JP2021108277A - Smart lamp adjustment method and adjustment system - Google Patents

Abstract

To provide a smart lamp adjustment method and adjustment system, capable of adjusting an emission time length and/or emission luminance in real time depending on needs.SOLUTION: A smart lamp includes a sterilization illumination module. Operation modes of the sterilization illumination module include a sterilization mode, an illumination mode, and a sterilization illumination mode. The smart lamp performs rectification processing on a received power supply signal and performs current adjustment to adjust an emission time length and/or emission luminance of the sterilization illumination module. Changeover among different operation modes is performed by the sterilization illumination module depending on a user's needs.EFFECT: By improving a user's experience feeling, the problem of low flexibility and compatibility in the conventional lamp technology is solved, in which an emission time length and/or emission luminance cannot be adjusted in real time depending on needs and only illumination using single power is enabled.SELECTED DRAWING: Figure 1

Description

The present application belongs to the field of lighting control technology, and particularly relates to smart lamp adjustment methods and adjustment systems.

As people's living standards have risen, the functional requirements for electronic devices have diversified, and as a result, electronic devices have gradually changed from a single control function to a multifunctional control method, satisfying the actual demands of people in various fields. Let me. Taking a lamp as an example, first in the design process of the lamp, only the lighting can be provided, and in the process of lighting, the length of emission time and / or the emission brightness cannot be adjusted in real time according to the needs. It can be illuminated with only one power, is less flexible and compatible, and has a poor user experience. Therefore, conventional lamp technology cannot adjust the length of emission time and / or emission brightness in real time according to needs, can illuminate with only a single power, and has low flexibility and compatibility. Exists.

For this reason, the embodiments of the present application cannot adjust the length of emission time and / or emission brightness in real time according to needs, can illuminate with only a single electric power, and have low flexibility and compatibility. We provide a smart lamp adjustment method and adjustment system that aims to solve the problem.

The first aspect of the embodiment of the present application is
How to adjust the smart lamp
The smart lamp includes a germicidal lighting module, and operating modes of the germicidal lighting module include a germicidal mode, a lighting mode, and a germicidal lighting mode.
The adjustment method is
Rectifying the received power signal and
By adjusting the current of the power supply signal after rectification, the length and / or emission brightness of the sterilization illumination module can be adjusted, and the output current can be controlled within a preset range.
It provides how to adjust the smart lamp, including switching the operating mode of the germicidal lighting module.

Preferably, switching the operating mode of the germicidal lighting module employs specifically adjusting the stage of the DIP switch.
When the DIP switch is adjusted to the first stage, the operation mode of the sterilization lighting module is switched to the sterilization mode, and
When the DIP switch is adjusted to the second stage, the operation mode of the sterilization lighting module is switched to the lighting mode, and
When the DIP switch is adjusted to the third stage, the operation mode of the sterilization lighting module is switched to the sterilization lighting mode.

Preferably, switching the operating mode of the germicidal lighting module specifically employs to receive an operating command of an external device, which is
When the first operation command sent from the external device is received, the operation mode of the sterilization lighting module is switched to the sterilization mode, and
When the second operation command sent from the external device is received, the operation mode of the sterilization lighting module is switched to the lighting mode, and
Upon receiving the third operation command transmitted from the external device, the operation mode of the sterilization lighting module is switched to the sterilization lighting mode.

Preferably, switching the operating mode of the germicidal lighting module employs, specifically, switching upon receiving an induction signal, the induction signal being a touch signal, a remote control signal, a heat induction signal, and an infrared induction. Includes any one or more of the signals.

Preferably, adjusting the length of the light emission time and / or the light emission brightness of the sterilization illumination module by adjusting the current to the power supply signal after the rectification process is specifically performed.
The width of the output current is adjusted based on the first pulse signal, and the adjusted output current is output to the germicidal lighting module at the first preset time zone, and the germicidal lighting module is set in the first preset. Controlling the light to emit light at different times
The width of the output current is adjusted based on the second pulse signal, and the adjusted output current is output to the sterilization illumination module to control the sterilization illumination module to emit light at the first preset emission intensity. That and
The width of the output current is adjusted based on the third pulse signal, and the adjusted output current is output to the sterilization illumination module to control the sterilization illumination module to emit light with a second preset emission intensity. Including that.

Preferably, the output current is controlled to a preset range, and the preset range is 5A-20A.

Preferably, by adjusting the current to the power signal after the rectification process, the length and / or emission brightness of the germicidal illumination module is adjusted, and the output current is controlled to a preset range.
It further includes detecting if a power down has occurred in the germicidal lighting module.

Preferably, detecting whether a power down has occurred in the germicidal lighting module is specifically described as
Detecting if a level drop pulse appears on the power port of the germicidal lighting module,
If detected, it determines that the germicidal lighting module has been powered down, and connects to emergency power to power the germicidal lighting module.

The second aspect of the embodiment of the present application is
It ’s a smart lamp adjustment system.
The smart lamp includes a germicidal lighting module, and operating modes of the germicidal lighting module include a germicidal mode, a lighting mode, and a germicidal lighting mode.
The adjustment system
A rectifier module used to rectify the received power signal,
It is used to adjust the length and / or emission brightness of the sterilization illumination module by adjusting the current to the power supply signal after rectification, and to control the output current to a preset range. , Constant current dimming module,
Provided is a smart lamp adjustment system including an operation mode switching module, which is used to switch the operation mode of the germicidal lighting module.

Preferably, the sterilization lighting module includes a lighting module and a sterilization module.
The sterilization mode means that only the sterilization module operates, the lighting mode means that only the lighting module operates, and the sterilization lighting mode means that the sterilization module and the lighting module are operating. Refers to operating at the same time.

The above is the adjustment method and adjustment system of the smart lamp, the smart lamp includes the sterilization lighting module, the operation mode of the sterilization lighting module includes the sterilization mode, the lighting mode and the sterilization lighting mode, and the received power supply signal is rectified. Subsequently, by adjusting the current of the power supply signal after the rectification process, the length of the light emission time and / or the light emission brightness of the sterilization lighting module is adjusted, and the output current is controlled within a preset range. Switch the operation mode. It is easy to operate in this way and the effect of constant current dimming is achieved. And the sterilization lighting module can switch different operation modes according to the user's needs, is highly flexible and compatible, enhances the user's experience, and has a long emission time according to the needs in the conventional lamp technology. It solves the problem that the brightness and / or emission brightness cannot be adjusted in real time, it can only be illuminated with a single power, and it is not flexible and compatible.

In order to more clearly explain the technical solutions in the examples of the present application, the drawings used in the description of the examples will be briefly introduced below. Of course, the drawings in the following description are only a few examples of this application, and those skilled in the art will be able to obtain other drawings based on these drawings without the need for creative labor. Can be done.

It is a concrete flowchart of the adjustment method of the smart lamp provided by one Embodiment of this application. It is a specific flowchart of step S102 in the adjustment method of the smart lamp shown in FIG. It is another concrete flowchart of the adjustment method of a smart lamp provided by one Embodiment of this application. It is a block diagram of the adjustment system of the smart lamp provided by one Embodiment of this application.

In order to better clarify the purpose, technical solutions and advantages of the present application, the present application will be described in more detail with reference to the drawings and examples below. It should be understood that the specific examples described herein are for the purpose of interpreting the present application and not for limiting the present application.

It is necessary to explain that the smart lamp includes a germicidal lighting module, the operating modes of the germicidal lighting module include germicidal mode, lighting mode and germicidal lighting mode, while by adjusting the current, the length of light emission time of the germicidal lighting module and / Alternatively, the emission brightness is adjusted and the output current is controlled within a preset range, while the operation mode of the germicidal lighting module is switched by receiving a change in the ambient environment or an operation command. As a result, the effect of constant current dimming is realized, and the sterilization lighting module can switch different operation modes according to the user's needs, and the various uses of the smart lamp are enriched, improving the user's experience. .. The smart lamp can be applied to an environment where "sterilization is required and lighting is required depending on the situation" such as an application place such as a bath or a corridor.

As shown in FIG. 1, the method of adjusting the smart lamp provided by one embodiment of the present application shows only a part related to the present embodiment for convenience of explanation, and the details are as follows.

A method of adjusting a smart lamp, the smart lamp includes a sterilization lighting module, an operating mode of the sterilization lighting module includes a sterilization mode, a lighting mode, and a sterilization lighting mode, and the adjustment method includes the following.

S101: The received power supply signal is rectified.

Here, since the received power supply signal is an AC electric signal, it is necessary to rectify the AC electric signal and convert it into a DC electric signal, whereby power is supplied to the sterilization lighting module. The rectification processing method may be full-wave rectification, half-wave rectification, or may be set according to needs.

S102: By adjusting the current of the power supply signal after the rectification process, the length of the light emission time and / or the light emission brightness of the sterilization illumination module is adjusted, and the output current is controlled within a preset range.

Specifically, the current is adjusted based on the power supply signal after the rectification process, thereby adjusting the length of the light emission time and / or the light emission brightness of the sterilization illumination module. On the one hand, the on / off of the current is controlled to control the length of the light emission time of the sterilization lighting module, that is, when the output current is on, the sterilization lighting module emits light, and when the output current is off, the sterilization lighting module is Stop the light emission. On the other hand, adjusting the magnitude of the current, that is, when the output current is on, increasing the current will increase the emission brightness of the sterilization illumination module, and when the output current is off, decreasing the current will increase the sterilization illumination module. The emission brightness of is weakened.

S103: The operation mode of the sterilization lighting module is switched.

As described above, the operation mode of the sterilization lighting module includes a sterilization mode, a lighting mode, and a sterilization lighting mode, and different operation modes can be switched according to the needs of the user. For example, when it is detected that a living body exists within a preset range, the lighting mode may be switched. When the light of the surrounding environment reaches a preset threshold value and it is detected that the living body does not exist, the mode may be switched to the sterilization mode. When the light in the surrounding environment is below a preset threshold value and it is detected that there is no living body, the mode is switched to the sterilization lighting mode.

In the flowchart for realizing the adjustment method shown in FIG. 1, the received power supply signal is rectified, and then the current is adjusted to the power supply signal after the rectification processing, whereby the length of the light emission time of the sterilization lighting module and / Alternatively, the emission brightness is adjusted, and the output current is controlled within a preset range to switch the operation mode of the sterilization lighting module. It is easy to operate in this way and the effect of constant current dimming is achieved. And the sterilization lighting module can switch different operation modes according to the user's needs, is highly flexible and compatible, enhances the user's experience, and has a long emission time according to the needs in the conventional lamp technology. It solves the problem that the brightness and / or emission brightness cannot be adjusted in real time, it can only be illuminated with a single power, and it is not flexible and compatible.

In one embodiment, in step S103 of the adjustment method shown in FIG. 1, switching the operating mode of the germicidal lighting module specifically employs adjusting the stage of the DIP switch.
When the DIP switch is adjusted to the first stage, the operation mode of the sterilization lighting module is switched to the sterilization mode, and
When the DIP switch is adjusted to the second stage, the operation mode of the sterilization lighting module is switched to the lighting mode, and
When the DIP switch is adjusted to the third stage, the operation mode of the sterilization lighting module is switched to the sterilization lighting mode.

Specifically, the DIP switch has different stages, for example, the DIP switch has 3 or 4 stages, and when the DIP switch is adjusted to different stages, the DIP switch has different circuit control functions, so that the DIP switch has different stages. By changing the stage of, different circuit control functions can be achieved and different operation modes of the sterilization lighting module can be switched. Further, since it is relatively easy to switch the stage of the DIP switch, the response speed and the response accuracy of the circuit control can be greatly improved by controlling the circuit by changing the stage of the DIP switch. In the present embodiment, the DIP switch includes three stages, which are the first stage, the second stage, and the third stage, respectively, and therefore, by the stage adjustment command, the three stages of the DIP switch. Arbitrary and efficient switching between the two is possible, which enables switching between different operating modes for the germicidal lighting module. In the embodiment of the present application, the operation mode is switched by the DIP switch, the operation procedure is greatly simplified, and it is simple and practical.

Here, the "DIP switch" referred to in the present embodiment is a DIP switch of each model number in this field, and the specific model number of the DIP switch is not limited.

In one embodiment, in step S103 of the adjustment method shown in FIG. 1, switching the operation mode of the germicidal lighting module specifically employs receiving an operation command of an external device, which is:
When the first operation command sent from the external device is received, the operation mode of the sterilization lighting module is switched to the sterilization mode, and
When the second operation command sent from the external device is received, the operation mode of the sterilization lighting module is switched to the lighting mode, and
Upon receiving the third operation command transmitted from the external device, the operation mode of the sterilization lighting module is switched to the sterilization lighting mode.

Specifically, the above external device may include a mobile application, a dedicated control platform, etc., and of course, even if the effect of switching the operation mode of the sterilization lighting module is achieved by controlling the number of switches on the wall. good.

In one embodiment, in step S103 of the adjustment method shown in FIG. 1, switching the operation mode of the sterilization lighting module specifically adopts switching when a guidance signal is received, and the guidance signal is the same. , A touch signal, a remote control signal, a heat induction signal, and one or more of infrared induction signals.

FIG. 2 shows the specific process of step S102 of the smart lamp adjustment method of FIG. 1, and for convenience of explanation, only the part related to the present embodiment is shown, and the details are as follows.

In one embodiment, FIG. 2 shows the specific realization process of step S102 of the smart lamp adjustment method of FIG. 1, and by adjusting the current to the power supply signal after the rectification process, the light emission time of the sterilization lighting module Adjusting the length and / or emission brightness specifically
S1021: The width of the output current is adjusted based on the first pulse signal, and the adjusted output current is output to the sterilization illumination module at the first preset time zone, and the sterilization illumination module is output to the first advance. Controlling to emit light in the set time zone and
S1022: The width of the output current is adjusted based on the second pulse signal, and the adjusted output current is output to the sterilization illumination module so that the sterilization illumination module emits light at the first preset emission intensity. To control and
S1023: The width of the output current is adjusted based on the third pulse signal, and the adjusted output current is output to the sterilization illumination module so that the sterilization illumination module emits light at the second preset emission intensity. Including to control.

Specifically, a pulse signal including a specific circuit control function is generated, and PWM (Pulse Width Modulation) dimming is performed on the sterilization illumination module by the pulse signal having a different preset duty ratio. This gives you the flexibility to adjust the actual light emission state of the sterilization lighting module to meet your light source control needs. Therefore, in the present embodiment, the width of the output current is adjusted based on the pulse signal of a specific duty ratio, whereby the length of the emission time and / or the emission brightness of the sterilization illumination module is accurately changed. Is easy to operate and highly accurate.

Here, one can control the length of the light emission time of the sterilization illumination module by the pulse signal, and the other can control the emission brightness of the sterilization illumination module by the pulse signal.

As obtained from the above, when generating the first pulse signal, the second pulse signal, or the third pulse signal, respectively, the length of the light emission time and / or the light emission brightness of the sterilization illumination module is determined in real time. It can be adjusted, the light emission state of the sterilization lighting module can be changed flexibly, and the dimming control efficiency of the sterilization lighting module can be guaranteed. Therefore, in the present embodiment, the sterilization illumination module is dynamically dimmed in all directions in relation to the first pulse signal, the second pulse signal, and the third pulse signal, and the sterilization illumination module is dimmed. Improve control efficiency.

On the other hand, the output current is controlled to a preset range, and the preset range is 5A-20A, thereby achieving the effect of constant current dimming. Also, at an output current of 5A-20A, the emission brightness of the germicidal lighting module is the most comfortable and the user experience is better.

As shown in FIG. 3, the other specific implementation process of the smart lamp adjustment method provided by one embodiment of the present application is shown only in a portion related to the present embodiment for convenience of explanation. The details are as follows.

On top of the process of implementing the adjustment method shown in FIG. 1, before step S102,
S104: Further includes detecting whether or not a power down has occurred in the germicidal lighting module.

Specifically, since the adjustment process is performed on the smart lamp, it is necessary to ensure that the sterilization lighting module does not power down, so that the adjustment method can be smoothly executed. Therefore, step S104 is provided before step S102 to detect whether or not the sterilization lighting module has been powered down, and the sterilization lighting module is powered down, so that the complete adjustment method cannot be executed.

In one embodiment, in step S104 of the adjustment method described above, detecting whether or not a power down has occurred in the germicidal lighting module can be done.
S1041, including detecting whether or not a level drop pulse appears at the power port of the germicidal lighting module.

Here, the sterilization lighting module is connected to external power via a power port, thereby realizing its own power supply stability and power supply safety. In the process of connecting the sterilization lighting module to electric power through the power port, the sterilization lighting module was powered down by detecting whether or not a level drop pulse appeared in the electric power input to the sterilization lighting module. Determine whether or not it is accurate and efficient. Therefore, in the present embodiment, by inspecting the voltage level fluctuation state of the power port of the sterilization lighting module, the actual power-down situation of the sterilization lighting module can be accurately determined, and the power-down detection step of the sterilization lighting module is performed. The control flow is simplified.

S1042: When it is detected that a level drop pulse appears in the power port of the sterilization lighting module, it is determined that the sterilization lighting module has been powered down, and the sterilization lighting module is connected to the emergency power to supply power to the sterilization lighting module.

S1043: When it is detected that a level drop pulse appears in the power port of the sterilization lighting module, it is determined that the power down has not occurred in the sterilization lighting module.

If a level drop pulse appears in the power port of the sterilization lighting module, it means that the sterilization lighting module is disconnecting external power, and at this time, emergency power must be activated to supply the sterilization lighting module. , The sterilization lighting module emits light during the power cut delay. If the level of the power port of the sterilization lighting module is always maintained stable, the sterilization lighting module is supplied by external power, the sterilization lighting module has not been powered down, and the sterilization lighting module is stable. It means that it can emit a light source. As an example, when the power port of the germicidal lighting module is connected to a high level power of 3.3V, the germicidal lighting module emits light by external power, which means that the power port of the germicidal lighting module is in a high level state. .. If a falling pulse from 3.3V to 0V is detected in the power port of the sterilization lighting module, it means that the sterilization lighting module has been powered down. By detecting the level fluctuation of the power port of the sterilization lighting module, the function of detecting the power-down incident can be accurately performed.

As shown in FIG. 4, the structure of the smart lamp adjustment system provided by one embodiment of the present application shows only the parts related to the present embodiment for convenience of explanation, and the details are as follows. be.

It ’s a smart lamp adjustment system.
The smart lamp includes a germicidal lighting module, and the operating modes of the germicidal lighting module include a germicidal mode, a lighting mode, and a germicidal lighting mode.
The above adjustment system
The rectifying module 100, which is used to rectify the received power signal,
Used to adjust the length and / or emission brightness of the sterilization illumination module by adjusting the current to the rectified power signal, and to control the output current to a preset range. Current dimming module 200 and
Includes an operation mode switching module 300, which is used to switch the operation mode of the germicidal lighting module.

Specifically, the sterilization lighting module described above includes a lighting module and a sterilization module.
The sterilization mode means that only the sterilization module operates, the lighting mode means that only the lighting module operates, and the sterilization lighting mode means that the sterilization module and the lighting module operate at the same time. Point to.

From the above, the present application provides a smart lamp adjustment method and adjustment system, the smart lamp includes a sterilization lighting module, the operation mode of the sterilization lighting module includes a sterilization mode, a lighting mode and a sterilization lighting mode, and a received power supply. By rectifying the signal and then adjusting the current to the rectified power supply signal, the length and / or emission brightness of the sterilization illumination module is adjusted and the output current is controlled within a preset range. Then, switch the operation mode of the sterilization lighting module. It is easy to operate in this way and the effect of constant current dimming is achieved. And the sterilization lighting module can switch different operation modes according to the user's needs, is highly flexible and compatible, enhances the user's experience, and has a long emission time according to the needs in the conventional lamp technology. It solves the problem that the brightness and / or emission brightness cannot be adjusted in real time, it can only be illuminated with a single power, and it is not flexible and compatible.

Various embodiments have been described herein for different devices, circuits, devices, systems, and / or methods. Various specific details have been provided for a complete understanding of the overall configuration, function, manufacture and use of embodiments as described in the specification and shown in the drawings. However, those skilled in the art will appreciate that embodiments can be implemented without such specific details. In other embodiments, well-known behaviors, components and elements have been described in detail to avoid comprehension of the embodiments in the specification. For those skilled in the art, the present specification and the illustrated embodiments are non-limiting examples, and the particular structural and functional details disclosed herein are representative and not necessarily the scope of the embodiments. You will understand that it is not a limitation.

Throughout the instructions, references such as "various embodiments," "in embodiments," "one embodiment," or "execution" have at least one particular feature, structure, or characteristic that describes an embodiment. It means that it is included in the form. Therefore, the appearance of appropriate locations throughout the description, such as the terms "in various embodiments," "in some embodiments," "in one embodiment," or "in embodiments," does not necessarily mean the same embodiment. Does not mean. Also, certain features, structures or properties can be combined in any suitable way in one or more embodiments. Thus, a particular feature, structure or property indicated or described with respect to one embodiment may be combined in whole or in part with the feature, structure or property of one or more other embodiments. We do not assume that the combination is not a constraint on whether it is logical or functional. Any direction reference (eg plus, minus, top, bottom, top, bottom, left, right, left, right, top, bottom, top of XX, bottom of XX, vertical, horizontal, clock Rotation and counterclockwise) are used for identification purposes to help the reader understand the content of this disclosure and do not specifically limit the position, orientation, or use of the embodiments.

Although the above has described some embodiments in detail, one of ordinary skill in the art can make many changes to the disclosed embodiments without departing from the scope of the present disclosure. Connection references (eg, attachment, connection, connection, etc.) should be broadly interpreted and can include intermediate members between element connections and relative motion between elements. Therefore, a connection reference does not necessarily mean that the two elements are directly connected / combined and are in a fixed relationship with each other. The use of "eg" throughout the description should be broadly explained and used to provide a non-limiting example of embodiments of the present disclosure, and the present disclosure to such examples. Not limited. It is intended that all matters contained in the above description or shown in the drawings should be construed as illustration only, not limitation. Details or structural changes may be made without departing from this disclosure.

The above is merely a preferred embodiment of the present application and is not intended to limit the application, and any modifications, replacements and improvements made within the spirit and principles of the present application may be made in the present application. Should be included in the scope of protection.

Claims (10)

How to adjust the smart lamp
The smart lamp includes a germicidal lighting module, and operating modes of the germicidal lighting module include a germicidal mode, a lighting mode, and a germicidal lighting mode.
The adjustment method is
Rectifying the received power signal and
By adjusting the current of the power supply signal after rectification, the length and / or emission brightness of the sterilization illumination module can be adjusted, and the output current can be controlled within a preset range.
Switching the operation mode of the sterilization lighting module and
A method of adjusting a smart lamp, which comprises. Switching the operating mode of the germicidal lighting module specifically employs adjusting the stage of the DIP switch, which is
When the DIP switch is adjusted to the first stage, the operation mode of the sterilization lighting module is switched to the sterilization mode, and
When the DIP switch is adjusted to the second stage, the operation mode of the sterilization lighting module is switched to the lighting mode, and
When the DIP switch is adjusted to the third stage, the operation mode of the sterilization lighting module is switched to the sterilization lighting mode, and
The method for adjusting a smart lamp according to claim 1, wherein the smart lamp includes. Switching the operation mode of the germicidal lighting module specifically employs to receive the operation command of the external device, which is
When the first operation command sent from the external device is received, the operation mode of the sterilization lighting module is switched to the sterilization mode, and
When the second operation command sent from the external device is received, the operation mode of the sterilization lighting module is switched to the lighting mode, and
When the third operation command sent from the external device is received, the operation mode of the sterilization lighting module is switched to the sterilization lighting mode, and
The method for adjusting a smart lamp according to claim 1, wherein the smart lamp includes. Switching the operation mode of the sterilization lighting module specifically adopts switching when a guidance signal is received, and the guidance signal is included in a touch signal, a remote control signal, a heat guidance signal, and an infrared guidance signal. The method for adjusting a smart lamp according to claim 1, wherein any one or more of the above is included. Specifically, adjusting the length of the light emission time and / or the light emission brightness of the sterilization illumination module by adjusting the current of the power supply signal after the rectification process is performed.
The width of the output current is adjusted based on the first pulse signal, and the adjusted output current is output to the germicidal lighting module at the first preset time zone, and the germicidal lighting module is set in the first preset. Controlling the light to emit light at different times
The width of the output current is adjusted based on the second pulse signal, and the adjusted output current is output to the sterilization illumination module to control the sterilization illumination module to emit light at the first preset emission intensity. That and
The width of the output current is adjusted based on the third pulse signal, and the adjusted output current is output to the sterilization illumination module to control the sterilization illumination module to emit light with a second preset emission intensity. That and
The method for adjusting a smart lamp according to claim 1, wherein the smart lamp includes. The method for adjusting a smart lamp according to claim 1, wherein the output current is controlled to a preset range, and the preset range is 5A-20A. By adjusting the current to the power signal after rectification, the length and / or emission brightness of the germicidal lighting module is adjusted, and before controlling the output current to a preset range.
The method for adjusting a smart lamp according to claim 1, further comprising detecting whether or not a power down has occurred in the germicidal lighting module. Detecting whether a power down has occurred in a germicidal lighting module is specifically
Detecting if a level drop pulse appears on the power port of the germicidal lighting module,
If detected, it determines that the germicidal lighting module has been powered down, and connects to emergency power to power the germicidal lighting module.
7. The method for adjusting a smart lamp according to claim 7. It ’s a smart lamp adjustment system.
The smart lamp includes a germicidal lighting module, and operating modes of the germicidal lighting module include a germicidal mode, a lighting mode, and a germicidal lighting mode.
The adjustment system
A rectifier module used to rectify the received power signal,
It is used to adjust the length and / or emission brightness of the sterilization illumination module by adjusting the current to the power supply signal after rectification, and to control the output current to a preset range. , Constant current dimming module,
An operation mode switching module used to switch the operation mode of the sterilization lighting module, and
A smart lamp adjustment system characterized by including. The sterilization lighting module includes a lighting module and a sterilization module.
The sterilization mode means that only the sterilization module operates, the lighting mode means that only the lighting module operates, and the sterilization lighting mode means that the sterilization module and the lighting module are operating. The smart lamp adjustment system according to claim 9, wherein the smart lamp adjusting system indicates that they operate at the same time.

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