CN111432521A

CN111432521A - Induction splicing lamp

Info

Publication number: CN111432521A
Application number: CN202010342377.0A
Authority: CN
Inventors: 不公告发明人
Original assignee: Shenzhen Topband Co Ltd
Current assignee: Shenzhen Topband Co Ltd
Priority date: 2020-04-27
Filing date: 2020-04-27
Publication date: 2020-07-17

Abstract

The invention relates to an induction splicing lamp, which comprises: the lamp comprises a fixed structure, a lamp module and an inductive switch module; each lamp module comprises a first connecting end, a second connecting end, a first switch and a lighting circuit, wherein the first switch is respectively connected with the first connecting end, the second connecting end and the lighting circuit; each induction switch module comprises a third connecting end, a fourth connecting end, an induction unit and a second switch, the second switch is respectively connected with the third connecting end and the fourth connecting end, and the induction unit is connected with the second switch and the third connecting end and used for driving the second switch to be switched on or switched off; the lamp module and the induction module are respectively arranged on the fixed structure, the first connecting end and the third connecting end are respectively connected with the adjacent first connecting end and/or the adjacent third connecting end, any first connecting end is connected with a power supply input, and the second connecting end and the fourth connecting end are respectively connected with the adjacent second connecting end and/or the adjacent fourth connecting end. The invention can increase the induction range of the lamp, is more convenient to operate and improves the use experience of users.

Description

Induction splicing lamp

Technical Field

The invention relates to the technical field of illumination, in particular to an induction splicing lamp.

Background

Generally, in lamp control, a lamp is controlled by an inductor. Even during the process of splicing a plurality of lamps, the existing circuit of the lamp control circuit generally adopts one inductor to control all the lamps spliced by the lamp control circuit due to the power supply of the inductor. In work engineering, the sensor control is often relied on only. Through a sensor control, its response scope is little, and to the large-scale concatenation lamps and lanterns that adopt at present, in its use, can appear being difficult to the response, the use scene is single.

Disclosure of Invention

The technical problem to be solved by the present invention is to provide an induction splicing lamp, aiming at some technical defects in the prior art.

The technical scheme adopted by the invention for solving the technical problems is as follows: constructing an induction splicing luminaire comprising: the lamp comprises a fixed structure, a first number of lamp modules and a second number of induction switch modules;

each lamp module comprises a first connecting end, a second connecting end, a first switch and a lighting circuit, wherein the first end of the first switch is connected with the first connecting end, and the second end of the first switch is connected with the second connecting end and the lighting circuit;

each induction switch module comprises a third connecting end, a fourth connecting end, an induction unit and a second switch, wherein the first end of the second switch is connected with the third connecting end, the second end of the second switch is connected with the fourth connecting end, and the induction unit is connected with the second switch and the third connecting end and used for driving the second switch to be switched on or switched off;

the lamp module and the sensing module are arranged on the fixed structure according to a preset rule, the first connecting end and the third connecting end are respectively connected with the adjacent first connecting end and/or the adjacent third connecting end, the first connecting end is connected with a power supply input through any one of the first connecting ends, and the second connecting end and the fourth connecting end are respectively connected with the adjacent second connecting end and/or the adjacent fourth connecting end.

Preferably, at least one lamp module is arranged between every two induction switch modules.

Preferably, the second switch includes a first relay, the first relay includes a first coil and a first contact, the first coil is connected to the sensing unit, a first end of the first contact is connected to the third connection terminal, and a second end of the first contact is connected to the fourth connection terminal.

Preferably, each of the first connection ends includes a first input end and a first output end, each of the second connection ends includes a second input end and a second output end, each of the third connection ends includes a third input end and a third output end, and/or each of the fourth connection ends includes a fourth input end and a fourth output end;

the first input end and the third input end are respectively connected with the adjacent first output end, the adjacent third output end or the power supply input;

the second input end and the fourth input end are respectively connected with the adjacent second output end or fourth output end;

the first output end and the third output end are respectively connected with the adjacent first input end or the third input end;

the second output end and the fourth output end are respectively connected with the adjacent second input end or the fourth input end.

Preferably, in each of the lamp modules, the first input terminal is in conduction connection with the first output terminal, and/or the second input terminal is in conduction connection with the second output terminal.

Preferably, in each of the inductive switch modules, the third input terminal is conductively connected to the third output terminal, and/or the fourth input terminal is conductively connected to the fourth output terminal.

Preferably, each of the inductive switch modules further includes a third switch connected to the inductive unit and driven to turn on or off by the inductive unit, a first end of the third switch is connected to the fourth input end, and a second end of the third switch is connected to the fourth output end.

Preferably, the third switch includes a second relay, the second relay includes a second coil and a second contact, a first end of the second contact is connected to the fourth input terminal, and a second end of the second contact is connected to the fourth output terminal.

Preferably, the sensing unit comprises one or more of a microwave sensing unit, a PIR sensing unit and a photoelectric sensing unit.

Preferably, the lighting circuit comprises an L ED lighting circuit.

The induction splicing lamp has the following beneficial effects: the induction range of the lamp is increased, the operation is more convenient, and the use experience of a user is improved.

Drawings

The invention will be further described with reference to the accompanying drawings and examples, in which:

FIG. 1 is a logic block diagram of an embodiment of an induction splicing lamp of the present invention;

FIG. 2 is a schematic diagram of a partial circuit of an embodiment of an induction splicing lamp of the present invention;

FIG. 3 is a schematic circuit diagram of an embodiment of an induction splicing lamp of the present invention;

FIG. 4 is a logic block diagram of another embodiment of an induction splicing lamp of the present invention;

FIG. 5 is a schematic partial circuit diagram of another embodiment of an induction splicing lamp of the present invention;

fig. 6 is a schematic circuit diagram of another embodiment of an induction splicing lamp according to the invention.

Detailed Description

For a more clear understanding of the technical features, objects and effects of the present invention, embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

As shown in fig. 1, in a first embodiment of the induction splicing lamp of the present invention, the lamp includes: a fixed structure, a first number of luminaire modules 100 and a second number of inductive switch modules 200; each lamp module 100 comprises a first connection end, a second connection end, a first switch 110 and a lighting circuit 120, wherein the first end of the first switch 110 is connected with the first connection end, and the second end of the first switch 110 is connected with the second connection end and the lighting circuit 120; each inductive switch module 200 includes a third connection terminal, a fourth connection terminal, an inductive unit 220 and a second switch 210, wherein a first terminal of the second switch 210 is connected to the third connection terminal, a second terminal of the second switch 210 is connected to the fourth connection terminal, and the inductive unit 220 is connected to the second switch 210 and the third connection terminal and is used for driving the second switch 210 to be turned on or off; the lamp module 100 and the sensing module are disposed in the fixed structure according to a predetermined rule, and the first connection end and the third connection end are respectively connected to the adjacent first connection end or the third connection end, and are connected to the power input through any one of the first connection ends, and the second connection end and the fourth connection end are respectively connected to the adjacent second connection end or the fourth connection end. Specifically, the induction splicing lamp comprises a certain number of lamp modules 100 and a certain number of induction switch modules 200, and the number of each module can be configured as required. The lamp modules 100 and the inductive switch modules 200 may be arranged in any number and arrangement in a fixed configuration as desired. The lamp module 100 includes a lighting circuit 120 and a first switch 110, the lighting circuit 120 in the lamp module 100 is connected to a first connection end through the first switch 110, the first connection ends of all the lamp modules 100 are connected to each other, and are connected to a power input through any first connection end, when the first switch 110 is closed, the lamp circuit of the lamp module 100 provides a working voltage and a working current through the power input, and the lamp circuit works. When the first switch 110 is closed, the second connection terminal of the lamp module 100 is conducted with the power input. When the lamp module 100 is disposed adjacent to another lamp module 100, the second connection terminal of the lamp module 100 is connected to the second connection terminal of the adjacent lamp module 100, so that the lighting circuit 120 in the adjacent lamp module 100 is powered on. When the lamp module 100 and the inductive switch module 200 are disposed adjacent to each other, the inductive switch module 200 is connected to a power input through a third connection end thereof, and can control output of a working voltage and a working current of a fourth connection end of the inductive module through the inductive switch module 200, and can provide a working voltage and a working current to a second connection end of another lamp module 100 connected thereto through the fourth connection end of the inductive module, so that the lighting circuit 120 thereof is powered on and operated, and so on, to implement operation of the inductive splicing lamp. It will be appreciated that adjacent link ends are link ends of adjacent modules. The sensing unit 220 in the sensing switch module 200 is connected to the power input through the third connection end, that is, the power input is connected to the first connection end and the third connection end, and the lamp module 100 and the sensing switch module 200 provide the working voltage and the working current through the same power input. In one embodiment, the power input may be a mains input. When the inductive switch module 200 is controlled to operate, the first switch 110 is in an off state, the inductive unit 220 in any inductive switch module 200 triggers the second switch 210 to be turned on, at this time, the fourth connection end of the inductive switch module 200 is turned on with the power input, when the inductive switch module 200 is disposed adjacent to the lamp module 100, the fourth connection end of the inductive switch module 200 is turned on and connected with the second connection end of the adjacent lamp module 100, and the lighting circuit 120 in the lamp module 100 is powered on to operate. When the inductive switch module 200 is disposed adjacent to another inductive switch module 200, the fourth connection terminal of the inductive switch module 200 is connected to the fourth connection terminal of the another inductive module, and the fourth connection terminal of the another inductive module is provided with power input, so that the second connection terminal of the lamp module 100 connected to the fourth connection terminal supplies power, and the lighting circuit 120 is powered on. The induction splicing lamp can work in two modules, and when the induction splicing lamp is in a manual state, the induction splicing lamp can be controlled to work or not work through the connection or disconnection of the first switch 110. That is, the whole induction splicing lamp lighting operation can be controlled by the first switch 110 arranged in any one of the lamp modules 100. In the sensing state, the first switch 110 is not operated, and the second switch 210 of the sensing switch module 200 controls the lamp module 100 of the sensing splicing lamp to work, that is, the second switch 210 of any one sensing switch module 200 can control the lighting work of the sensing splicing lamp. In the process of splicing the induction switch module 200 and the lamp module 100, the position relationship can be set arbitrarily. Through the reasonable splicing position that sets up inductive switch module 200 and lamps and lanterns module 100, can increase the response scope of whole response concatenation lamps and lanterns, can make this response concatenation lamps and lanterns operation more convenient, promote user's use and experience.

In one embodiment, at least one luminaire module 100 is spaced between every two inductive switch modules 200. Generally, when the induction switch module 200 and the lamp module 100 are assembled on a fixed structure, they may be staggered according to any rule. By enabling control of the entire induction-tiled luminaire for minimal cost, one or more luminaire modules 100 may be provided spaced between two induction switch modules 200.

As shown in fig. 2 and 3, in an embodiment, the second switch 210 includes a first relay including a first coil 212 and a first contact 211, the first coil 212 is connected to the sensing unit 220, a first end of the first contact 211 is connected to the third connection terminal, and a second end of the first contact 211 is connected to the fourth connection terminal. Specifically, the second switch 210 may adopt a relay switch, a contact of the relay is a normally open contact, a coil of the relay is driven to be powered up through the sensing unit 220, the contact of the relay is closed, and the third connection end and the fourth connection end of the sensing switch module 200 are switched on, so that the fourth connection end of the sensing switch module 200 is connected with the sensing switch module 200 or the lamp module 100 corresponding to the power input for supplying power.

In one embodiment, each first connection comprises a first input 131 and a first output 132, each second connection comprises a second input 141 and a second output 142, each third connection comprises a third input 231 and a third output 232, and/or each fourth connection comprises a fourth input 241 and a fourth output 242; the first input terminal 131 and the third input terminal 231 are respectively connected to the adjacent first output terminal 132, the adjacent third output terminal 232 or the power input; the second input terminal 141 and the fourth input terminal 241 are respectively connected to the adjacent second output terminal 142 or fourth output terminal 242; the first output end 132 and the third output end 232 are respectively connected with the adjacent first input end 131 or the third input end 231; the second output terminal 142 and the fourth output terminal 242 are respectively connected to the adjacent second input terminal 141 or fourth input terminal 241. Specifically, in the splicing process, for convenience of connection, the first connection end of the lamp module 100 is provided with a first input end 131 and a first output end 132, the first input end 131 is used for connecting the corresponding connection end of the upper module, and the first output end 132 is used for connecting the corresponding connection end of the lower module. Similarly, the second connection end of the lamp module 100 is provided with a second input end 141 and a second output end 142, the second input end 141 is used for connecting the corresponding connection end of the upper module, and the second output end 142 is used for connecting the corresponding connection end of the lower module. The inductive switch module 200 is similarly configured, and a third connection end thereof is provided with a third input end 231 and a third output end 232, the third input end 231 is used to connect a corresponding connection end of an upper module, the third output end 232 is used to connect a corresponding connection end of a lower module, similarly, a fourth connection end of the inductive switch module 200 is provided with a fourth input end 241 and a fourth output end 242, the fourth input end 241 is used to connect a corresponding connection end of an upper module, and the fourth output end 242 is used to connect a corresponding connection end of a lower module. That is, adjacent here refers to adjacent modules of an upper and lower level. In one embodiment, when the lamp module 100 and the lamp module 100 are adjacently disposed, the first output end 132 of the lamp module 100 is connected to the first input end 131 of the adjacent lamp module 100, the second output end 142 of the lamp module 100 is connected to the second input end 141 of the adjacent lamp module 100, when the lamp module 100 and the inductive switch module 200 are adjacently disposed, the first output end 132 of the lamp module 100 is connected to the third input end 231 of the inductive switch module 200, and the second output end 142 of the lamp module 100 is connected to the fourth input end 241 of the inductive switch module 200. When the inductive switch module 200 is disposed adjacent to the lamp module 100, the third output end 232 of the inductive switch module 200 is connected to the first input end 131 of the lamp module 100, the fourth output end 242 of the inductive switch module 200 is connected to the second input end 141 of the lamp module 100, when the inductive switch module 200 is disposed adjacent to the inductive switch module 200, the third output end 232 of the previous inductive switch module 200 is connected to the third input end 231 of the adjacent inductive switch module 200, and the fourth output end 242 of the previous inductive switch module 200 is connected to the fourth input end 241 of the adjacent inductive switch module 200.

Optionally, in each lamp module 100, the first input end 131 is conductively connected to the first output end 132, and/or the second input end 141 is conductively connected to the second output end 142. Specifically, in order to realize the cascade power supply of the power supply, in each luminaire module 100, the first input terminal 131 and the first output terminal 132 thereof are directly connected in a conducting manner. The second input 141 and the second output 142 may also be directly connected in conduction, for example, in each light fixture module 100, the first input 131 and the first output 132 are directly connected by a wire, and the second input 141 and the second output 142 are also directly connected by a wire.

Optionally, in each inductive switch module 200, the third input terminal 231 is conductively connected to the third output terminal 232, and/or the fourth input terminal 241 is conductively connected to the fourth output terminal 242. Specifically, in order to implement the cascade power supply of the power supply, in each inductive switch module 200, the third input terminal 231 and the third output terminal 232 are directly connected in a conductive manner. The fourth input 241 and the fourth output 242 may also be directly connected in a conducting manner, for example, in each inductive switch module 200, the third input 231 and the third output 232 are directly connected by a wire, and the fourth input 241 and the fourth output 242 are also directly connected by a wire.

As shown in fig. 4, in an embodiment, each of the sensing switch modules 200 further includes a third switch 230 connected to the sensing unit 220 and driven to turn on or off by the sensing unit 220, a first end of the third switch 230 is connected to the fourth input end 241, and a second end of the third switch 230 is connected to the fourth output end 242. The third switch 230 may be disposed between the fourth input end 241 and the third output end 232 of the inductive switch module 200, and the inductive unit 220 is driven to be turned on or off, so that the lamp module 100 between the two inductive switch modules 200 closest to both sides of the inductive switch module 200 can work. According to the specific working principle, when the sensing unit 220 of any sensing switch module 200 senses to work and drive the second switch 210 to be turned on, the third switch 230 is driven to be turned on at the same time. The fourth input end 241 and the fourth output end 242 of the inductive switch module 200 are connected and connected to a power input, at this time, the second input end 141 or the second output end 142 of the lamp module 100 adjacent to the upper stage and the lower stage of the inductive switch module 200 have a power input, and at this time, the corresponding lighting circuit 120 supplies power through the power input of the second input end 141 or the second output end 142. Since the second input end 141 and the second output end 142 of the adjacent lamp module 100 are both connected in a conducting manner, at this time, the adjacent lamp module 100 is all operated to illuminate, until when one of the lamp module 100 is adjacent to another inductive switch module 200 and the inductive switch module 200 is not triggered by induction, the corresponding third switch 230 and the second switch 210 are both in an off state, the power input of the second input end 141 or the second output end 142 of the lamp module 100 cannot be connected in a conducting manner with the lamp module 100 at the other end through the fourth input end 241 or the fourth output end 242 of the inductive switch module 200, and the lamp module 100 at the other end will not emit light to operate. Especially, the light of the lamp modules 100 corresponding to the inductive switch module 200 can be flexibly controlled, so that the flexible control of the spliced lamp is realized.

As shown in fig. 5 to 6, the third switch 230 includes a second relay including a second coil and a second contact, a first end of the second contact is connected to the fourth input terminal 241, and a second end of the second contact is connected to the fourth output terminal 242. Specifically, the third switch 230 may adopt a relay switch, a contact of the relay is a normally open contact, a coil of the relay is driven to be powered up through the sensing unit 220, the contact of the relay is closed, and the fourth input end 241 and the fourth output end 242 of the induction switch module 200 are turned on, so that the fourth connection end of the induction switch module 200 is connected to the induction switch module 200 or the lamp module 100 corresponding to the power input for supplying power. In an embodiment, the same relay may be used for the first relay and the second relay, the first coil and the second coil may both be coils of the relay, and the first contact 211 and the second contact 213 may be two different contacts of the relay.

Optionally, the sensing unit 220 includes one or more of a microwave sensing unit, a PIR sensing unit, and a photoelectric sensing unit. The sensing unit 220 may specifically include a power circuit 221, a sensing circuit 222, a main control circuit 223, and a driving circuit 224, where the power circuit 221 is connected to the third connection terminal to supply power to the inside of the sensing unit 220, the main control circuit 223 is connected to the sensing circuit 222 and the driving circuit 224, the sensing circuit 222 generates a sensing signal according to the environment, the main control circuit 223 receives the sensing information to generate a control level, and the control level controls the driving circuit 224 to drive the second switch 210 or the third switch 230 to turn on or off. The sensing circuit 222 may be one or more of a microwave sensing circuit, a PIR sensing circuit, and a photo-electric sensing circuit.

Optionally, the lighting circuit 120 includes L ED lighting circuit 120, specifically, the lighting circuit 120 may employ L ED lighting circuit 120, which may specifically include a driving power supply 121 and a L ED light emitting unit connected to the driving power supply, an input of the driving power supply 121 is connected to a first connection terminal, a power input is provided through the first connection terminal, and power is output to the L ED light emitting unit, so that the L ED light emitting unit operates.

It is to be understood that the foregoing examples, while indicating the preferred embodiments of the invention, are given by way of illustration and description, and are not to be construed as limiting the scope of the invention; it should be noted that, for those skilled in the art, the above technical features can be freely combined, and several changes and modifications can be made without departing from the concept of the present invention, which all belong to the protection scope of the present invention; therefore, all equivalent changes and modifications made within the scope of the claims of the present invention should be covered by the claims of the present invention.

Claims

1. An induction splicing luminaire, comprising: the lamp comprises a fixed structure, a first number of lamp modules and a second number of induction switch modules;

2. The induction splicing lamp of claim 1, wherein at least one said lamp module is spaced between every two said induction switch modules.

3. The induction splicing luminaire of claim 1,

the second switch includes first relay, first relay includes first coil and first contact, first coil is connected induction element, the first end of first contact is connected the third link, the second end of first contact is connected the fourth link.

4. The induction splicing lamp of claim 1, wherein each of the first connection ends comprises a first input end and a first output end, each of the second connection ends comprises a second input end and a second output end, each of the third connection ends comprises a third input end and a third output end, and/or each of the fourth connection ends comprises a fourth input end and a fourth output end;

5. The induction splicing lamp of claim 4, wherein in each of the lamp modules, the first input terminal is conductively connected to the first output terminal, and/or the second input terminal is conductively connected to the second output terminal.

6. The induction splicing lamp of claim 4, wherein in each of the induction switch modules, the third input terminal is conductively connected with the third output terminal, and/or the fourth input terminal is conductively connected with the fourth output terminal.

7. The induction splicing lamp of claim 4, wherein each induction switch module further comprises a third switch connected to the induction unit and driven by the induction unit to turn on or off, a first end of the third switch is connected to the fourth input end, and a second end of the third switch is connected to the fourth output end.

8. The induction splicing luminaire of claim 7,

the third switch comprises a second relay, the second relay comprises a second coil and a second contact, the first end of the second contact is connected with the fourth input end, and the second end of the second contact is connected with the fourth output end.

9. The induction splicing lamp of claim 1, wherein the induction unit comprises one or more of a microwave induction unit, a PIR induction unit, and a photoelectric induction unit.

10. The induction splicing light fixture of claim 1, wherein said lighting circuit comprises an L ED lighting circuit.