阅读说明：本技术 太阳能灯的作业方法及该种太阳能灯 (Solar lamp and operation method thereof ) 是由 许美玉 于 2020-11-16 设计创作，主要内容包括：本申请实施例公开一种太阳能灯的作业方法及该种太阳能灯,该种太阳能灯的作业方法包括以下步骤：通过太阳能电板上的传感器获取该太阳能灯所处区域的光线量；通过红外传感器获取环境数据,该环境数据表示该太阳能灯周围是否存在人员；根据获取到的光线量和环境数据,使该太阳能灯在预设条件下运行。本申请的太阳能灯包括发光模块、光伏电源模块、环境数据检测模块、光线量检测模块、控制模块；本申请的太阳能灯的作业方法及该种太阳能灯,实现了太阳能灯根据使用环境进行运行状态地自适应调整功能,提高了绿色生活质量。(The embodiment of the application discloses an operation method of a solar lamp and the solar lamp, and the operation method of the solar lamp comprises the following steps: acquiring the light quantity of the area where the solar lamp is located through a sensor on the solar panel; acquiring environmental data through an infrared sensor, wherein the environmental data represents whether personnel exist around the solar lamp or not; and operating the solar lamp under a preset condition according to the acquired light quantity and environmental data. The solar lamp comprises a light emitting module, a photovoltaic power supply module, an environmental data detection module, a light quantity detection module and a control module; the operation method of the solar lamp and the solar lamp realize the self-adaptive adjustment function of the running state of the solar lamp according to the using environment, and the green life quality is improved.)

1. A method of operating a solar powered light comprising the steps of:

acquiring the light quantity of the area where the solar lamp is located through a sensor on the solar panel;

acquiring environmental data through an infrared sensor, wherein the environmental data represents whether personnel exist around the solar lamp or not;

and operating the solar lamp under a preset condition according to the acquired light quantity and environmental data.

2. The solar lamp operation method according to claim 1, wherein the preset conditions include a low power consumption operation condition, and the step of "operating the solar lamp under the preset conditions according to the acquired light quantity and environmental data" includes: the solar powered light operates in a low power consumption operating condition when the amount of light acquired exceeds a preset light level.

3. The solar lamp operation method according to claim 1, wherein the preset conditions include a low power consumption operation condition, and the step of "operating the solar lamp under the preset conditions according to the acquired light quantity and environmental data" includes: when the acquired environmental data indicates that no personnel are present around the solar lamp, the solar lamp is operated in a low power consumption operating condition.

4. The solar lamp operation method according to claim 1, wherein the preset conditions include a high power consumption operation condition, and the step of operating the solar lamp under the preset conditions according to the acquired light quantity and environmental data includes: and when the acquired environmental data indicate that personnel exist around the solar lamp and the acquired light quantity meets a preset light standard, the solar lamp operates under a high-power-consumption operation condition.

5. The solar lamp operation method according to claim 1, wherein the preset conditions include a medium power consumption operation condition, and the step of operating the solar lamp under the preset conditions according to the acquired light quantity and environmental data includes: and when the acquired environmental data indicate that no personnel exist around the solar lamp and the acquired light quantity meets a preset light standard, the solar lamp operates under a medium-power-consumption operation condition.

6. A solar lamp is characterized by comprising a light emitting module, a photovoltaic power module, an environmental data detection module, a light quantity detection module and a control module;

the photovoltaic power supply module is connected with the light emitting module, the environment data detection module, the light quantity detection module and the control module and used for supplying power;

the control module is connected with the light-emitting module and is used for controlling the running state of the light-emitting module;

the environment data detection module is connected with the control module and used for detecting whether personnel exist around the solar lamp and transmitting a detection result to the control module so as to control the running state of the light emitting module;

the light quantity detection module is respectively connected with the photovoltaic power module and the control module and used for acquiring the light quantity of the area where the solar lamp is located and transmitting the detection result to the control module so as to control the running state of the light emitting module.

7. A solar powered light as claimed in claim 6 wherein the control module includes a master MCU, a switch control circuit, a voltage regulation circuit; the main control MCU is respectively connected with the photovoltaic power module, the light emitting module, the environment data detection module and the light quantity detection module; the switch control circuit is respectively connected with the main control MCU and the light-emitting module and is used for controlling the power-on or power-off of the light-emitting module; the voltage regulating circuit is respectively connected with the master control MCU and the light-emitting module and is used for controlling the light-emitting module to regulate the running state under the power-on condition; the operation states of the light emitting module include a low power consumption operation state, a medium power consumption operation state, and a high power consumption operation state.

8. A solar energy lamp as claimed in claim 7, wherein the control module further comprises a delay circuit, the delay circuit is respectively connected to the main control MCU, the switch control circuit and the voltage regulating circuit, and the main control MCU performs delay control on the operation state of the light emitting module through the delay circuit.

9. A solar lamp as claimed in claim 6, wherein the light quantity detection module includes a voltage comparison circuit, the voltage comparison circuit is respectively connected to the photovoltaic power module and the control module, and is configured to obtain a voltage value generated by the photovoltaic power module, compare the voltage value with a voltage value corresponding to a preset light standard, and send a comparison result to the control module, and the control module controls the operation state of the light emitting module according to the comparison result.

10. A solar powered light as claimed in claim 6, wherein the environmental data detection module is an infrared sensor.

Technical Field

The application relates to the technical field of lighting equipment, in particular to a solar lamp and an operation method thereof.

Background

Lamps, lighting articles, generally refer to lighted implements. With the increase of richness of life, the applicable scenes of the lamp are more and more, and the lamp in the lake of birth slowly appears in some occasions outdoors, such as corridors and the like.

Based on the advocation of green life, the application of new energy technology becomes the mainstream development direction of society. The lamp using solar energy in the prior art can be used as a power supply through solar photovoltaic power generation, so that green energy is fully utilized, and a series of problems caused by traditional electric equipment are reduced. However, this kind of solar lamp is usually switched on and off by manual control, or is set to an operation mode in which it is turned off during the daytime and turned on when the night comes, and thus cannot be adjusted in an adaptive manner according to the use environment.

Disclosure of Invention

The application aims to solve the technical problems and provides the solar lamp and the operation method thereof, which can be used for carrying out self-adaptive adjustment on the working state according to the use environment and improving the green life quality.

In order to achieve the above object, the present application discloses a method for operating a solar lamp, comprising the steps of: acquiring the light quantity of the area where the solar lamp is located through a sensor on the solar panel; acquiring environmental data through an infrared sensor, wherein the environmental data represents whether personnel exist around the solar lamp or not; and operating the solar lamp under a preset condition according to the acquired light quantity and environmental data.

Preferably, the preset conditions include low power consumption operation conditions, and the step of "operating the solar lamp under the preset conditions according to the acquired light quantity and environmental data" includes: the solar powered light operates in a low power consumption operating condition when the amount of light acquired exceeds a preset light level.

Preferably, the preset conditions include low power consumption operation conditions, and the step of "operating the solar lamp under the preset conditions according to the acquired light quantity and environmental data" includes: when the acquired environmental data indicates that no personnel are present around the solar lamp, the solar lamp is operated in a low power consumption operating condition.

Preferably, the preset conditions include a high power consumption operation condition, and the step of "operating the solar lamp under the preset conditions according to the acquired light quantity and environmental data" includes: and when the acquired environmental data indicate that personnel exist around the solar lamp and the acquired light quantity meets a preset light standard, the solar lamp operates under a high-power-consumption operation condition.

Preferably, the preset condition includes a medium power consumption operation condition, and the step of "operating the solar lamp under the preset condition according to the acquired light quantity and the environmental data" includes: and when the acquired environmental data indicate that no personnel exist around the solar lamp and the acquired light quantity meets a preset light standard, the solar lamp operates under a medium-power-consumption operation condition.

Based on the operation method of the solar lamp, the operation state of the solar lamp is adaptively switched according to the light quantity of the area where the solar lamp is located and whether personnel exist around the solar lamp, so that the function of adaptively adjusting the working state of the solar lamp according to the use environment is realized, and the green life quality is improved.

The application also discloses a solar lamp, which comprises a light-emitting module, a photovoltaic power module, an environmental data detection module, a light quantity detection module and a control module; the photovoltaic power supply module is connected with the light emitting module, the environment data detection module, the light quantity detection module and the control module and used for supplying power; the control module is connected with the light-emitting module and is used for controlling the running state of the light-emitting module; the environment data detection module is connected with the control module and used for detecting whether personnel exist around the solar lamp and transmitting a detection result to the control module so as to control the running state of the light emitting module; the light quantity detection module is respectively connected with the photovoltaic power module and the control module and used for acquiring the light quantity of the area where the solar lamp is located and transmitting the detection result to the control module so as to control the running state of the light emitting module.

Preferably, the control module comprises a main control MCU, a switch control circuit and a voltage regulating circuit; the main control MCU is respectively connected with the photovoltaic power module, the light emitting module, the environment data detection module and the light quantity detection module; the switch control circuit is respectively connected with the main control MCU and the light-emitting module and is used for controlling the power-on or power-off of the light-emitting module; the voltage regulating circuit is respectively connected with the master control MCU and the light-emitting module and is used for controlling the light-emitting module to regulate the running state under the power-on condition; the operation states of the light emitting module include a low power consumption operation state, a medium power consumption operation state, and a high power consumption operation state.

Preferably, the control module further comprises a delay circuit, the delay circuit is respectively connected with the main control MCU, the switch control circuit and the voltage regulating circuit, and the main control MCU performs delay control on the operation state of the light emitting module through the delay circuit.

Preferably, the light quantity detection module includes a voltage comparison circuit, the voltage comparison circuit is respectively connected to the photovoltaic power module and the control module, and is configured to obtain a power generation voltage value of the photovoltaic power module, compare the voltage value with a voltage value corresponding to a preset light standard, and send a comparison result to the control module, and the control module controls an operation state of the light emitting module according to the comparison result.

Preferably, the environment data detection module is an infrared sensor.

Based on the structure of the solar lamp, the light quantity detection module is used for detecting the voltage received by the photovoltaic power supply module, so that the light quantity of the current environment is measured and calculated, the control module is used for controlling the running state of the light emitting module, and when the environment brightness is larger than the preset light quantity, the light emitting module is turned off or enters a low-power-consumption running state after being delayed for a certain time; when ambient brightness is smaller than the preset light quantity, whether people exist around the solar lamp or not is detected through the sensing detection module, when people exist, the control module controls the light emitting module to adjust to enter a high-power-consumption running state, when no people exist, the control module controls the light emitting module to enter a medium-power-consumption running state, and the function that the solar lamp can be adaptively adjusted according to the external environment is achieved.

In summary, the operation method of the solar lamp and the solar lamp realize the function of self-adaptive adjustment of the solar lamp according to the external environment, and improve the quality of green life and the reliability of illumination according to needs.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a schematic structural diagram of a solar lamp in an embodiment of the present application.

Detailed Description

In order to make those skilled in the art better understand the technical solutions in the present application, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

Example (b): a method of operating a solar powered light comprising the steps of:

acquiring the light quantity of the area where the solar lamp is located through a sensor on the solar panel;

acquiring environmental data through an infrared sensor, wherein the environmental data represents whether personnel exist around the solar lamp or not;

and operating the solar lamp under a preset condition according to the acquired light quantity and environmental data.

The preset conditions comprise low-power-consumption operation conditions, and the step of enabling the solar lamp to operate under the preset conditions according to the acquired light quantity and the acquired environmental data comprises the following steps of: the solar powered light operates in a low power consumption operating condition when the amount of light acquired exceeds a preset light level.

In this embodiment, the preset condition includes a low power consumption operation condition, and the step "operating the solar lamp under the preset condition according to the obtained light quantity and the environmental data" includes: when the acquired environmental data indicates that no personnel are present around the solar lamp, the solar lamp is operated in a low power consumption operating condition.

The preset conditions comprise high-power-consumption operation conditions, and the step of enabling the solar lamp to operate under the preset conditions according to the acquired light quantity and the acquired environmental data comprises the following steps of: and when the acquired environmental data indicate that personnel exist around the solar lamp and the acquired light quantity meets a preset light standard, the solar lamp operates under a high-power-consumption operation condition.

The preset conditions comprise medium power consumption operation conditions, and the step of enabling the solar lamp to operate under the preset conditions according to the acquired light quantity and the acquired environmental data comprises the following steps of: and when the acquired environmental data indicate that no personnel exist around the solar lamp and the acquired light quantity meets a preset light standard, the solar lamp operates under a medium-power-consumption operation condition.

By means of the method, the operation state of the solar lamp is adaptively switched according to the light quantity of the area where the solar lamp is located and whether personnel exist around the solar lamp, so that the function of adaptively adjusting the working state of the solar lamp according to the use environment is achieved, and the green life quality is improved.

The embodiment also discloses a solar lamp as shown in fig. 1, which comprises a light emitting module, a photovoltaic power module, an environmental data detection module, a light quantity detection module and a control module. The light emitting module may be any one of the prior art lamps, such as a lamp tube.

The photovoltaic power module is connected with the light emitting module, the environment data detection module, the light quantity detection module and the control module and used for supplying power. The photovoltaic power module can be any photovoltaic power generation device in the prior art, such as a photovoltaic power generation device which generates power through a solar panel.

The control module is connected with the light emitting module and used for controlling the operation state of the light emitting module, and the control module can be any one of the prior art.

The environment data detection module is connected with the control module and used for detecting whether personnel exist around the solar lamp or not and transmitting a detection result to the control module to control the running state of the light emitting module, and the environment data detection module can be any one of the prior art.

The light quantity detection module is respectively connected with the photovoltaic power module and the control module and used for acquiring the light quantity of the area where the solar lamp is located and transmitting the detection result to the control module so as to control the running state of the light emitting module. The light amount detection module may be any one of the prior art.

In some possible implementations of the present embodiment, the control module may be a PLC or the like in the prior art. As a preferred implementation manner of this embodiment, in this embodiment, the control module includes a main control MCU, a switch control circuit, and a voltage regulation circuit; the main control MCU is respectively connected with the photovoltaic power module, the light-emitting module, the environmental data detection module and the light quantity detection module; the switch control circuit is respectively connected with the main control MCU and the light-emitting module and is used for controlling the power-on or power-off of the light-emitting module; the voltage regulating circuit is respectively connected with the main control MCU and the light emitting module and is used for controlling the light emitting module to adjust the running state under the power-on condition; the operation states of the light emitting module include a low power consumption operation state, a medium power consumption operation state, and a high power consumption operation state.

The control module further comprises a delay circuit, the delay circuit is respectively connected with the main control MCU, the switch control circuit and the voltage regulating circuit, and the main control MCU carries out delay control on the running state of the light-emitting module through the delay circuit.

Specifically, when the light quantity detection module detects that the generation voltage of the photovoltaic power supply module is large, the state switching process of the light emitting module is that the main control MCU controls the switch control circuit to drive the light emitting module to switch to the off state, or the main control MCU controls the switch control circuit to drive the light emitting module through the delay circuit to switch to the off state after a period of time t (t can be any time such as 5 seconds, 10 seconds, 30 seconds) is delayed, or the main control MCU drives the voltage regulation circuit through the delay circuit to control the light emitting module to switch to the low-power-consumption operation state, and the brightness of the light emitting module is dark at this time.

When the light quantity detection module detects that the power generation voltage of the photovoltaic power supply module is small, the main control MCU controls the switch control circuit to drive the light emitting module to be switched to the on state. When the environmental data detection module detects that people are around the solar lamp, the main control MCU controls the light emitting module to be switched into a high-power-consumption running state through the voltage regulating circuit, and at the moment, the brightness of the light emitting module is bright. When the environmental data detection module detects that no person is around the solar lamp, the main control MCU controls the light emitting module to be switched to a medium power consumption running state through the voltage regulating circuit, and at the moment, the brightness of the light emitting module is medium brightness between darker brightness and bright brightness.

In some possible embodiments of the present embodiment, the light amount detection module may be a light brightness detection sensor in the prior art. As a preferred implementation manner of this embodiment, in this embodiment, the light amount detection module includes a voltage comparison circuit, the voltage comparison circuit is respectively connected to the photovoltaic power module and the control module, and is configured to obtain a power generation voltage value of the photovoltaic power module, compare the voltage value with a voltage value corresponding to a preset light standard, send a comparison result to the control module, and control the operation state of the light emitting module according to the comparison result by the control module. As a possible implementation manner of this embodiment, the voltage value corresponding to the preset light standard is a power generation voltage value when the photovoltaic power module is irradiated under illumination with lower brightness. For example, under the irradiation of darker brightness with light intensity of 0-10 lx, the generated voltage of the photovoltaic power module is used as the voltage value corresponding to the preset light standard.

In some possible implementations of the present embodiment, the environment data detection module may be any human body detection sensor in the prior art. In this embodiment, the environment data detection module is an infrared sensor.

By means of the structure, the solar lamp detects the voltage received by the photovoltaic power supply module through the light quantity detection module, so that the illumination brightness of the current environment is measured and calculated, whether people exist around the solar lamp is judged through the control module and the environment data detection module, the running state of the light emitting module is adjusted in a self-adaptive mode by combining the detection result of the light quantity detection module, and the function that the solar lamp can be adjusted in an adaptive mode according to the external environment is achieved. In summary, the operation method of the solar lamp and the solar lamp in the embodiment realize the function of self-adaptive adjustment of the solar lamp according to the external environment, and improve the quality of green life and the reliability of illumination according to needs.

The foregoing description is for the purpose of illustration and is not for the purpose of limitation. Many embodiments and many applications other than the examples provided will be apparent to those of skill in the art upon reading the above description. The scope of the present teachings should, therefore, be determined not with reference to the above description, but should instead be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled. The disclosures of all articles and references, including patent applications and publications, are hereby incorporated by reference for all purposes. The omission in the foregoing claims of any aspect of subject matter that is disclosed herein is not intended to forego the subject matter and should not be construed as an admission that the applicant does not consider such subject matter to be part of the disclosed subject matter.