CN220892135U - Electromagnetic induction type lamp - Google Patents

Abstract

The utility model provides an electromagnetic induction type lamp, comprising: the lamp body is provided with a first connecting part; the sensing assembly comprises a second connecting part and a sensing probe, one end of the second connecting part is connected with the sensing probe, and the other end of the second connecting part is detachably connected with the first connecting part; the first electromagnetic induction module is arranged in the first connecting part and is electrically connected with the lamp body; the second electromagnetic induction module is electrically connected with the induction probe, wherein in the state that the lamp body is connected with the circuit, the induction probe can cause the change of induction current between the first electromagnetic induction module and the second electromagnetic induction module after detecting a triggering event, and the lamp body is driven to work by detecting the change of induction current. The electromagnetic induction type lamp provided by the embodiment of the utility model is simple and reliable in assembly and low in maintenance cost.

Description

Electromagnetic induction type lamp

Technical Field

The utility model relates to the field of lamps, in particular to an electromagnetic induction type lamp.

Background

The floodlight is a lamp capable of uniformly irradiating all directions and is widely used in scenes such as billboards, highways, railway tunnels, bridges, culverts, squares, buildings and the like.

Currently, the lamps commonly used in the market are divided into two main types, namely with a sensor and without a sensor. The two types of products are suitable for different application scenes, but the lamps with the sensors become mainstream products for environmental protection and energy saving and some other reasons. Most of the application scenes of the lamp with the sensor are outdoor, but the assembly mode is complicated, so that the installation and maintenance cost is correspondingly increased.

Disclosure of utility model

In view of the above, the utility model provides an electromagnetic induction type lamp, which is simple and reliable to assemble and low in maintenance cost.

In order to solve the technical problems, the utility model adopts the following technical scheme:

An electromagnetic induction type lamp according to an embodiment of the present utility model includes:

The lamp body is provided with a first connecting part;

The sensing assembly comprises a second connecting part and a sensing probe, one end of the second connecting part is connected with the sensing probe, and the other end of the second connecting part is detachably connected with the first connecting part;

the first electromagnetic induction module is arranged in the first connecting part and is electrically connected with the lamp body;

the second electromagnetic induction module is arranged in the second connecting part and is electrically connected with the induction probe;

The induction probe can cause the first electromagnetic induction module and the second electromagnetic induction module to generate induction current change after detecting a triggering event in a state that the lamp body is connected with the circuit, and the lamp body is driven to work by detecting the induction current change.

Further, the lamp body includes:

the base shell is internally provided with a first accommodating cavity, and the back of the base shell is provided with the first connecting part;

The lamp bead plate is arranged in the first accommodating cavity;

The driving plate is arranged in the first accommodating cavity and is electrically connected with the lamp bead plate and the first electromagnetic induction module;

The reflector is arranged in the first accommodating cavity, and the bottom of the reflector is sleeved on the periphery of the lamp bead plate;

The surface frame and the light-emitting cover are jointly installed at the port of the base shell and are abutted to the peripheral edge of the reflecting cover.

Further, the lamp body further comprises a waterproof connector lug, the waterproof connector lug is mounted on the back of the base shell, and the waterproof connector lug is communicated with the inside and the outside of the base shell.

Further, the lamp body further comprises a connecting support, the connecting support is U-shaped, and two ends of the connecting support are respectively connected with two sides of the base shell in an angle-adjustable mode.

Further, the first connecting portion is formed to protrude out of a boss on the back of the base shell, a closed second accommodating cavity is formed in the boss, and the first electromagnetic induction module is arranged in the second accommodating cavity.

Further, the second connection part includes:

The connecting shell is internally provided with a third accommodating cavity, the second electromagnetic induction module is arranged in the third accommodating cavity, the bottom of the connecting shell is detachably connected with the boss, and the side wall of the connecting shell is connected with the induction probe;

The connecting cover is connected to the opening of the third accommodating cavity.

Further, the boss is cylindrical, a plurality of first grooves with intervals are sequentially formed on the side wall of the boss, a convex block is formed between every two adjacent first grooves, and a first convex edge is formed between the first grooves and the surface of the boss;

The connecting shell is cylindric, the bottom of connecting shell is formed with convex semicircular cutting ferrule, semicircular second recess has been seted up to the lower half of cutting ferrule inner wall, semicircular second chimb has been formed with to the upper half of cutting ferrule inner wall, correspond on the second chimb the third recess of vertical direction has been seted up to the lug, through the lug adaptation the third recess the adaptation of second chimb first recess and the adaptation of second recess first chimb, make the connecting shell with boss joint.

Further, the side wall of the connecting shell is connected with a third connecting part, and the induction probe is rotatably connected with the third connecting part.

Further, the inductive probe includes:

The front cover is internally provided with a fourth accommodating cavity, the top of the front cover is provided with a protruding communication port, the front end of the front cover is provided with a lens, and the rear end of the front cover is provided with an opening;

the induction module is arranged in the fourth accommodating cavity and is electrically connected with the second electromagnetic induction module;

the shaft sleeve is arranged in the communication port;

The bottom of the rotating shaft is formed into a sphere and is movably arranged in the shaft sleeve, and the top of the rotating shaft is connected with the third connecting part;

The gland is in threaded connection with the outside of the communication port and is in pressure connection with the upper half part of the sphere at the bottom of the rotating shaft;

A rear cover connected with the opening at the rear end of the front cover,

Wherein, the axle sleeve with the inside cavity of pivot is used for wearing to establish the wire.

Further, a buckle is formed at the top of the rotating shaft, a clamping groove is formed in the third connecting portion, and the rotating shaft is clamped into the clamping groove in the third connecting portion through the buckle.

The technical scheme of the utility model has at least one of the following beneficial effects:

the electromagnetic induction type lamp comprises a lamp body, an induction assembly, a first electromagnetic induction module and a second electromagnetic induction module, wherein a first connection part is arranged on the lamp body, the first electromagnetic induction module is arranged in the first connection part, the first electromagnetic induction module is electrically connected with the lamp body, the induction assembly comprises a second connection part and an induction probe, one end of the second connection part is connected with the induction probe, the other end of the second connection part is detachably connected with the first connection part, the second electromagnetic induction module is arranged in the second connection part, the second electromagnetic induction module is electrically connected with the induction probe, and under the state of an external circuit of the lamp body, namely, the electric supply, the induction probe in the induction assembly can generate induction current change between the first electromagnetic induction module and the second electromagnetic induction module after detecting a triggering event (triggered), and the lamp body can drive the lamp body to work by detecting the induction current change. According to the electromagnetic induction type lamp provided by the embodiment of the utility model, the two electromagnetic induction modules are detachably connected, so that the lamp body is driven to work through the principle of electromagnetic induction, the structure is simple and reliable to assemble, the maintenance cost is low, and the electromagnetic induction type lamp is convenient for various outdoor scenes to be widely applied.

Drawings

FIG. 1 is a perspective view of an electromagnetic induction lamp according to an embodiment of the present utility model;

fig. 2 is another perspective view of an electromagnetic induction lamp according to an embodiment of the present utility model;

FIG. 3 is a schematic diagram illustrating an assembly of a lamp body and an induction assembly of an electromagnetic induction lamp according to an embodiment of the present utility model;

fig. 4 is a schematic structural diagram of a first connection portion of a lamp body of an electromagnetic induction lamp according to an embodiment of the utility model;

Fig. 5 is a schematic structural diagram of a second connection portion of an electromagnetic induction lamp according to an embodiment of the present utility model;

fig. 6 is an exploded view of a lamp body of an electromagnetic induction lamp according to an embodiment of the present utility model;

FIG. 7 is a schematic diagram of an exploded view of an induction assembly of an electromagnetic induction lamp according to an embodiment of the present utility model;

Fig. 8 is a cross-sectional view of an induction assembly of an electromagnetic induction lamp according to an embodiment of the present utility model.

Reference numerals: 100. a lamp body; 110. a base shell;

120. A first connection portion; 121. a first groove; 122. a bump; 123. a first flange;

130. A lamp bead plate; 140. a driving plate; 150. a reflector; 160. a face frame; 170. a light-emitting cover; 180. waterproof connector lug; 190. a bracket;

200. An induction assembly; 210. a second connecting portion; 211. a connection housing; 2111. a cutting sleeve; 2112. a second groove; 2113. a second convex edge; 212. a connection cover; 213. third connecting part

220. An inductive probe; 221. a front cover; 2211. a lens; 2212. a communication port; 222. an induction module; 223. a shaft sleeve; 224. a rotating shaft; 2241. a buckle; 225. a gland; 226. a rear cover;

300. a first electromagnetic induction module; 400. and the second electromagnetic induction module.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. It will be apparent that the described embodiments are some, but not all, embodiments of the utility model. All other embodiments, which are obtained by a person skilled in the art based on the described embodiments of the utility model, fall within the scope of protection of the utility model.

Unless defined otherwise, technical or scientific terms used herein should be given the ordinary meaning as understood by one of ordinary skill in the art to which this utility model belongs. The terms "first," "second," and the like, as used herein, do not denote any order, quantity, or importance, but rather are used to distinguish one element from another. The terms "connected" or "connected," and the like, are not limited to physical or mechanical connections, but may include electrical connections, whether direct or indirect. "upper", "lower", "left", "right", etc. are used merely to indicate a relative positional relationship, which changes accordingly when the absolute position of the object to be described changes.

An electromagnetic induction type lamp according to an embodiment of the present utility model is described below in detail with reference to the accompanying drawings.

An electromagnetic induction lamp according to an embodiment of the present utility model, as shown in fig. 1, 2, 3, 6 and 7, may include: the lamp body 100, the sensing assembly 200, the first electromagnetic induction module 300, and the second electromagnetic induction module 400.

The lamp body 100 is provided with a first connection portion 120.

The sensing assembly 200 includes a second connection portion 210 and a sensing probe 220, wherein one end of the second connection portion 210 is connected to the sensing probe 220 and the other end is detachably connected to the first connection portion 120.

The first electromagnetic induction module 300 is disposed in the first connection portion 120, and the first electromagnetic induction module 120 is electrically connected to the lamp body 100.

The second electromagnetic induction module 400 is disposed in the second connection portion 210, and the second electromagnetic induction module 400 is electrically connected to the induction probe 220.

In a state that the lamp body 100 is connected to the circuit, after the sensing probe 220 detects a triggering event, a change of an induced current can be generated between the first electromagnetic induction module 300 and the second electromagnetic induction module 400, and the lamp body 100 drives the lamp body 100 to operate by detecting the change of the induced current.

That is, according to the electromagnetic induction type lamp of the embodiment of the utility model, the first connection portion 120 provided on the lamp body 100 and the second connection portion 210 provided on the induction component 200 are detachably connected, the first electromagnetic induction module 300 is provided in the first connection portion 120, the second electromagnetic induction module 400 is provided in the second connection portion 210, and after the induction probe 220 is triggered in the state that the lamp body 100 is externally connected with a power supply, an induction current can be generated between the first electromagnetic induction module 300 and the second electromagnetic induction module 400 to drive the lamp body 100 to work, the structure assembly is simple and reliable, the maintenance cost is low, and the wide application in various outdoor scenes is facilitated.

In some embodiments, as shown in fig. 3 and 6, the lamp body 100 may include: the lamp comprises a base shell 110, a lamp bead plate 130, a driving plate 140, a reflector 150, a face frame 160 and a light outlet cover 170.

Wherein, a first accommodating cavity is formed inside the base shell 110, and a first connecting portion 120 is disposed at the back of the base shell.

The lamp bead plate 130 is installed in the first accommodating cavity.

The driving plate 140 is disposed in the first accommodating cavity, and the driving plate 140 is electrically connected to the lamp bead plate 130 and the first electromagnetic induction module 300.

The reflector 150 is disposed in the first accommodating cavity, and its bottom is sleeved on the periphery of the lamp bead plate 130.

The light-emitting cover 170 is mounted at an opening inside the face frame 160, and the face frame 160 and the light-emitting cover 170 are jointly mounted at a port of the base shell 110 and abut against the peripheral edge of the light-reflecting cover 150.

That is, the components of the lamp body 100 such as the lamp bead plate 130, the driving plate 140, the reflector 150, the face frame 160, and the light-emitting cover 170 are sequentially mounted on the base housing 110, wherein the driving plate 140 is electrically connected with the lamp bead plate 130 and the first electromagnetic induction module 300, that is, after the induction probe 220 is triggered in a state that the driving plate 140 is externally connected with a power supply, an induction current is generated between the first electromagnetic induction module 300 and the second electromagnetic induction module 400, and the driving plate 140 drives the lamp bead plate 130 to work.

In some embodiments, as shown in fig. 3 and 6, the lamp body 100 further includes a waterproof connector lug 180, the waterproof connector lug 180 is mounted on the back of the base housing 110, and the waterproof connector lug 180 communicates the inside and the outside of the base housing 110.

That is, the waterproof connector lug 180 is installed at the back of the base housing 110 of the lamp body 100 for the driving board 130 to be connected to the power source through the wire outwards, improving the safety of the electricity consumption of the connection.

In some embodiments, as shown in fig. 3, the lamp body 100 further includes a connection bracket 190, the connection bracket 190 has a U shape, and two ends of the connection bracket 190 are respectively and angularly adjustably connected to two sides of the base housing 110.

Therefore, the base shell 110 is connected with the connecting support 190 with adjustable angle, so that the irradiation angle can be adjusted to meet the installation and use requirements of the lamp body 100, and the applicability of the lamp is improved.

In some embodiments, as shown in fig. 3, the first connection portion 120 is formed as a boss protruding from the back of the base housing 110, and a closed second accommodating cavity is formed inside the boss, and the first electromagnetic induction module 300 is disposed in the second accommodating cavity.

That is, a protruding boss is provided at the back of the base case 110 to form an independent space for installing the first electromagnetic induction module 300, so as to protect the first electromagnetic induction module 300 and not occupy the space inside the base case 110.

In some embodiments, as shown in fig. 3 and 7, the second connection part 210 may include: a connection housing 211 and a connection cover 212.

Wherein, a third accommodating cavity is formed inside the connection housing 211, the second electromagnetic induction module 400 is disposed in the third accommodating cavity, the bottom of the connection housing 211 is detachably connected with the boss, and the side wall of the connection housing 211 is connected with the induction probe 220.

The connection cover 212 is connected to the opening of the third receiving cavity.

That is, the second connection part 210 includes a connection housing 211 formed with a third receiving cavity and a connection cover 212 connected at an opening of the third receiving cavity, the second electromagnetic induction module 400 is installed in the third receiving cavity, and detachably connected with the boss through the bottom of the connection housing 211 (i.e., the detachable connection of the second connection part 210 and the first connection part 120 is realized), and the induction probe 220 is connected to the side wall of the connection housing 211, so that the structure is simple, the assembly is convenient and reliable, and the maintenance cost is low.

In some embodiments, as shown in fig. 4 and 5, the boss (i.e., the first connecting portion 120) is cylindrical, a plurality of first grooves 121 are sequentially formed on the sidewall of the boss at intervals, a bump 122 is formed between adjacent first grooves, and a first convex edge 123 is formed between the first grooves 121 and the surface of the boss.

The connection shell 211 is cylindric, and the bottom of connection shell 211 is formed with protruding semicircle-shaped cutting ferrule 2111, and semicircular second recess 2112 has been seted up to the lower half of cutting ferrule 2111 inner wall, and semicircular second chimb 2113 has been formed with to the upper half of cutting ferrule 2111 inner wall, and the third recess 2114 of vertical direction has been seted up to corresponding lug 122 on the second chimb 2113, through lug 122 adaptation third recess 2114, second chimb 2113 adaptation first recess 121 and second recess 2112 adaptation first chimb 123 for connection shell 211 and boss joint.

Therefore, the connection between the connection shell 211 and the boss is more stable and reliable, loose separation is avoided, and the connection shell is convenient to detach and maintain and replace.

In some embodiments, as shown in fig. 5, a third connection part 213 is connected to a sidewall of the connection housing 211, and the sensing probe 220 is rotatably connected to the third connection part 213.

That is, the third connecting portion 213 is disposed on the side wall of the connecting housing 211, and the sensing probe 220 is rotatably connected to the third connecting portion 213, so that the light sensing angle of the sensing probe 220 is adjustable, and the applicability of the lamp in the open air is improved.

In some embodiments, as shown in fig. 7 and 8, the inductive probe 220 may include: front cover 221, sensing module 222, sleeve 223, spindle 224, gland 225 and back cover 226.

Wherein, a fourth accommodating cavity is formed in the front cover 221, a protruding communication port 2212 is formed at the top of the front cover 221, a lens 2211 is mounted at the front end of the front cover 221, and an opening is formed at the rear end of the front cover 221. The lens 2211 is used for transmitting light into the front cover 221, and the sensing module 222 receives the incident light to detect whether the illumination intensity reaches the triggering threshold.

The sensing module 222 is installed in the fourth accommodating cavity, and the sensing module 222 is electrically connected to the second electromagnetic sensing module 400.

The boss 223 is provided inside the communication port 2212.

The bottom of the rotation shaft 224 is formed into a sphere and movably disposed in the shaft sleeve 223, and the top of the rotation shaft 224 is connected to the third connection part 213.

The gland 225 is screwed on the outside of the communication port 2212 and is pressed against the upper half of the sphere at the bottom of the rotating shaft 224.

The rear cover 226 is connected to an opening of the rear end of the front cover 221.

Wherein, the shaft sleeve 223 and the shaft 224 are hollow for threading the lead wire.

Therefore, the sensing probe 220 is connected to the third connecting portion 213 through the rotating shaft 224, and the sensing probe 220 can rotate around the rotating shaft 224, so as to adjust the orientation angle of the lens 2211 on the front cover 221, and further adjust the angle of light sensing, so that the structure is compact and reliable, and the practicality is strong. Wherein the inner induction module 222 passes through the shaft sleeve 223 and the rotation shaft 224 by a wire to be connected with the second electromagnetic induction module 400.

In some embodiments, as shown in fig. 7 and 8, a buckle 2241 is formed at the top of the rotating shaft 224, and a slot is formed inside the third connecting portion 213, and the rotating shaft 224 is engaged with the slot in the third connecting portion 213 through the buckle 2241.

That is, the rotation shaft 224 is detachably connected with the third connection part 213 by the snap 2241 at the top thereof, thereby facilitating the installation, disassembly and maintenance of the second connection part 210 and the sensing probe 220 in the sensing assembly 200.

While the foregoing is directed to the preferred embodiments of the present utility model, it will be appreciated by those skilled in the art that various modifications and adaptations can be made without departing from the principles of the present utility model, and such modifications and adaptations are intended to be comprehended within the scope of the present utility model.

Claims (10)

1. An electromagnetic induction lamp, comprising:

The lamp body is provided with a first connecting part;

The sensing assembly comprises a second connecting part and a sensing probe, one end of the second connecting part is connected with the sensing probe, and the other end of the second connecting part is detachably connected with the first connecting part;

the first electromagnetic induction module is arranged in the first connecting part and is electrically connected with the lamp body;

the second electromagnetic induction module is arranged in the second connecting part and is electrically connected with the induction probe;

The induction probe can cause the first electromagnetic induction module and the second electromagnetic induction module to generate induction current change after detecting a triggering event in a state that the lamp body is connected with the circuit, and the lamp body is driven to work by detecting the induction current change.

2. The electromagnetic induction lamp of claim 1, wherein the lamp body comprises:

the base shell is internally provided with a first accommodating cavity, and the back of the base shell is provided with the first connecting part;

The lamp bead plate is arranged in the first accommodating cavity;

The driving plate is arranged in the first accommodating cavity and is electrically connected with the lamp bead plate and the first electromagnetic induction module;

The reflector is arranged in the first accommodating cavity, and the bottom of the reflector is sleeved on the periphery of the lamp bead plate;

The surface frame and the light-emitting cover are jointly installed at the port of the base shell and are abutted to the peripheral edge of the reflecting cover.

3. The electromagnetic induction lamp of claim 2, wherein the lamp body further comprises a waterproof connector lug mounted on the back of the base housing, the waterproof connector lug communicating the inside and outside of the base housing.

4. The electromagnetic induction lamp of claim 2, wherein the lamp body further comprises a connecting bracket, the connecting bracket is U-shaped, and two ends of the connecting bracket are respectively connected to two sides of the base shell in an angle-adjustable manner.

5. The electromagnetic induction lamp of claim 2, wherein the first connection portion is formed as a boss protruding out of the back of the base housing, and a closed second accommodating cavity is formed in the boss, and the first electromagnetic induction module is disposed in the second accommodating cavity.

6. The electromagnetic induction lamp of claim 5, wherein the second connection portion comprises:

The connecting shell is internally provided with a third accommodating cavity, the second electromagnetic induction module is arranged in the third accommodating cavity, the bottom of the connecting shell is detachably connected with the boss, and the side wall of the connecting shell is connected with the induction probe;

The connecting cover is connected to the opening of the third accommodating cavity.

7. The electromagnetic induction lamp of claim 6, wherein the boss is cylindrical, a plurality of first grooves are sequentially formed on the side wall of the boss at intervals, a convex block is formed between every two adjacent first grooves, and a first convex edge is formed between the first grooves and the boss surface;

The connecting shell is cylindric, the bottom of connecting shell is formed with convex semicircular cutting ferrule, semicircular second recess has been seted up to the lower half of cutting ferrule inner wall, semicircular second chimb has been formed with to the upper half of cutting ferrule inner wall, correspond on the second chimb the third recess of vertical direction has been seted up to the lug, through the lug adaptation the third recess the adaptation of second chimb first recess and the adaptation of second recess first chimb, make the connecting shell with boss joint.

8. The electromagnetic induction lamp of claim 6, wherein a third connection portion is connected to a side wall of the connection housing, and the induction probe is rotatably connected to the third connection portion.

9. The electromagnetic induction luminaire of claim 8, wherein said induction probe comprises:

The front cover is internally provided with a fourth accommodating cavity, the top of the front cover is provided with a protruding communication port, the front end of the front cover is provided with a lens, and the rear end of the front cover is provided with an opening;

the induction module is arranged in the fourth accommodating cavity and is electrically connected with the second electromagnetic induction module;

the shaft sleeve is arranged in the communication port;

The bottom of the rotating shaft is formed into a sphere and is movably arranged in the shaft sleeve, and the top of the rotating shaft is connected with the third connecting part;

The gland is in threaded connection with the outside of the communication port and is in pressure connection with the upper half part of the sphere at the bottom of the rotating shaft;

A rear cover connected with the opening at the rear end of the front cover,

Wherein, the axle sleeve with the inside cavity of pivot is used for wearing to establish the wire.

10. The electromagnetic induction lamp of claim 9, wherein a buckle is formed at the top of the rotating shaft, a clamping groove is formed in the third connecting portion, and the rotating shaft is clamped into the clamping groove in the third connecting portion through the buckle.