The support section (1211) is used to abut against the detector body (210) to support the detector body (210); the connecting section (1212) is used to connect or disconnect from the second connecting part (122).

7. The gas detector mounting structure (100) according to claim 6, characterized in that, The second connecting part (122) includes a bolt (1221) and a nut (1222); The mounting part (111) has a first through hole (1113), and the connecting section (1212) has a second through hole (1213). The bolt (1221) is used to pass through the first through hole (1113) and the second through hole (1213) in sequence, and to fit the nut (1222) to connect the mounting part (111) and the detector body (210).

8. The gas detector mounting structure (100) according to claim 6, characterized in that, The second connecting part (122) is a screw; One of the mounting part (111) and the connecting section (1212) has a through hole, and the other has a threaded hole that matches the screw. The screw is used to pass through the through hole and connect to the threaded hole to connect the mounting part (111) and the detector body (210).

9. The gas detector mounting structure (100) according to any one of claims 1 to 4, characterized in that, The mounting component (110) is made of plastic or metal.

10. A gas detector (200), characterized in that, It includes a detector body (210) and a gas detector mounting structure (100) as described in any one of claims 1 to 9 connected to the detector body (210).