A simple linear industrial and mining lamp
By designing a simple linear industrial and mining lamp with various fixed structures and control components, the problems of ceiling installation compatibility and lighting effect adjustment are solved, achieving flexible installation and diverse lighting effects, and improving the flexibility of use.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHENZHEN GOLDENLUX CO LTD
- Filing Date
- 2025-09-15
- Publication Date
- 2026-07-03
AI Technical Summary
Existing linear industrial and mining lights lack adaptability to different ceiling installation environments, have insufficient ability to adjust lighting effects, and are limited in terms of structural simplification and miniaturization.
A simple linear industrial and mining light was designed, which adopts multiple fixed structure connection positions and control components, supports multiple ceiling installation methods, and has lighting effect adjustment function. It includes a variety of fixed structures and control components, such as booms, ropes, mounting brackets and ZHAGA controllers, to achieve flexible installation and lighting adjustment.
It enables flexible installation in different locations and various lighting effects, improves the adaptability of ceiling installation and lighting adjustment capabilities, has a simple structure, is easy to operate, and enhances the flexibility of use.
Smart Images

Figure CN224454500U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of lighting device technology, specifically a simple linear industrial and mining lamp. Background Technology
[0002] Linear industrial and mining lamps are commonly used lighting devices in factories, warehouses, docks, and other places that require high-brightness lighting. However, as user demands increase, the shortcomings of existing linear industrial and mining lamps have gradually become apparent.
[0003] Regarding its versatility in adapting to ceiling installation in different application environments, a single linear industrial light typically only fits one type of ceiling installation structure. When the ceiling environment of a site cannot meet the basic requirements for installation, a different type of linear industrial light with a different ceiling installation structure needs to be installed. Therefore, the ability of linear industrial lights to adapt to different application environments remains a limitation. Furthermore, since different users have varying needs for adjusting lighting effects such as brightness and color temperature, existing linear industrial lights lack optimization for their lighting effect adjustment structures, resulting in insufficient ability to accommodate different lighting effects. Additionally, the simplification of the linear industrial light's structure is still insufficient, hindering cost reduction and miniaturization. Utility Model Content
[0004] To address the technical deficiencies in the background technology, this utility model proposes a simplified linear industrial and mining lamp, which solves the aforementioned technical problems and meets practical needs. The specific technical solution is as follows:
[0005] A simple linear industrial and mining lamp includes a lamp housing with several heat dissipation fins arranged in a straight line along its length. Each end of the heat dissipation fins along the length of the lamp housing has a first connecting portion, and the end of the lamp housing in the width direction has a second connecting portion. The first or second connecting portion is connected to a fixing structure. A third mounting portion is located in the middle of the lamp housing, and a power supply box is fixedly connected to the third mounting portion. A mounting groove is located on the end face of the lamp housing away from the third mounting portion. A light source PCB is located within the mounting groove, and several LED beads are embedded on the surface of the light source PCB. A light-transmitting plate is fixedly connected to the mounting groove on the outer side of each LED bead. Control components are distributed within the power supply box and the light-transmitting plate.
[0006] As a further embodiment of the present invention, the first connecting part includes a first connecting hole and a second connecting hole. The first connecting hole is disposed on the heat dissipation fins at both ends of the lamp housing in the length direction, and the second connecting hole is disposed on the heat dissipation fins outside the first connecting hole. The fixing structure is connected to the first connecting hole and / or the second connecting hole.
[0007] As a further embodiment of the present invention, the fixing structure is a boom with an L-shaped cross-section. One end of the boom is provided with a third connecting hole that is directly opposite the first connecting hole. The boom outside the third connecting hole is provided with a fourth connecting hole with an arc-shaped cross-section that is directly opposite the second connecting hole. The end of the boom away from the third connecting hole is provided with a first waist hole.
[0008] As a further embodiment of this utility model, the fixing structure is a suspension rope and a connecting buckle. Both ends of the suspension rope are provided with loops, and the loops are fastened to the connecting buckles, which are fastened to the second connecting hole.
[0009] As a further embodiment of this utility model, the second connecting part is a fifth connecting hole, and at least two second connecting parts are provided at the end of the lamp housing in the width direction. The fixing structure is a mounting bracket, and one end of the mounting bracket is fixed to the lamp housing by connecting to the fifth connecting hole through a connector.
[0010] As a further embodiment of this utility model, the mounting frame includes a first frame and a second frame. One end of the first frame is provided with at least two sixth connecting holes that are directly opposite the fifth connecting hole. Both sides of the other end of the first frame are provided with seventh connecting holes. The wall surface of the first frame outside the seventh connecting holes is provided with a plurality of semi-circularly distributed eighth connecting holes. Both sides of one end of the second frame are provided with ninth connecting holes. The wall surface of the second frame outside the ninth connecting holes is provided with a tenth connecting hole. The other end of the second frame is provided with at least two second waist holes. The wall surface of the second frame located between the two second waist holes is provided with an eleventh connecting hole.
[0011] As a further embodiment of this utility model, the power supply box is provided with a power supply fixedly connected to the lamp housing, and the space outside the power supply box is provided with a control PCB fixedly connected to the inner wall of the power supply box. The control component includes a DIP switch, the control PCB is provided with at least one DIP switch, and the outer wall of the power supply box of the DIP switch is provided with a mating hole for mating with a sealing plug.
[0012] As a further embodiment of this utility model, the control component also includes a ZHAGA controller located in the inner space of the light-transmitting plate. The ZHAGA controller is fixedly connected to the light source PCB. Both the light source PCB and the lamp housing wall outside the light source PCB are provided with through holes, and the ZHAGA controller is directly opposite the through holes.
[0013] As a further embodiment of this utility model, the power box has a plurality of wiring terminals on the outer wall of the power supply, and the outer side of the wiring terminals is connected by a connecting rope to a sealing cap for sealing the wiring terminals.
[0014] As a further embodiment of this utility model, a breather is provided on the wall of the power supply box located on the outside of the power supply.
[0015] The beneficial effects of this utility model are as follows: This linear industrial and mining lamp has multiple connection positions for the fixed structure to connect to the lamp housing for ceiling installation, and the fixed structure also has various structural types. This allows the linear industrial and mining lamp to select the appropriate fixed structure to connect to the lamp housing according to the actual ceiling installation needs of the site, thus achieving different forms of ceiling installation. This enables it to be installed and used in different usage scenarios, and the lighting effect can be adjusted to meet the needs of different sites and users. It is stable in operation, convenient to operate, and has a simple structure. The assembly and installation operations of the lamp are simple, and it offers high flexibility in use. Attached Figure Description
[0016] Figure 1 This is a schematic diagram of the structure of the first type of linear industrial and mining lamp.
[0017] Figure 2 This is a schematic diagram of the fixed structure in the first type of linear industrial and mining lamp.
[0018] Figure 3 This is a schematic diagram of the structure of the second type of linear industrial and mining lamp.
[0019] Figure 4 This is a schematic diagram of the fixed structure in the second type of linear industrial and mining lamp.
[0020] Figure 5 This is a schematic diagram of the structure of the third type of linear industrial and mining lamp.
[0021] Figure 6 This is a schematic diagram of the fixed structure in the third type of linear industrial and mining lamp.
[0022] Figure 7 This is a schematic diagram of the internal structure of the power supply box.
[0023] Figure 8 A schematic diagram showing the DIP switch located inside the power supply box.
[0024] Figure 9 This is a schematic diagram of the ZHAGA controller.
[0025] Figure 10 This is a schematic diagram of the power supply box.
[0026] In the diagram, 1. Lamp housing; 12. Heat dissipation fins; 13. Mounting groove; 14. First connecting part; 141. First connecting hole; 142. Second connecting hole; 15. Second connecting part; 151. Fifth connecting hole; 16. Third mounting part; 2. Fixing structure; 21. Boom; 211. Third connecting hole; 212. Fourth connecting hole; 213. First waist hole; 22. Lifting rope; 23. Connecting buckle; 24. Collar; 25. Mounting bracket; 251. First frame; 2511. Sixth connecting hole; 2512. Seventh connecting hole; 2513, Eighth connecting hole; 252, Second frame; 2521, Ninth connecting hole; 2522, Tenth connecting hole; 2523, Second waist hole; 2524, Eleventh connecting hole; 3, Power supply box; 31, Power supply; 32, Mating hole; 321, Sealing plug; 33, Wiring terminal; 331, Sealing cover; 34, Breather; 4, Light source PCB; 41, LED beads; 5, Light-transmitting plate; 6, Control components; 61, Control PCB; 62, DIP switch; 63, ZHAGA controller; 7, Through hole. Detailed Implementation
[0027] The embodiments of this utility model will be described below with reference to the accompanying drawings and related examples:
[0028] This utility model discloses a simple linear industrial and mining lamp, such as Figures 1-10 As shown, the lamp housing 1 includes a lamp housing 1 with several heat dissipation fins 12 arranged in a straight line along its length. Each heat dissipation fin 12 at both ends of the lamp housing 1 along its length has a first connecting portion 14. The lamp housing 1 has a second connecting portion 15 at its width end. A fixing structure 2 is connected to either the first connecting portion 14 or the second connecting portion 15. A third mounting portion 16 is provided in the middle of the lamp housing 1. A power supply box 3 is fixedly connected to the third mounting portion 16. A mounting groove 13 is provided on the end face of the lamp housing 1 away from the third mounting portion 16. A light source PCB 4 is provided within the mounting groove 13. Several LED beads 41 are embedded on the surface of the light source PCB 4. A light-transmitting plate 5 is fixedly connected to the mounting groove 13 on the outer side of each LED bead 41. Control components 6 are distributed within the power supply box 3 and the light-transmitting plate 5.
[0029] It should be noted that the first connecting part 14 and the second connecting part 15 in this linear mining lamp provide connection positions for the fixing structure 2 to be connected to the lamp housing 1. Moreover, the fixing structure 2 has various structural types, allowing the linear mining lamp to select the corresponding fixing structure 2 to connect to the first connecting part 14 or the second connecting part 15 according to the actual installation conditions of the site, so as to realize different forms of ceiling installation of the linear mining lamp and enable it to be installed and used in different occasions. The control component 6 not only enables the linear mining lamp to work stably, but also adjusts the working state of the LED beads 41 in the linear mining lamp, thereby controlling the lighting effect to meet the needs of different sites and users, and is easy to operate. In addition, the linear mining lamp has a simple structure, and the assembly and installation operations during use are simple, with high flexibility in use.
[0030] It needs to be further explained that, such as Figures 1-4 As shown, the first connecting part 14 includes a first connecting hole 141 and a second connecting hole 142. The first connecting hole 141 is disposed on the heat dissipation fins 12 at both ends of the lamp housing 1 in the length direction, and the second connecting hole 142 is disposed on the heat dissipation fins 12 outside the first connecting hole 141. The fixing structure 2 is connected to the first connecting hole 141 and / or the second connecting hole 142.
[0031] The first connecting hole 141 and the second connecting hole 142 on both ends of the lamp housing 1 along the length direction provide two different connection positions when connecting the fixing structure 2, thereby meeting the installation requirements of the fixing structure 2 of different structural types. This allows the lamp housing 1 to accommodate more structural types of the fixing structure 2 to be connected, thus enriching the means of ceiling installation for this linear industrial and mining lamp.
[0032] Specifically, such as Figure 1 and Figure 2 As shown, the fixed structure 2 is an L-shaped boom 21. One end of the boom 21 is provided with a third connecting hole 211 that is directly opposite the first connecting hole 141. The boom 21 outside the third connecting hole 211 is provided with a fourth connecting hole 212 that is arc-shaped and directly opposite the second connecting hole 142. The end of the boom 21 away from the third connecting hole 211 is provided with a first waist hole 213.
[0033] As one of the ceiling installation methods for this linear industrial and mining lamp, when the linear industrial and mining lamp is ceiling installed by connecting the first connecting part 14 to the hanging arm 21, after connecting the connecting parts to the corresponding first connecting hole 141 and third connecting hole 211, the connecting parts are then connected to the corresponding second connecting hole 142 and fourth connecting hole 212, thereby connecting the hanging arm 21 to the lamp housing 1. Then, the connecting parts are inserted into the wall through the first waist hole 213, so that the hanging arm 21 is connected to the wall. At this point, the ceiling installation of the linear industrial and mining lamp is completed. After the ceiling installation is completed, the part of the linear industrial and mining lamp where the lamp housing 1 is located can rotate around the central axis of the third connecting hole 211. Moreover, the structure of the fourth connecting hole 212 ensures that the connecting parts in the second connecting hole 142 and the fourth connecting hole 212 will not affect the rotation of the part of the linear industrial and mining lamp where the lamp housing 1 is located.
[0034] Specifically, such as Figure 3 and Figure 4 As shown, the fixing structure 2 consists of a suspension rope 22 and a connecting buckle 23. Both ends of the suspension rope 22 are provided with collars 24, and the collars 24 are fastened to the connecting buckles 23. The connecting buckles 23 are fastened to the second connecting hole 142.
[0035] As one of the ceiling installation methods for this linear industrial and mining lamp, when installing the linear industrial and mining lamp by connecting the first connecting part 14 to the above-mentioned fixed structure 2, firstly, fasten the connecting buckle 23 on the loops 24 at both ends of the suspension rope 22, then fasten the connecting buckle 23 at one end of the suspension rope 22 to the second connecting hole 142, so that the suspension rope 22 is connected to the lamp housing 1, and then fasten the connecting buckle 23 at the other end of the suspension rope 22 to the connecting part on the wall (not shown in the figure), thereby realizing the ceiling installation of the linear industrial and mining lamp.
[0036] It needs to be further explained that, such as Figure 5 and Figure 6 As shown, the second connecting part 15 is the fifth connecting hole 151. At least two second connecting parts 15 are provided at the end of the lamp housing 1 in the width direction. The fixing structure 2 is a mounting bracket 25. One end of the mounting bracket 25 is fixed to the lamp housing 1 by connecting it to the fifth connecting hole 151 through a connector.
[0037] As one of the ceiling installation methods for this linear industrial and mining lamp, when the linear industrial and mining lamp is ceiling installed by connecting the second connecting part 15 to the mounting bracket 25, the lamp housing 1 and the mounting bracket 25 are connected by inserting the connector into one end of the mounting bracket 25 and the fifth connecting hole 151, and then the other end of the mounting bracket 25 is fixed to the wall, thereby realizing the ceiling installation of the linear industrial and mining lamp.
[0038] Specifically, such as Figure 5 and Figure 6 As shown, the mounting frame 25 includes a first frame 251 and a second frame 252. One end of the first frame 251 is provided with at least two sixth connecting holes 2511, which are directly opposite the fifth connecting hole 151. Both sides of the other end of the first frame 251 are provided with seventh connecting holes 2512. The wall surface of the first frame 251 outside the seventh connecting holes 2512 is provided with a plurality of semi-circularly distributed eighth connecting holes 2513. Both sides of one end of the second frame 252 are provided with ninth connecting holes 2521. The wall surface of the second frame 252 outside the ninth connecting holes 2521 is provided with a tenth connecting hole 2522. The other end of the second frame 252 is provided with at least two second waist holes 2523. The wall surface of the second frame 252 located between the two second waist holes 2523 is provided with an eleventh connecting hole 2524.
[0039] In the process of connecting the mounting bracket 25 to the lamp housing 1, connectors are inserted into the fifth and sixth connecting holes 151 and 2511 to connect the first bracket 251 to the lamp housing 1. Then, the connectors are connected to the seventh and ninth connecting holes 2521 to connect the first bracket 251 to the second bracket 252. Finally, the connectors are connected to the eighth and tenth connecting holes 2513 and 2522 to fix the positions of the first bracket 251 and the second bracket 252. Finally, the connecting parts that pass through to the wall are connected to the second waist hole 2523 and the eleventh connecting hole 2524, so that the entire mounting frame 25 is connected to the wall. At this point, the linear industrial and mining lamp has been installed in the ceiling. When the connecting parts are connected to the eighth connecting hole 2513 at different positions and then connected to the tenth connecting hole 2522, the first frame 251 and the second frame 252 form a relatively inclined structure, so that the part where the lamp housing 1 is located in the linear industrial and mining lamp can be inclined to the horizontal plane, thereby adjusting the light output angle of the linear industrial and mining lamp.
[0040] It needs to be further explained that, such as Figure 7 and Figure 8 As shown, the power supply box 3 is provided with a power supply 31 fixedly connected to the lamp housing 1. The space outside the power supply 31 in the power supply box 3 is provided with a control PCB 61 fixedly connected to the inner wall of the power supply box 3. The control component 6 includes a DIP switch 62. The control PCB 61 is provided with at least one DIP switch 62. The wall surface of the power supply box 3 outside the DIP switch 62 is provided with a mating hole 32 for mating with the sealing plug 321.
[0041] The two DIP switches 62 are used to control the luminous power and color temperature of the LED beads 41 when they are working, thereby adjusting the brightness and color of the light emitted by the linear industrial and mining lamp, making the lighting effect of the linear industrial and mining lamp more diverse. When controlling the DIP switches 62, after the sealing plug 321 is removed from the mating hole 32, the inner and outer spaces of the power box 3 wall are connected to form a space for the operator to adjust the DIP switches 62, allowing the operator to adjust the DIP switches 62.
[0042] Specifically, such as Figure 7 and Figure 9 As shown, the control component 6 also includes a ZHAGA controller 63 located in the inner space of the light-transmitting plate 5. The ZHAGA controller 63 is fixedly connected to the light source PCB4. The light source PCB4 and the wall of the lamp housing 1 outside the light source PCB4 are provided with through holes 7. The ZHAGA controller 63 is directly opposite the through holes 7.
[0043] Among them, the ZHAGA controller 63 adopts the international lighting industry alliance's standardized interface specifications to solve the compatibility problem between different manufacturers' components in LED lighting systems, such as light engines, sensors, communication modules and other external components, and achieve "plug and play" interoperability. This allows the light source PCB4 to be connected to different types of control devices, which is conducive to increasing the ways to adjust the lighting effects and making the lamps more versatile in terms of application scenarios.
[0044] It needs to be further explained that, such as Figure 10 As shown, the power box 3 has several wiring terminals 33 on the wall outside the power supply 31. The wiring terminals 33 are connected to a sealing cover 331 for sealing the wiring terminals 33 by a connecting rope.
[0045] By setting multiple terminals 33 on the power supply box 3, the lines can be introduced at different locations in the power supply box 3, which facilitates the wiring operation of the power supply 31 and electrical components in the power supply box 3, and makes the wiring layout in the power supply box 3 more orderly. The sealing cover 331 can seal the terminals 33 when they are not in use.
[0046] It needs to be further explained that, such as Figure 10 As shown, the power supply box 3 has a respirator 34 on the wall outside the power supply 31.
[0047] The respirator 34 is designed to prevent the internal temperature of the power supply box 3 from becoming too high.
[0048] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.
Claims
1. A simple linear industrial and mining lamp comprising a lamp housing, characterized in that, The lamp housing has several heat dissipation fins arranged in a straight line along its length. Each heat dissipation fin at both ends of the lamp housing along its length has a first connecting portion. The lamp housing has a second connecting portion at its width end. The first or second connecting portion is connected to a fixing structure. The lamp housing has a third mounting portion in its middle. The third mounting portion is fixedly connected to a power supply box. The end face of the lamp housing away from the third mounting portion has a mounting groove. The mounting groove contains a light source PCB. Several LED beads are embedded on the surface of the light source PCB. A light-transmitting plate is fixedly connected to the mounting groove on the outside of the LED beads. Control components are distributed in the power supply box and the light-transmitting plate.
2. A luminaire according to claim 1, characterised in that The first connecting part includes a first connecting hole and a second connecting hole. The first connecting hole is disposed on the heat dissipation fins at both ends of the lamp housing in the length direction, and the second connecting hole is disposed on the heat dissipation fins outside the first connecting hole. The fixing structure is connected to the first connecting hole and / or the second connecting hole.
3. A luminaire according to claim 2, characterised in that The fixed structure is an L-shaped boom. One end of the boom is provided with a third connecting hole that is directly opposite the first connecting hole. The boom outside the third connecting hole is provided with a fourth connecting hole that is arc-shaped and directly opposite the second connecting hole. The end of the boom away from the third connecting hole is provided with a first waist hole.
4. A luminaire according to claim 2, characterised in that The fixing structure consists of a suspension rope and a connecting buckle. Both ends of the suspension rope are provided with loops, and the loops are fastened to the connecting buckles, which are fastened to the second connecting holes.
5. A luminaire according to claim 1, characterised in that The second connecting part is the fifth connecting hole. At least two second connecting parts are provided at the end of the lamp housing in the width direction. The fixing structure is a mounting bracket. One end of the mounting bracket is fixed to the lamp housing by connecting it to the fifth connecting hole through a connector.
6. The industrial and mining lamp according to claim 5, characterized in that, The mounting frame includes a first frame and a second frame. One end of the first frame is provided with at least two sixth connecting holes that are directly opposite the fifth connecting hole. Both sides of the other end of the first frame are provided with seventh connecting holes. The wall surface of the first frame outside the seventh connecting holes is provided with a plurality of semi-circularly distributed eighth connecting holes. Both sides of one end of the second frame are provided with ninth connecting holes. The wall surface of the second frame outside the ninth connecting holes is provided with a tenth connecting hole. The other end of the second frame is provided with at least two second waist holes. The wall surface of the second frame located between the two second waist holes is provided with an eleventh connecting hole.
7. A luminaire according to claim 1, characterised in that The power supply box contains a power supply fixedly connected to the lamp housing. The space outside the power supply box contains a control PCB fixedly connected to the inner wall of the power supply box. The control component includes a DIP switch. The control PCB has at least one DIP switch. The outer wall of the power supply box of the DIP switch has a mating hole for mating with a sealing plug.
8. A luminaire according to claim 7, characterised in that The control component also includes a ZHAGA controller located in the inner space of the light-transmitting plate. The ZHAGA controller is fixedly connected to the light source PCB. Both the light source PCB and the lamp housing wall outside the light source PCB are provided with through holes. The ZHAGA controller is directly opposite the through holes.
9. A luminaire according to claim 1, characterised in that The power box has several wiring terminals on the outer wall of the power supply, and the outer side of the wiring terminals is connected to a sealing cap for sealing the wiring terminals by a connecting rope.
10. A luminaire as defined in claim 1, characterized by The power supply box has a breather installed on the outer wall of the power supply.