CN211406348U

CN211406348U - Intelligent lamp control system and intelligent cabinet lamp

Info

Publication number: CN211406348U
Application number: CN201922056001.9U
Authority: CN
Inventors: 魏天义; 牛衍方; 张望
Original assignee: Guangdong Dongche Intelligent Technology Co ltd
Current assignee: Guangdong Dongche Intelligent Technology Co ltd
Priority date: 2019-11-25
Filing date: 2019-11-25
Publication date: 2020-09-01
Anticipated expiration: 2029-11-25

Abstract

The utility model provides an intelligent lamp control system and an intelligent cabinet lamp, which comprise a first MCU, a human body induction circuit, a lighting circuit and a sterilization control circuit; the first MCU is respectively connected with the human body induction circuit, the lighting circuit and the sterilization control electric signal; the first MCU controls the lighting circuit to start the lighting function when the human body induction circuit detects a human body induction signal, otherwise the first MCU controls the sterilization control circuit to start the sterilization function; the sterilization control circuit comprises a second MCU and a sterilization indicating circuit, and the second MCU is in electric signal connection with the sterilization indicating circuit; the second MCU reads a radiation curve, wherein the radiation curve is a sterilization radiation rule of different sterilization radiation powers corresponding to radiation time intervals; the sterilization indicating circuit comprises at least one UV-LED lamp; the sterilization indicating circuit controls the UV-LED lamp to emit light according to the sterilization radiation rule. The utility model discloses satisfy the demand of illumination, disinfecting, and intelligence starts the illumination respectively, the function of disinfecting, sets up the germicidal radiation law and avoids disinfecting article and receive ultraviolet damage and restrain the bacterial regeneration.

Description

Intelligent lamp control system and intelligent cabinet lamp

Technical Field

The utility model relates to a house illumination, concretely relates to intelligence lamps and lanterns control system and intelligent cabinet lamp.

Background

The bactericidal lamp on the current market is provided with a special LED lamp for sterilization besides the conventional traditional bactericidal lamp, and the lamp has a sterilization effect but cannot play a role in illumination and needs to be manually switched on and off to realize control. The LED illuminating lamp is one of products with high household utilization rate, in particular to a cooking bench, a tableware cabinet, a shoe cabinet and the like. Therefore, a lamp with lighting and sterilization effects is needed to be provided, but a common sterilization lamp in the prior art is used for powering on an ultraviolet LED lamp so as to achieve the sterilization effect, but ultraviolet sterilization has certain potential safety hazards to human bodies and articles.

SUMMERY OF THE UTILITY MODEL

The application provides an intelligence lamps and lanterns control system for solve the illumination, disinfect the problem of switching control, and solve and cause the problem of the ultraviolet damage of article except that the bacterium because of radiant power is unchangeable, and the problem to the ultraviolet damage that causes the human body.

The technical scheme of the utility model as follows:

an intelligent luminaire control system comprising:

the first MCU, the human body induction circuit, the lighting circuit and the sterilization control circuit;

the first MCU is respectively connected with the human body induction circuit, the lighting circuit and the sterilization control electric signal;

the first MCU reads the sterilization cycle time and controls the lighting circuit to start the lighting function when the human body induction circuit detects a human body induction signal, otherwise, the first MCU sends a sterilization indication signal and the sterilization cycle time to the sterilization control circuit to control the sterilization control circuit to start the sterilization function;

the sterilization control circuit comprises a second MCU and a sterilization indicating circuit, and the second MCU is in electric signal connection with the sterilization indicating circuit; the sterilization indicating circuit comprises at least one UV-LED lamp;

the second MCU reads a radiation curve, wherein the radiation curve is a sterilization radiation rule of different sterilization radiation powers and corresponding radiation time intervals;

the second MCU receives the sterilization indicating signal and the sterilization cycle time and sends a corresponding sterilization working signal to the sterilization indicating circuit by combining the sterilization radiation rule;

and the sterilization indicating circuit controls the UV-LED lamp to emit light according to the sterilization working signal.

Preferably, the sterilization control circuit comprises a sterilization curve circuit; the sterilization curve circuit is electrically connected with the second MCU, and is used for setting a plurality of radiation powers and corresponding radiation time intervals so as to form a radiation curve.

Preferably, the sterilization indicating circuit comprises a potentiometer RW2 and a potentiometer RW3, and the potentiometer RW2 and the potentiometer RW3 are respectively used for setting radiation time intervals corresponding to two different radiation powers.

Preferably, the sterilization control circuit comprises a sterilization time circuit, the sterilization time circuit is electrically connected with the second MCU, and the sterilization time circuit is used for setting the minimum unit time of the radiation time interval.

Preferably, the intelligent lamp control system comprises a sterilization cycle circuit, the sterilization cycle circuit is electrically connected with the first MCU, the sterilization cycle circuit comprises a potentiometer RW1, and the sterilization cycle time is set by the potentiometer RW 1.

Preferably, the lighting circuit comprises at least one white LED lamp; the white light LED lamp is in electrical signal connection with the first MCU; the first MCU controls the white light LED lamp to emit light according to the human body induction signal detected by the human body induction circuit.

Preferably, the lighting circuit comprises a brightness control circuit and a first inductive switch; the brightness control circuit and the first inductive switch are respectively connected with the first MCU through electric signals;

the first inductive switch is used for detecting a first inductive signal and sending the first inductive signal to the first MCU;

the first MCU sends a first induction signal and a human body induction signal to the brightness control circuit; the brightness control circuit controls the illumination brightness of the current white light LED lamp according to the first sensing signal and/or the human body sensing signal.

Preferably, the white light LED lamp comprises a high color temperature white light LED lamp and a low color temperature white light LED lamp;

the lighting circuit comprises a double-color-temperature lighting switching circuit and a second inductive switch;

the first MCU is respectively connected with the double-color-temperature illumination switching circuit and the second inductive switch through electric signals;

the first inductive switch is used for detecting a second inductive signal and sending the second inductive signal to the first MCU; the first MCU sends a second induction signal to the bicolor temperature illumination switching circuit;

the double-color-temperature illumination switching circuit controls the high-color-temperature white-light LED lamp and the low-color-temperature white-light LED lamp to switch to emit light according to a first induction signal.

Preferably, the sterilization control circuit comprises a switch enabling port, the switch enabling port is respectively in electrical signal connection with the first MCU and the second MCU, and the normal switching or abnormal switching of the sterilization control circuit is controlled through the switch enabling port.

The utility model discloses another technical scheme:

the utility model provides an intelligence cabinet lamp, includes the cabinet body, still includes: a lamp panel,By usingSuch asAs described aboveThe intelligent lamp control system comprises a low color temperature white light LED lamp, a high color temperature white light LED lamp, a UV-LED lamp and a sterilization indicator lamp; the lamp plate sets firmly in inside the cabinet body, continuous and interval arrangement in proper order on the lamp plate low colour temperature white light LED lamp, high colour temperature white light LED lamp, UV-LED lamp, bactericidal indicator lamp.

Compared with the prior art, the beneficial effects of the application are that:

(1) the intelligent lighting and sterilizing functions are integrated, so that the lighting requirement is ensured, and the sterilizing effect is achieved;

(2) the intelligent switch is used for controlling, so that ultraviolet injury to a human body is avoided;

(3) the sterilization radiation-realization curve rule is set, so that the ultraviolet damage of single high radiation power to the target object is avoided, and the regeneration of bacteria is inhibited in a longer time;

(4) and different requirements on illumination brightness and color temperature are met.

Drawings

FIG. 1 is a block diagram of an integrated circuit structure for illumination and sterilization according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of the power supply of the lighting and sterilizing integrated circuit according to the embodiment of the present invention;

FIG. 3 is a schematic diagram of the sterilization control according to the embodiment of the present invention;

FIG. 4 is a schematic view of a sterilization time curve according to an embodiment of the present invention;

FIG. 5 is a flow chart of the sterilization control according to the embodiment of the present invention;

fig. 6 is a flow chart of illumination control according to an embodiment of the present invention;

FIG. 7 is a schematic diagram of a first MCU and an infrared human body induction circuit according to an embodiment of the present invention;

fig. 8 is a schematic diagram of a proximity inductive switch circuit according to an embodiment of the present invention;

fig. 9 is a schematic diagram of a two-color temperature switching and brightness control circuit according to an embodiment of the present invention;

fig. 10 is a schematic view of an arrangement structure of UV-LEDs and white LEDs according to an embodiment of the present invention.

Reference numerals:

100. an intelligent lamp control system, 110, a first MCU, 120, a lighting circuit, 130, a human body induction circuit, 122, a double-color temperature lighting switching circuit, 123, a brightness control circuit, 124, a first induction switch, 125, a second induction switch, 140, a sterilization control circuit, 141, a second MCU, 142, a sterilization indicating circuit, 143, a sterilization curve circuit, 144, a sterilization time circuit, 150, a sterilization cycle circuit, 160, a power supply circuit, 1, a lamp panel, 2, a high-color temperature white light LED lamp, 3, a low-color temperature white light LED lamp, 4, a UV-LED lamp, 5, a sterilization indicating lamp.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

An intelligent lamp control system 100 combines a lighting circuit 120 and a sterilization control circuit 140 to realize integration of an intelligent lighting function and an ultraviolet sterilization function. In the embodiment, the lighting control system and the sterilization control system are respectively provided with the first MCU110 and the second MCU141, the first MCU110 and the second MCU141 are set to be in a master-slave control relationship, the first MCU110 controls the lighting state and the switch of the lighting sterilization function, and the second MCU141 controls the sterilization state.

Embodiment mode 1

Referring to fig. 1, an intelligent luminaire control system 100 comprises: the first MCU110, the human body induction circuit 130, the lighting circuit 120, the sterilization control circuit 140 and the power supply circuit 160. The first MCU110 is respectively connected with the human body induction circuit 130, the lighting circuit 120, the sterilization control circuit 140 and the power supply circuit 160 through electric signals.

The power supply circuit 160 supplies power to the entire intelligent lamp control system 100, and in this embodiment, referring to fig. 2, the power supply circuit 160 is supplied with power by using a direct current input method.

The human body induction circuit 130 is used for detecting a human body induction signal and transmitting the human body induction signal to the first MCU 110. Of course, the human body induction signal can be collected by various methods, so that the human body induction signal can be conveniently identified, for example, the thermal imaging technology is used for identifying the human body induction signal.

In this embodiment, the human body sensing circuit 130 is an infrared human body sensing circuit. Further, the human body induction circuit 130 includes an infrared human body inductor, the infrared human body inductor is used for receiving a human body induction signal of the lamp in a preset range, and sending the human body induction signal to the first MCU110, the first MCU110 controls the lighting circuit 120 to start and control the lighting state according to the human body induction signal detected by the human body induction circuit 130, and further, the lighting brightness of the white light LED lamp is adjusted and controlled by the intensity change of the received human body induction signal by the infrared human body inductor.

The first MCU110 reads the sterilization cycle time and controls the lighting circuit to start when the human body induction circuit 130 detects a human body induction signal, otherwise, the first MCU110 sends a sterilization instruction signal and the sterilization cycle time to the sterilization control circuit to control the sterilization control circuit to start.

In this embodiment, when the human body induction circuit 130 detects a human body induction signal, the first MCU110 controls the lighting circuit 120 to turn on the lighting function, and controls the sterilization control circuit 140 to turn off the sterilization function immediately; if the human body induction circuit 130 does not detect the human body induction signal, the first MCU110 controls the lighting circuit 120 to turn off the lighting function and sends a sterilization indication signal to the sterilization control circuit 140 to control the sterilization control circuit 140 to turn on the sterilization function, thereby realizing intelligent on-off control and avoiding ultraviolet injury to the human body caused by the sterilization not being turned off when the human body induction signal is detected.

Embodiment mode 2

Referring to fig. 3-5, the sterilization control circuit 140 includes a second MCU141, a sterilization indication circuit 142; the second MCU141 and the sterilization indicating circuit 142 are electrically connected. Wherein the sterilization indication circuit 142 includes at least one UV-LED lamp for sterilization.

When the first MCU141 controls the sterilization control circuit 140 to start the sterilization function, it transmits the sterilization instruction signal 142 and the sterilization cycle time to the sterilization control circuit 140 so that the sterilization control circuit 140 starts controlling the sterilization state.

After the sterilization control circuit 140 is started, the second MCU141 reads a radiation curve, wherein, referring to fig. 4, the radiation curve is a sterilization radiation rule of different sterilization radiation powers and corresponding radiation time intervals.

The second MCU141 receives the sterilization instruction signal and the sterilization cycle time, and sends a corresponding sterilization operation signal to the sterilization instruction circuit 142 in combination with the sterilization radiation law. The sterilization indicating circuit 142 controls the UV-LED lamp to emit light according to the sterilization working signal.

Further, the intelligent lamp control system 100 includes a sterilization cycle circuit 150, the sterilization cycle circuit 150 is electrically connected to the first MCU110, the sterilization cycle circuit 140 includes a potentiometer RW1, and the sterilization cycle time is set by the potentiometer RW 1.

In order to better exert the sterilization effect, the sterilization control circuit 140 includes a sterilization curve circuit 143, and the sterilization curve circuit 143 is electrically connected to the second MCU141 for setting a plurality of radiation powers and corresponding radiation time intervals so as to form a radiation curve. In the present embodiment, the sterilization indicating circuit includes the potentiometer RW2 and the potentiometer RW3, and the potentiometer RW2 and the potentiometer RW3 are used to set the radiation time intervals corresponding to two different radiation powers, respectively. By matching with potentiometer devices with different resistance values, the sterilizing effect achieved by different radiation powers and radiation time intervals is met. In the present embodiment, the radiation time interval of the maximum radiation power in the radiation curve is adjusted by the potentiometer RW 2.

Further, referring to fig. 4, the radiation curve includes a plurality of sterilization cycles, each sterilization cycle includes a plurality of sterilization stages, in this embodiment, a pre-sterilization stage, a first sterilization stage, a second sterilization stage, and a third sterilization stage are included, and in the sterilization process, the sum of time intervals of the stages is the sterilization cycle. Each sterilization stage corresponds to different sterilization radiation power and a radiation time interval corresponding to each sterilization radiation power. The sterilization is carried out by utilizing the radiation curve, so that the ultraviolet damage to the target object caused by the invariable maximum radiation power is avoided, and meanwhile, the bacterial regeneration is inhibited in a longer time.

In this embodiment, the first MCU110 sends the second MCU141 a sterilization cycle time, which is the total time of the sterilization cycle, the sterilization cycle time is adjusted by the potentiometer RW1, and the first MCU110 reads the sterilization cycle time; after the first MCU110 reads the sterilization cycle time, the sterilization control circuit 140 is activated to transmit the sterilization cycle time to the second MCU 141.

The second MCU141 reads the sterilization radiation curve set by the sterilization curve circuit 143. Further, the time interval of the pre-sterilization stage is preparation time; during the first stage of sterilization, the second MCU141 adjusts the radiation time interval corresponding to the sterilization power of the first stage by using the potentiometer RW 2; during the second stage of sterilization, the second MC141U uses the potentiometer RW3 to adjust the radiation time interval corresponding to the sterilization power of the second stage of sterilization; in the third sterilization stage, the radiation time interval in the third sterilization stage is the sterilization cycle time, the pre-sterilization time, the first sterilization stage time, and the second sterilization stage time, so that the second MCU adjusts the radiation time interval corresponding to the third sterilization stage by using the potentiometer RW1, the potentiometer RW2, and the potentiometer RW 3. The synchronous different radiation powers correspond to different sterilization times so as to avoid the damage of the single radiation power to the sterilization target object.

Further, the sterilization control circuit comprises a sterilization time circuit, and the sterilization time circuit is electrically connected with the second MCU for setting the minimum unit time of the radiation time interval. In the present embodiment, the minimum unit time is set to 15 minutes by the sterilization time circuit, wherein the setting can be adjusted by the potentiometer RW 3.

The sterilization cycle circuit 150, the sterilization time circuit 144 and the sterilization curve circuit are provided with peripheral AD sampling circuits, and time is set according to sampled values, so that custom adjustment is facilitated.

Embodiment 3

Referring to fig. 6, an intelligent lamp control system 100 includes a lighting circuit 120, a human body induction circuit 130, a first MCU110, and a sterilization control circuit 140; the first MCU110 is respectively connected with the human body induction circuit 130, the lighting circuit 120 and the sterilization control circuit 140 through electric signals. The human body induction circuit 130 is used for detecting a human body induction signal and sending the human body induction signal to the first MCU 110;

referring to fig. 7, when the first MCU110 detects the human body sensing signal according to the human body sensing circuit, the lighting circuit is controlled to start the lighting function, otherwise, the first MCU110 controls the sterilization control circuit to start the sterilization function.

In this embodiment, the lighting circuit 120 includes at least one white LED lamp; the white light LED lamp is in electrical signal connection with the first MCU 110; the first MCU110 controls the white LED lamp to emit light according to the judgment result of the environmental signal.

Further, the method also comprises the step of controlling the light emitting state of the white light LED lamp.

Referring to fig. 8, in the present embodiment, the lighting circuit 120 includes a brightness control circuit 123 and a first inductive switch 124, and the brightness control circuit 123 and the first inductive switch 124 are respectively electrically connected to the first MCU 110; the first inductive switch 124 detects the first inductive signal and sends the first inductive signal to the first MCU 110; the first MCU110 transmits the first sensing signal and the human body sensing signal detected by the human body sensing circuit 130 to the brightness control circuit 123; the brightness control circuit 123 controls the current illumination brightness of the white light LED lamp according to the first sensing signal and/or the human body sensing signal.

Referring to fig. 9, in the present embodiment, the white LED lamp includes a high color temperature white LED and a low color temperature white LED; the lighting circuit 120 comprises a bicolor temperature lighting switching circuit 122 and a second inductive switch; the first MCU110 is respectively connected with the bicolor temperature illumination switching circuit 122 and the second inductive switch through electric signals; the first inductive switch 124 detects the second inductive signal and sends the second inductive signal to the first MCU 110; the first MCU110 sends the second sensing signal to the dual color temperature lighting switching circuit 122; the dual color temperature illumination switching circuit 122 controls the high color temperature white light LED lamp and the low color temperature white light LED lamp to switch to emit light according to the first sensing signal.

The first inductive switch 124 and the second inductive switch both use a short-distance inductive control circuit, in this example, an infrared reflective receiver is used for controlling, and the infrared reflective receiver receives an infrared reflective signal to generate an inductive signal for adjusting and controlling, so as to achieve brightness control and color temperature switching control.

In this embodiment, the short-distance sensing control circuit may adopt a sweep switch mode, a long-press off mode, and a short-press adjustment mode, so as to realize non-contact illumination state control based on the sweep switch mode, the long-press off mode, and the short-press adjustment mode.

In the embodiment, the close-range induction control circuit adjusts the color temperature in a hand scanning mode; if the scanning process is stopped, the brightness value is kept.

Further, for example, when the switch is quickly swept, the brightness is turned on and off; if the lamp stays above the detection switch for a short time, entering a program step of keeping the current value of the illumination brightness; if the lamp stays above the detection switch for a long time, the lamp enters an illumination off state, a timer is started to time, and the sterilization function circuit is started after 0.5-1 hour.

In addition, the step of the color temperature switching program can be entered when the switch is quickly swept, so that the switching between the white light with high color temperature and the white light with low color temperature can be realized.

In this embodiment, when the human body sensing circuit detects a human body sensing signal, the first MCU110 immediately controls the sterilization control circuit 140 to turn off, and triggers the brightness control circuit 123 of the white LED lamp to start the illumination function, and enters the human body perception brightness control procedure step to realize the automatic adjustment of the illumination brightness of the white LED lamp; if the first MCU110 determines that no human body induction signal is present in the environmental signal, the lighting system enters the lighting-off state and starts to perform the sterilization procedure.

In this embodiment, the first MCU110 includes a delay module; the delayed off illumination function of the illumination circuit 120 is set by the delay module, and the delayed on sterilization function of the sterilization control circuit 140 is set by the delay module. In embodiment 3, when the first MCU110 determines that there is no human body induction signal in the environmental signal, the delay module is used to control the white LED lamp in the lighting circuit 120 to be turned off in a delayed manner, and the sterilization function in the sterilization control circuit 140 is turned on in a delayed manner, in this embodiment, the first MCU110 controls the sterilization control circuit 140 to be turned on after a delay time of 0.5 to 1 hour. Wherein, in the ultraviolet sterilization work, when someone approaches, the sterilization function is immediately closed; when the person leaves, the lighting function is turned off, timing counting is restarted, and the sterilization function is waited to be turned on instead of being switched immediately or being switched to the sterilization function at the same time.

Embodiment 4

The sterilization control circuit 140 includes a switch enabling port, the switch enabling port is electrically connected to the first MCU110 and the second MCU141 respectively, and the switch enabling port controls the sterilization control circuit 140 to be normally switched on or off.

Further, after the sterilization control circuit 140 determines that no human body induction signal is in the environmental signal, a sterilization indication signal is generated and is sent to the second MCU141 in a delayed manner by using the delay module, and the sterilization indication signal passes through the switch enable port when being sent to the second MCU 141. In this embodiment, if the sterilization function needs to be turned off, the switch enable port is turned off, so that the sterilization control circuit 140 cannot be controlled to be turned on even after the first MCU110 determines that no human body induction signal is included in the environmental signal.

In this embodiment, the switch enable port is a serial data port capable of receiving the sterilization cycle time parameter and an enable port for performing the sterilization function switch control.

Application example

Referring to fig. 10, an intelligent cabinet lamp includes a cabinet body, and further includes: the intelligent LED lamp comprises a lamp panel 1 and an intelligent lamp control system, wherein the intelligent lamp control system comprises a low-color-temperature white LED lamp 2, a high-color-temperature white LED lamp 3, a UV-LED lamp 4 and a sterilization indicator lamp 5; the lamp plate 2 sets firmly inside the cabinet body, and continuous and interval arrangement low colour temperature white light LED lamp 3, high colour temperature white light LED lamp 4, UV-LED lamp 5, bactericidal indicator 6 in proper order on the lamp plate 2.

Further, in the present embodiment, the low color temperature white LED lamp 2 adopts 2750K color temperature. In this embodiment, the high color temperature white LED lamp 3 adopts 4250K color temperature. The UV-LED lamp 4 adopts an ultraviolet sterilization light source with the ultraviolet wavelength of 265nm, and the sterilization indicator lamp 5 adopts an ultraviolet sterilization indicator light source of a blue LED. The ultraviolet sterilization light source is connected with the blue LED in series to realize the starting indication of the sterilization function; the sterilization indicator lamp is used for indicating the ultraviolet sterilization working state.

It is right to have used specific individual example above the utility model discloses expound, only be used for helping to understand the utility model discloses, not be used for the restriction the utility model discloses. To the technical field of the utility model technical personnel, the foundation the utility model discloses an idea can also be made a plurality of simple deductions, warp or replacement.

Claims

1. An intelligent luminaire control system, comprising:

2. The intelligent luminaire control system of claim 1 wherein said germicidal control circuit comprises a germicidal profile circuit; the sterilization curve circuit is electrically connected with the second MCU, and is used for setting a plurality of radiation powers and corresponding radiation time intervals so as to form a radiation curve.

3. The intelligent lamp control system according to claim 2, wherein the sterilization indicating circuit comprises a potentiometer RW2 and a potentiometer RW3, and the radiation time intervals corresponding to two different radiation powers are set by the potentiometer RW2 and the potentiometer RW3 respectively.

4. The intelligent luminaire control system of claim 1 wherein the germicidal control circuit comprises a germicidal time circuit in electrical signal connection with the second MCU, the germicidal time circuit for setting a minimum unit time of a radiation time interval.

5. The intelligent lamp control system according to claim 1, wherein the intelligent lamp control system comprises a germicidal cycle circuit electrically connected to the first MCU, the germicidal cycle circuit comprising a potentiometer RW1, whereby the germicidal cycle time is set by the potentiometer RW 1.

6. The intelligent luminaire control system of claim 1, wherein the lighting circuit comprises at least one white light LED lamp; the white light LED lamp is in electrical signal connection with the first MCU; the first MCU controls the white light LED lamp to emit light according to the human body induction signal detected by the human body induction circuit.

7. The intelligent luminaire control system of claim 6, wherein the lighting circuit comprises a brightness control circuit, a first inductive switch; the brightness control circuit and the first inductive switch are respectively connected with the first MCU through electric signals;

8. The intelligent luminaire control system of claim 7 wherein the white light LED lamps comprise high color temperature white light LED lamps and low color temperature white light LED lamps;

9. The intelligent lamp control system according to claim 1, wherein the sterilization control circuit comprises a switch enabling port, the switch enabling port is electrically connected to the first MCU and the second MCU, and the switch enabling port controls normal switching or abnormal switching of the sterilization control circuit.

10. The utility model provides an intelligence cabinet lamp, includes the cabinet body, its characterized in that still includes: the intelligent lamp control system comprises a lamp panel and the intelligent lamp control system according to any one of claims 1-9, wherein the intelligent lamp control system comprises a low-color-temperature white-light LED lamp, a high-color-temperature white-light LED lamp, a UV-LED lamp and a sterilization indicator lamp; the lamp plate sets firmly in inside the cabinet body, continuous and interval arrangement in proper order on the lamp plate low colour temperature white light LED lamp, high colour temperature white light LED lamp, UV-LED lamp, bactericidal indicator lamp.