A temperature sensor housing and a temperature sensor
By designing a limiting part and a sliding groove structure on the temperature sensor housing, combined with an internal partition and potting layer, the problem of the traditional single function of temperature sensors is solved, realizing multi-functional integration and efficient sealing, and improving the installation accuracy and protection level of the equipment.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HANGZHOU SUPER ELECTRONICS TECH
- Filing Date
- 2025-08-07
- Publication Date
- 2026-07-14
AI Technical Summary
Traditional temperature sensors have a simple structure, limited functionality, and poor expandability, making it difficult to meet the needs of multi-functional integration.
Design a temperature sensor housing with limiting parts and sliding groove structure on both sides of the housing. The functional board is accurately positioned and tightly fitted by limiting blocks and elastic elements. The internal partition divides the assembly chamber and is sealed by potting layer. It integrates a multi-functional module such as a solar panel.
This achieves standardized installation of functional panels, preventing loosening and detachment, improving the equipment's multi-functional integration capabilities and sealing performance, reducing installation difficulty and potting costs, and enhancing the equipment's protection level.
Smart Images

Figure CN224499706U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of temperature sensor technology, and in particular to a temperature sensor housing and a temperature sensor. Background Technology
[0002] In the field of temperature measurement and control, temperature sensors, as core sensing devices, directly determine the accuracy and application range of the system through their performance and functionality. Traditional temperature sensors are used in many fields to monitor the temperature of specific locations or spaces, but their structural designs generally suffer from limitations such as single functionality and poor expandability. Utility Model Content
[0003] In order to overcome at least one of the defects of the prior art, the present invention provides a temperature sensor housing and a temperature sensor, which can solve the problem that the temperature sensor in the prior art has a simple structure and lacks a basis for functional expansion.
[0004] The technical solution adopted by this utility model to solve its problem is:
[0005] A temperature sensor housing, comprising:
[0006] The housing has an assembly area, and a first limiting part and a second limiting part are respectively provided on opposite sides of the assembly area. The first limiting part and the housing form a first sliding groove, and the second limiting part and the housing form a second sliding groove.
[0007] A function board, wherein the first slide groove and the second slide groove are respectively inserted into the two sides of the function board.
[0008] Furthermore, the first limiting part is provided with a first limiting block facing the first slide groove. The first limiting block is located on the movement trajectory of the functional plate inserted into the first slide groove, and the first limiting part and / or the first limiting block are elastic members to keep the functional plate under pressure on the housing.
[0009] The second limiting part is provided with a second limiting block facing the direction of the second slide groove. The second limiting block is located on the movement trajectory of the functional plate inserted into the second slide groove, and the second limiting part and / or the second limiting block are elastic members to keep the functional plate under pressure on the housing.
[0010] Furthermore, the housing has an assembly cavity inside, and a partition is provided in the assembly cavity. The partition is attached to the inner wall of the housing and divides the assembly cavity into a first assembly cavity and a second assembly cavity by the partition.
[0011] Furthermore, the second assembly cavity is provided with an adhesive layer.
[0012] Furthermore, the housing is provided with a support plate in the first assembly cavity, the support plate is arranged along the edge of the partition, and the partition abuts against the support plate.
[0013] Furthermore, the partition is a circuit board.
[0014] Furthermore, the functional panel is a solar panel.
[0015] Furthermore, the housing has multiple assembly areas, and each assembly area is provided with a first limiting part, a second limiting part and a functional plate, and each functional plate is correspondingly assembled in each first slide groove and each second slide groove.
[0016] Furthermore, the housing includes a first housing and a second housing, one end of the first housing is provided with an opening, the second housing is provided at the opening, and the first limiting part and the second limiting part are both provided in the first housing.
[0017] Furthermore, the first housing is provided with a third limiting part in the direction away from the second housing. The third limiting part is located at the end of the first slide groove and the second slide groove away from the second housing, and the functional plate abuts against the third limiting part.
[0018] This utility model also provides a temperature sensor, including:
[0019] The temperature sensor housing described above has an assembly cavity inside, and a partition is provided inside the assembly cavity. The partition is fitted to the inner wall of the housing and divides the assembly cavity into a first assembly cavity and a second assembly cavity by the partition.
[0020] Antenna, wherein the antenna is disposed in the first assembly cavity;
[0021] A battery, wherein the battery is disposed in the first assembly cavity;
[0022] A temperature probe is located outside the housing.
[0023] Furthermore, the partition is a circuit board, and the antenna, the battery, and the temperature probe are all electrically connected to the circuit board. The second assembly cavity is provided with a potting layer.
[0024] Furthermore, it also includes an assembly base, which is located at one end of the housing.
[0025] Furthermore, a magnetic element is provided on one side of the mounting base.
[0026] Furthermore, it also includes a conductive component, wherein the mounting base is made of a conductive material, one end of the conductive component is connected to the circuit board, and the other end is connected to the mounting base, so that the circuit board and the mounting base are at the same potential.
[0027] In summary, the temperature sensor housing and temperature sensor provided by this utility model have the following technical effects:
[0028] 1. The housing has a first limiting part and a second limiting part on both sides of the assembly area, forming a first sliding groove and a second sliding groove with the housing, providing a standardized installation channel for the functional board. When the functional board is inserted into the sliding groove on both sides, the guiding effect of the first and second sliding grooves ensures the accuracy of the installation direction, avoids deviation or jamming, and significantly reduces the installation difficulty;
[0029] 2. Based on the structure where a first limiting block is provided in the direction of the first limiting part facing the first slide groove, and a second limiting block is provided in the direction of the second limiting part facing the second slide groove, both the first and second limiting blocks are located on the movement trajectory of the functional plate inserted into the slide groove. Dynamic pressure adjustment is achieved through an elastic element, ensuring that the elastic element continuously applies pressure after the functional plate is inserted, making it tightly fitted to the housing and preventing the functional plate from loosening or falling off due to vibration or external force. The functional plate maintains pressure towards the housing, and the pressure on the housing from the functional plate makes the housing fit more tightly with the internal components, ensuring leak-proof subsequent glue application. Attached Figure Description
[0030] Figure 1 This is a three-dimensional structural diagram of the present invention.
[0031] Figure 2 This is a schematic diagram of the exploded structure of this utility model.
[0032] Figure 3 This is a schematic diagram of the internal structure of the assembly gun of this utility model.
[0033] Figure 4 This is a partial enlarged view of the first and second sliding grooves of this utility model.
[0034] Figure 5 This is a schematic diagram of the side structure of this utility model.
[0035] Figure 6 This utility model Figure 5 A schematic diagram of the AA cross-sectional structure.
[0036] Figure 7 This utility model Figure 5 A schematic diagram of the BB cross-sectional structure.
[0037] The reference numerals in the attached drawings have the following meanings: 1. Housing; 11. First housing; 111. Assembly area; 112. First limiting part; 1121. First limiting block; 113. Second limiting part; 1131. Second limiting block; 114. First slide groove; 115. Second slide groove; 116. Assembly cavity; 1161. First assembly cavity; 1162. Second assembly cavity; 117. Support plate; 12. Second housing; 13. Circuit board; 2. Functional board; 3. Antenna; 4. Battery; 5. Temperature probe; 6. Assembly base; 7. Magnetic component; 8. Conductive component. Detailed Implementation
[0038] To better understand and implement this invention, the technical solutions in the embodiments of this invention will be clearly and completely described and discussed below with reference to the accompanying drawings. Obviously, what is described here is only a part of the examples of this invention, not all of them. All other embodiments obtained by those skilled in the art based on the embodiments of this invention without creative effort are within the protection scope of this invention.
[0039] To facilitate understanding of the embodiments of this utility model, further explanations and descriptions will be provided below with reference to the accompanying drawings and specific embodiments. These embodiments do not constitute a limitation on the embodiments of this utility model.
[0040] In the description of this utility model, it should be noted that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", and "outer" indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model 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 utility model.
[0041] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention pertains. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.
[0042] See Figures 1-7 This utility model discloses a temperature sensor housing, including a housing 1 and a functional plate 2. The housing 1 is provided with an assembly area 111. A first limiting part 112 and a second limiting part 113 are respectively provided on opposite sides of the assembly area 111. A first sliding groove 114 is formed between the first limiting part 112 and the housing 1, and a second sliding groove 115 is formed between the second limiting part 113 and the housing 1. The first sliding groove 114 and the second sliding groove 115 are respectively inserted into the two sides of the functional plate 2.
[0043] Specifically, the housing 1 has an assembly area 111 inside, which is the area inside the housing 1 used to install the functional board 2. A first limiting part 112 and a second limiting part 113 are respectively provided on opposite sides of the assembly area 111. A first sliding groove 114 is formed between the first limiting part 112 and the housing 1, extending along the length of the assembly area 111. A second sliding groove 115 is formed between the second limiting part 113 and the housing 1, parallel to the first sliding groove 114, together forming the installation channel for the functional board 2. The functional board 2 is inserted into the first sliding groove 114 and the second sliding groove 115 on both sides respectively. During insertion, the functional board 2 moves along the guide direction of the sliding groove until it is fully embedded in the assembly area 111. The guiding function of the sliding groove ensures accurate orientation of the functional board 2 during installation, avoiding deviation or jamming, and reducing installation difficulty. The functional board 2 can be a solar panel, display screen, control panel, or other expansion module, achieving modular installation through the sliding groove structure, enhancing the multi-functional integration capability of the equipment.
[0044] See Figure 1 and Figure 4 As shown, in some embodiments, the first limiting part 112 is provided with a first limiting block 1121 in the direction of the first slide groove 114. The first limiting block 1121 is located on the movement trajectory of the functional plate 2 inserting into the first slide groove 114, and the first limiting part 112 and / or the first limiting block 1121 are elastic members so that the functional plate 2 maintains pressure on the housing 1.
[0045] The second limiting part 113 is provided with a second limiting block 1131 facing the second slide groove 115. The second limiting block 1131 is located on the movement trajectory of the function plate 2 inserting into the second slide groove 115, and the second limiting part 113 and / or the second limiting block 1131 are elastic members so that the function plate 2 maintains pressure on the housing 1.
[0046] Specifically, the first limiting part 112 is provided with a first limiting block 1121 facing the first slide groove 114, and the first limiting block 1121 is located on the movement trajectory of the functional plate 2 inserting into the first slide groove 114. The first limiting part 112 and / or the first limiting block 1121 are elastic elements. When the functional plate 2 is inserted into the first slide groove 114, the first limiting block 1121 is deformed by pressure and generates a reverse elastic force, so that the functional plate 2 continuously applies pressure to the housing 1, ensuring that the functional plate 2 is tightly attached to the inner wall of the slide groove. The continuous pressure of the elastic element prevents the functional plate 2 from loosening and falling off due to vibration or external force. Similarly, the second limiting part 113 is provided with a second limiting block 1131 facing the second slide groove 115, and the second limiting block 1131 is located on the movement trajectory of the functional plate 2 inserting into the second slide groove 115. The second limiting part 113 and / or the second limiting block 1131 are elastic elements. The second limiting block 1131 applies pressure to the functional plate 2 through elastic deformation, working in conjunction with the first limiting block 1121 to achieve bidirectional limiting and elastic pressure fixation of the functional plate 2 within the groove. The elastic element can be made of a polymer material with elastic properties, as long as it can maintain the pressure of the functional plate 2 towards the housing 1, and is not limited here.
[0047] The functional plate 2 is inserted along the guide directions of the first slide groove 114 and the second slide groove 115 on both sides, respectively. The first limiting block 1121 and the second limiting block 1131 are compressed and deformed during insertion. After insertion, the elastic element recovers its deformation, applying continuous pressure to the functional plate 2, ensuring tight contact with the inner wall of the slide groove. This elastic pressure ensures no gaps between the functional plate 2 and the housing 1, preventing loosening due to long-term use or environmental vibration. The tight fit between the functional plate 2 and the housing 1 provides a foundation for subsequent glue application, ensuring the glue layer evenly fills the gaps and prevents dust, moisture, and other contaminants from entering the interior. The pressure of the elastic element also assists in the sealing effect after the glue layer cures, improving the equipment's protection level.
[0048] See Figure 2 and Figure 6 As shown, in some embodiments, the housing 1 has an assembly cavity 116 inside, and a partition is provided inside the assembly cavity 116. The partition is attached to the inner wall of the housing 1 and divides the assembly cavity 116 into a first assembly cavity 1161 and a second assembly cavity 1162 by the partition.
[0049] Specifically, the housing 1 has an assembly cavity 116 inside, which is a space inside the housing 1 for accommodating electronic components or functional modules. The assembly cavity 116 has a partition that fits against the inner wall of the housing 1. The partition divides the assembly cavity 116 into a first assembly cavity 1161 and a second assembly cavity 1162. The two cavities are separated by the partition, forming independent areas. Based on the structure of the first limiting block 1121 and the second limiting block 1131, the housing 1 fits more tightly with the partition, greatly reducing the gap between them. This prevents glue from flowing into the first assembly cavity 1161 during the potting process into the second assembly cavity 1162. The first assembly cavity 1161 is typically used to install sensitive electronic components such as the antenna 3 and battery 4. Its housing 1 has no structural seams in the first assembly cavity 1161. Therefore, after potting the second assembly cavity 1162, it is no longer necessary to pott the first assembly cavity 1161, ensuring that potting does not affect the signal transmission of the antenna 3. Furthermore, it facilitates the removal and analysis of electronic components such as the antenna 3 and battery 4 should a problem occur. The second assembly cavity 1162 can serve as an expansion space to accommodate other functional modules. The partition and housing 1 can be fixed by clips or screws, which are not limited here. The assembly cavity 116 is divided into a first assembly cavity 1161 and a second assembly cavity 1162, which makes the subsequent potting process more targeted, saves potting costs, and makes it easier to disassemble the temperature sensor when the temperature sensor needs to detect and analyze faults. Alternatively, the top of the housing 1 can be destructively removed, making it more convenient to detect and analyze the components inside the housing 1.
[0050] See Figure 6 As shown, in some embodiments, the second assembly cavity 1162 is provided with an adhesive layer.
[0051] Specifically, a potting layer is formed within the second assembly cavity 1162 using a potting process. Components requiring moisture protection are placed within this potting layer, ensuring their stability. Furthermore, the potting layer is only applied to the second assembly cavity 1162, making the potting process more targeted, saving on potting costs, and facilitating disassembly of the temperature sensor when it needs to detect and analyze faults. It should be noted that the potting layer is hidden in the attached drawings for better visualization of other components; in reality, the potting layer completely fills the second assembly cavity 1162.
[0052] See Figure 3 and Figure 7 As shown, in some embodiments, the housing 1 is provided with a support plate 117 in the first assembly cavity 1161. The support plate 117 is disposed along the edge of the partition, and the partition abuts against the support plate 117.
[0053] Specifically, the housing 1 is provided with a support plate 117 in the first assembly cavity 1161. The support plate 117 is arranged along the edge of the partition and tightly abuts against the edge of the partition. The tight abutment between the support plate 117 and the edge of the partition forms a physical sealing surface, preventing the potting layer from flowing into the first assembly cavity 1161 from the gap between the partition and the housing 1 during the curing process. The fitted structure can disperse the stress at the partition and the support plate 117, preventing the partition from deforming or displacing due to external forces (such as vibration or impact). The support plate 117 is arranged along the edge of the partition, and the force on the partition is dispersed through continuous support, preventing the partition from bending or breaking due to local stress concentration. The tight fit between the support plate 117 and the partition can resist external vibration or impact, preventing the partition from fretting or displacing during long-term use. For example, in industrial sites or outdoor environments, the supporting effect of the support plate 117 can effectively reduce the deformation of the partition caused by thermal expansion or mechanical stress. The fixed design of the bracket plate 117 and the partition extends the service life of the partition and reduces the risk of seal failure or component damage caused by structural loosening.
[0054] See Figure 2 , Figure 3 and Figure 7 As shown, in some embodiments, the partition is a circuit board 13.
[0055] Specifically, since the temperature sensor requires a circuit board 13, the circuit board 13 is used as a partition to separate the assembly cavity 116, thereby improving the utilization rate of the internal space of the equipment.
[0056] See Figure 1 and Figure 2 As shown, in some embodiments, the functional panel 2 is a solar panel.
[0057] Specifically, the functional panel 2 is a solar panel. The solar panel is inserted through the first groove 114 and the second groove 115 of the assembly area 111 of the housing 1. It is usually installed on the top or outside of the housing 1 to maximize the reception of sunlight, thus realizing the long-term self-powered power supply of the temperature sensor in the outdoor environment.
[0058] See Figure 1 and Figure 2 As shown, in some embodiments, the housing 1 has multiple assembly areas 111, and each assembly area 111 is provided with a first limiting part 112, a second limiting part 113 and a functional plate 2, and each functional plate 2 is correspondingly assembled in each first slide groove 114 and each second slide groove 115.
[0059] Specifically, multiple assembly areas 111 are arranged along the length or annular direction inside the housing 1. Each assembly area 111 is independently equipped with a first limiting part 112, a second limiting part 113, and a corresponding functional plate 2. The multiple assembly areas 111 are arranged sequentially along the axial direction of the housing 1 (e.g., top, middle, bottom), which is suitable for the layered installation of functional modules. The assembly areas 111 are distributed around the central axis of the housing 1, which is suitable for multi-directional functional expansion. In this embodiment, the housing 1 is hexahedral, and assembly areas 111 are provided on four sides of the hexahedron. Each assembly area 111 has a first limiting part 112 and a second limiting part 113 on its two sides, which together with the housing 1 form a first sliding groove 114 and a second sliding groove 115 for the insertion of the functional plate 2. The sliding grooves extend along the length direction of the assembly area 111 to ensure accurate orientation when the functional plate 2 is inserted, avoiding deviation or jamming. The functional plate 2 of each assembly area 111 can independently select different modules (e.g., solar panels, displays, control panels, etc.) to achieve multi-functional integration. Solar panels can also be installed on all sides to achieve solar energy utilization from multiple directions.
[0060] See Figure 2 As shown, in some embodiments, the housing 1 includes a first housing 11 and a second housing 12. One end of the first housing 11 is provided with an opening, and the second housing 12 is provided at the opening. The first limiting part 112 and the second limiting part 113 are both provided in the first housing 11.
[0061] Specifically, the housing 1 includes a first housing 11 and a second housing 12. The first housing 11 is used for assembling components. Correspondingly, the first housing 11 has an assembly area 111 inside. A first limiting part 112 and a second limiting part 113 are respectively provided on both sides of the assembly area 111. The two limiting parts and the housing 1 together form a first sliding groove 114 and a second sliding groove 115. The second housing 12 is located at the opening of the first housing 11 and is used to close the opening end of the first housing 11 to form a complete housing 1 structure.
[0062] Optionally, the second housing 12 can limit the first slide groove 114 and the second slide groove 115 near one end of the second housing 12, thereby preventing the function plate 2 from retracting. One end of the first housing 11 is provided with an opening, and the edge of the opening is fixed to the second housing 12 by means of a snap-fit or screw.
[0063] See Figure 2 As shown, in some embodiments, the first housing 11 is provided with a third limiting part in the direction away from the second housing 12. The third limiting part is located at the end of the first slide groove 114 and the second slide groove 115 away from the second housing 12, and the functional plate 2 abuts against the third limiting part.
[0064] Specifically, the third limiting part is located at the end of the first housing 11 away from the second housing 12, and at the ends of the first slide groove 114 and the second slide groove 115 away from the second housing 12. The third limiting part is aligned with the ends of the first slide groove 114 and the second slide groove 115, forming an end limiting boundary to restrict the axial movement of the functional plate 2. Combined with the limiting of the functional plate 2 by the second housing 12, the movement direction of the functional plate 2 is limited at both ends. The third limiting part can be a protrusion at the end of the first housing 11, which directly abuts against the functional plate 2; or the third limiting part can be a stepped structure, with a stepped limiting surface at the end of the first housing 11, and the functional plate 2 fits against the stepped surface after being inserted into the slide groove. No limitation is made here.
[0065] See Figure 1-7 As shown, this utility model also provides a temperature sensor, including an antenna 3, a battery 4, a temperature probe, and the aforementioned temperature sensor housing. The housing 1 has an assembly cavity 116 inside, and a partition is provided inside the assembly cavity 116. The partition is attached to the inner wall of the housing 1, and the assembly cavity 116 is divided into a first assembly cavity 1161 and a second assembly cavity 1162 by the partition. The antenna 3 is located in the first assembly cavity 1161, the battery 4 is located in the first assembly cavity 1161, and the temperature probe is located outside the housing 1.
[0066] Specifically, antenna 3 is located within the first assembly cavity 1161 for convenient signal transmission and reception. Battery 4 is embedded in the first assembly cavity 1161, facilitating moisture protection for antenna 3 and battery 4. Battery 4 can be charged via a solar panel or replenished via an external power interface (such as USB). The temperature probe is located outside the housing 1. During temperature measurement, the temperature probe can be directly attached to the temperature measurement area, or heat can be conducted to the temperature probe through other components for indirect contact; no limitation is made here.
[0067] See Figure 2 and Figure 7 As shown, in some embodiments, the partition is a circuit board 13, and the antenna 3, battery 4 and temperature probe are all electrically connected to the circuit board 13. The first assembly cavity 1161 is provided with a potting layer.
[0068] Specifically, the partition is designed as a circuit board 13 and combined with the potting layer, which significantly improves the overall performance of the temperature sensor: First, the potting layer (such as epoxy resin or silicone) fills the second assembly cavity 1162, blocking moisture, dust and corrosive gases, achieving an IP67 protection level, ensuring long-term stable operation of the equipment in outdoor and industrial environments, and preventing moisture, dust and corrosive gases from entering the first assembly cavity 1161; Second, the circuit board 13, as the core connection module, not only separates the assembly cavity 116, but also integrates the electrical connections of the antenna 3, battery 4 and temperature probe, reducing design redundancy; At the same time, the potting layer absorbs vibration and shock, disperses stress, and protects electronic components from physical damage.
[0069] See Figure 2 and Figure 6 As shown, in some embodiments, the temperature sensor also includes a mounting base 6, which is located at one end of the housing 1.
[0070] Specifically, the mounting base 6 is located at one end of the housing 1, and the mounting base 6 facilitates the installation of the temperature sensor. The mounting base 6 can be specifically designed according to the installation environment of the temperature sensor to improve the installation stability of the temperature sensor; the specific structure is not limited here.
[0071] See Figure 6 As shown, in some embodiments, a magnetic element 7 is provided on one side of the mounting base 6.
[0072] Specifically, a magnetic component 7 is provided on one side of the mounting base 6. The magnetic component 7 is attracted to the metal to which the temperature sensor is to be installed, so that the equipment can be installed quickly. The magnetic component 7 provides initial positioning when it is attracted, which facilitates installation.
[0073] See Figure 2 and Figure 3 As shown, in some embodiments, the temperature sensor further includes a conductive element 8, and the mounting base 6 is made of a conductive material. One end of the conductive element 8 is connected to the circuit board 13, and the other end is connected to the mounting base 6, so that the circuit board 13 and the mounting base 6 are at the same potential.
[0074] Specifically, the temperature sensor also includes a conductive element 8, and the mounting base 6 is made of conductive material. One end of the conductive element 8 is connected to the circuit board 13, and the other end is connected to the mounting base 6, so that the circuit board 13 and the mounting base 6 are at the same potential. This is especially important in high-voltage applications to prevent the temperature sensor from being damaged under voltage conditions.
[0075] The technical means disclosed in this utility model are not limited to those disclosed in the above embodiments, but also include technical solutions composed of any combination of the above technical features. It should be noted that those skilled in the art can make various improvements and modifications without departing from the principle of this utility model, and these improvements and modifications are also considered within the scope of protection of this utility model.
Claims
1. A temperature sensor housing, characterized in that, include: The housing (1) is provided with an assembly area (111). The housing (1) is provided with a first limiting part (112) and a second limiting part (113) on opposite sides of the assembly area (111). The first limiting part (112) and the housing (1) form a first sliding groove (114), and the second limiting part (113) and the housing (1) form a second sliding groove (115). Functional board (2), with the first slide groove (114) and the second slide groove (115) inserted into its two sides respectively.
2. The temperature sensor housing according to claim 1, characterized in that, The first limiting part (112) is provided with a first limiting block (1121) facing the first slide groove (114). The first limiting block (1121) is located on the movement trajectory of the function plate (2) inserted into the first slide groove (114). The first limiting part (112) and / or the first limiting block (1121) are elastic members so that the function plate (2) maintains pressure on the housing (1). The second limiting part (113) is provided with a second limiting block (1131) facing the second slide groove (115). The second limiting block (1131) is located on the movement trajectory of the function plate (2) inserted into the second slide groove (115). The second limiting part (113) and / or the second limiting block (1131) are elastic members so that the function plate (2) maintains pressure on the housing (1).
3. A temperature sensor housing according to claim 1, characterized in that, The housing (1) has an assembly cavity (116) inside. The assembly cavity (116) is provided with a partition. The partition is attached to the inner wall of the housing (1) and divides the assembly cavity (116) into a first assembly cavity (1161) and a second assembly cavity (1162) by the partition.
4. A temperature sensor housing according to claim 3, characterized in that, The second assembly cavity (1162) is provided with an adhesive layer.
5. A temperature sensor housing according to claim 3, characterized in that, The housing (1) has a support plate (117) in the first assembly cavity (1161), the support plate (117) is arranged along the edge of the partition, and the partition abuts against the support plate (117).
6. A temperature sensor housing according to claim 3, characterized in that, The partition is a circuit board (13).
7. A temperature sensor housing according to claim 1, characterized in that, The functional panel (2) is a solar panel.
8. A temperature sensor housing according to any one of claims 1-7, characterized in that, The housing (1) has multiple assembly areas (111), and each assembly area (111) is provided with a first limiting part (112), a second limiting part (113) and a functional plate (2), and each functional plate (2) is correspondingly assembled in each first slide groove (114) and each second slide groove (115).
9. A temperature sensor housing according to any one of claims 1-7, characterized in that, The housing (1) includes a first housing (11) and a second housing (12). One end of the first housing (11) is provided with an opening, and the second housing (12) is provided at the opening. The first limiting part (112) and the second limiting part (113) are both provided on the first housing (11).
10. A temperature sensor housing according to claim 9, characterized in that, The first housing (11) is provided with a third limiting part in the direction away from the second housing (12). The third limiting part is located at the end of the first slide groove (114) and the second slide groove (115) away from the second housing (12). The functional plate (2) abuts against the third limiting part.
11. A temperature sensor, characterized in that, include: The temperature sensor housing according to any one of claims 1-10, wherein the housing (1) has an assembly cavity (116) inside, the assembly cavity (116) is provided with a partition, the partition is fitted to the inner wall of the housing (1), and the assembly cavity (116) is divided into a first assembly cavity (1161) and a second assembly cavity (1162) by the partition. Antenna (3), wherein the antenna (3) is disposed in the first assembly cavity (1161); Battery (4), wherein the battery (4) is disposed in the first assembly cavity (1161); Temperature probe, which is located outside the housing (1).
12. A temperature sensor according to claim 11, characterized in that, The partition is a circuit board (13), the antenna (3), the battery (4) and the temperature probe are all electrically connected to the circuit board (13), and the second assembly cavity (1162) is provided with a potting layer.
13. A temperature sensor according to claim 12, characterized in that, It also includes an assembly base (6), which is located at one end of the housing (1).
14. A temperature sensor according to claim 13, characterized in that, A magnetic element (7) is provided on one side of the assembly base (6).
15. A temperature sensor according to claim 13, characterized in that, It also includes a conductive element (8), the mounting base (6) is made of conductive material, one end of the conductive element (8) is connected to the circuit board (13) and the other end is connected to the mounting base (6) so that the circuit board (13) and the mounting base (6) are at the same potential.