CN209819403U - Intelligent solar wall lamp - Google Patents

Abstract

The utility model discloses an intelligent solar wall lamp, which comprises a first processing module, a second processing module, a LED module and a touch switch, wherein the first processing module is respectively electrically connected with the touch switch and the second processing module, and the LED module is electrically connected with the second processing module; the tact switch is used for setting the gear of the brightness of the wall lamp and transmitting the gear value to the first processing module; the first processing module stores the gear value of the tact switch and transmits the gear value to the second processing module according to a request instruction of the second processing module after the circuit is powered off and powered on; the LED module responds to the PWM signal which is output by the second processing module and corresponds to the pulse width, and outputs bright light with corresponding intensity; the second processing module obtains the induction signal and the gear value, outputs a PWM signal and drives the LED module to work. Implement the utility model discloses, the mechanical switch structure who has solved current solar energy wall lamp is complicated, is difficult to effective waterproof problem, has realized the effective memory to LED gear numerical value, has improved user experience.

Description

Intelligent solar wall lamp

Technical Field

The utility model relates to a solar lamp technical field, in particular to use and dab button and realize solar energy wall lamp of many gears memory function.

Background

The solar wall lamp with the memory function on the current market is generally controlled by a mechanical switch. When the battery power of the solar wall lamp is consumed to a certain value, the solar wall lamp can enter a battery over-discharge protection state. That is, the solar cell stops supplying power to the control circuit, resulting in a power-off state for a period of time. When the solar wall lamp is powered on again, in order to enable the brightness to be consistent with the state before power failure, the gear state of the set mechanical switch is read usually.

The mechanical switch adopts the mode of stirring, and user experience is relatively poor. After the mechanical switch is used for a long time, the abrasion is large, when a mechanical gear is read, the precision is gradually reduced, and even the situation that a correct gear cannot be read occurs. The mechanical switch has more parts and complex structure, so that the manufacturing process is complex and the labor cost is high. On the other hand, due to the complexity of the mechanical switch structure, the difficulty of waterproofing the mechanical switch is also high. This greatly limits the application of mechanical wall-light switches.

Aiming at the problem of a mechanical switch of a solar wall lamp product in the market at present, the realization mode of the light touch switch is provided, the same function is realized, the structural mode is simplified, the cost is reduced, and the experience feeling of a customer is enhanced.

Disclosure of Invention

The existing mechanical solar wall lamp has the following problems: user experience is poor, and reading precision of machinery gear is low, and the structure is complicated, and the human cost is high, and waterproof degree of difficulty is big.

To above-mentioned problem, provide an intelligence solar energy wall lamp, use to dabber to realize many gears memory function, set up the gear that the wall lamp needs through the mode of dabbing, the mechanical switch structure of having solved current solar energy wall lamp is complicated, is difficult to effective waterproof problem, also improves the precision of gear numerical value simultaneously, realizes the accurate control to the wall lamp. The gear values are memorized by adopting a mode that the MCU integrated with the EERPOM or the MCU integrated with the EERPOM and the MCU are separately arranged, so that the gear values before power failure can be obtained after the wall lamp overdischarge protection or other problems are powered down, and the state of the wall lamp overdischarge protection or other problems is synchronized to the state before power failure. The effective memory of the LED gear value is realized, and the user experience is improved.

In a first aspect, the intelligent solar wall lamp comprises a first processing module, a second processing module, an LED module and a light touch switch, wherein the first processing module is electrically connected with the light touch switch and the second processing module respectively, and the LED module is electrically connected with the second processing module;

the touch switch is used for setting the gear of the brightness of the wall lamp in a touch mode and transmitting the gear value to the first processing module;

the first processing module is used for storing the gear value of the tact switch, transmitting the gear value to the second processing module and transmitting the gear value to the second processing module according to a request instruction of the second processing module after the circuit is powered off and powered on;

the LED module is used for responding to the PWM signal which is output by the second processing module and corresponds to the pulse width and outputting bright light with corresponding intensity;

and the second processing module is used for acquiring the induction signal and the gear value, outputting a PWM signal and driving the LED module to work.

In combination with the intelligent solar wall lamp of the utility model, in the first implementation case, the solar wall lamp further comprises a battery module and a protection module, the protection module is electrically connected between the battery module and the second processing module,

the battery module is used for providing power for the wall lamp circuit by using the stored electric quantity;

a protection module for performing over-discharge protection on the battery module;

combine intelligent solar energy wall lamp, the second kind implementation, solar energy wall lamp still includes the response module, the response module with second processing module electricity is connected for respond to human signal, and with this signal transmission to second processing module.

In combination with the second implementation case and the third implementation case, the sensing module is an infrared sensing module, and the second processing module is an infrared processing module.

Combine intelligence solar energy wall lamp, the fourth kind implements the condition, dab the switch including not bright, low bright, often bright and four high bright gears of bright.

Combine intelligence solar energy wall lamp, the fifth implementation condition, first processing module includes MCU, the integration has an EERPOM on the MCU.

Combine intelligence solar energy wall lamp, the sixth kind implementation, first processing module includes MCU and EERPOM, EERPOM with the MCU electricity is connected.

About the utility model provides a control method of intelligent solar energy wall lamp can realize through following step:

and S1, setting the shift of the brightness of the wall lamp in a light touch mode.

And S2, the first processing module reads the gear value, stores the gear value in a storage unit with power failure protection, and transmits the gear value to the second processing module. The second storage module sends a request for acquiring a gear value to the first processing module after power failure-power on; the first processing module sends a gear value before power failure to the second storage module at a certain frequency according to the request; the second storage module decodes the gear value after receiving the gear value, outputs a PWM signal according to the decoded gear value, drives the LED module to work, and sends a decoding response signal to the first processing module; and after receiving the decoding response signal, the first processing module stops sending the gear value until receiving a new gear value.

And S3, after receiving the induction signal, the second processing module outputs a PWM signal corresponding to the pulse width to drive the LED module to work according to the gear value.

Implement the utility model provides an intelligence solar energy wall lamp uses to dabber and realizes many gears memory function, sets up the gear that the wall lamp needs through the mode of dabbing, and the mechanical switch structure of having solved current solar energy wall lamp is complicated, is difficult to effective waterproof problem, also improves the precision of gear numerical value simultaneously, realizes the accurate control to the wall lamp. The gear values are memorized by adopting a mode that the MCU integrated with the EERPOM or the MCU integrated with the EERPOM and the MCU are separately arranged, so that the gear values before power failure can be obtained after the wall lamp overdischarge protection or other problems are powered down, and the state of the wall lamp overdischarge protection or other problems is synchronized to the state before power failure. The effective memory of the LED gear value is realized, and the user experience is improved.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic diagram of a connection of circuit logic components of an embodiment of an intelligent solar wall lamp according to the present invention;

fig. 2 is a schematic diagram of a connection of logical components of a first processing module in an intelligent solar wall lamp according to the present invention;

fig. 3 is a schematic flow chart of a control method of an intelligent solar wall lamp according to the present invention;

fig. 4 is a schematic flow chart of a substep S2 in the control method of the intelligent solar wall lamp according to the present invention;

the part names indicated by the numbers in the drawings are as follows: 110-tact switch, 120-first processing module, 121-EERPOM, 122-MCU, 130-second processing module, 140-protection module, 150-battery module, 160-induction module, 170-LED module.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are only a part of the embodiments of the present invention, not all of the embodiments. Based on the embodiments in the present invention, other embodiments obtained by a person of ordinary skill in the art without creative efforts all belong to the protection scope of the present invention.

The mechanical switch adopts the mode of stirring, and user experience is relatively poor. After the mechanical switch is used for a long time, the abrasion is large, when a mechanical gear is read, the precision is gradually reduced, and even the situation that a correct gear cannot be read occurs. The mechanical switch has more parts and complex structure, so that the manufacturing process is complex and the labor cost is high. On the other hand, due to the complexity of the mechanical switch structure, the difficulty of waterproofing the mechanical switch is also high.

To the above problems, an intelligent solar wall lamp is provided to solve the above problems.

As shown in fig. 1, fig. 1 is a schematic diagram of the circuit logic composition connection of an embodiment of an intelligent solar wall lamp of the present invention, which includes a first processing module 120, a second processing module 130, a tact switch 110, a first processing module 120, an induction module 160, a protection module 140, an LED module 170, and a battery module 150.

The first processing module 120 is electrically connected to the tact switch 110 and the second processing module 130, respectively. The LED module 170 is electrically connected to the second processing module 130, and the protection module 140 is electrically connected between the battery module and the second processing module 130. The sensing module 160 is electrically connected to the second processing module 130.

Specifically, the tact switch 110 is configured to set a gear of the brightness of the wall lamp in a touch manner, and transmit a gear value to the first processing module 120. The first processing module 120 is configured to record a gear value of the tact switch 110 when the circuit is powered on, store the gear value when the circuit is powered off, and transmit the gear value to the second processing module 130 when a request instruction of the second processing module 130 is received. And the second processing module 130 is used for acquiring the induction signal and the gear value, and driving and lighting the LED of the wall lamp.

The battery module is used for supplying power to the wall lamp circuit by utilizing the stored electric quantity. The protection module 140 is used to electrically protect the battery module, and is mainly used to protect the battery module 150 from over-discharge. The LED module 170 is configured to output a bright light with a corresponding intensity in response to the PWM signal output by the second processing module 130.

The sensing module 160 is used for sensing a human body signal and transmitting the signal to the second processing module 130.

The specific working principle is as follows: when the solar wall lamp works normally, a user firstly sets the gear of the solar wall lamp through the light touch switch 110, and the mode adopts hand touch. The tact switch 110 records the number of touches by the user, and corresponds the number of touches to a corresponding shift position. For example, if the number of touches is 1, the first gear is corresponded, and if the number of touches is two, the second gear is corresponded; or changing to the next gear every 1 touch. The first processing module 120 reads the gear value and transmits it to the second processing module 130. When the sensing module 160 senses a human body signal, the sensing signal is transmitted to the second processing module 130, and according to the gear value, the second processing module 130 outputs a corresponding PWM signal to drive the LED module 170 to operate and output light with corresponding brightness.

When the protection module 140 performs overdischarge protection on the wall lamp circuit or has other problems or power failure, the first processing module 120 has a memory function and stores the currently acquired gear value. When the wall lamp is powered on, the second processing module 130 sends a data request to the first processing module 120, and the second processing module 130 responds to the request and sends the wall lamp gear value before power failure once every 400 ms. Therefore, after the second processing module 130 decodes the data, the gear numerical information before power failure is obtained, and the synchronization function is realized.

The LED module 170 includes an LED lamp set and a circuit, and the number of LEDs in the LED lamp set and the connection method thereof are not limited.

This application dabs switch 110 button through the use and realizes many gears memory function, sets up the gear that the wall lamp needs through the mode of dabbing, and the mechanical switch structure of having solved current solar energy wall lamp is complicated, is difficult to effective waterproof problem, also improves the precision of gear numerical value simultaneously, realizes the accurate control to the wall lamp. Preferably, the sensing module 160 is an infrared sensing module 160, and the second processing module 130 is an infrared processing module. The wall lamp is started by sensing infrared information of a human body.

Preferably, the tact switch 110 in the present application includes four steps of no-light, low-light, normal-light and high-light.

Preferably, as shown in fig. 2, fig. 2 is a schematic diagram of a logic composition connection of modules of the first processing module 120 in the intelligent solar wall lamp of the present invention, in which the first processing module 120 includes an MCU 122, and an eercom 121 is integrated on the MCU 122. EEPROM (electrically erasable programmable read-write memory) is a user-alterable read-only memory that can be erased and reprogrammed (rewritten) by the action of voltages higher than normal, and a memory chip whose data is not lost upon power loss.

In some embodiments, the eercom 121 is disposed outside the MCU 122, the first processing module 120 includes the MCU 122 and the eercom 121, and the eercom 121 is electrically connected to the MCU 122. The gear values are memorized by adopting the MCU 122 integrated with the EERPOM 121 or a mode that the MCU 122 and the EERPOM are separately arranged, so that the gear values before power failure can be obtained after wall lamp over-discharge protection or other problems are powered down, and the state of the gear values is synchronized to the state before power failure. The effective memory of the LED gear value is realized, and the user experience is improved.

About intelligent solar energy wall lamp control method in this application realizes through following step, like fig. 3 and 4, fig. 3 is the utility model discloses in an intelligent solar energy wall lamp control method flow schematic diagram, fig. 4 is the utility model discloses in an intelligent solar energy wall lamp control method neutron step S2' S flow schematic diagram, utilize the intelligent solar energy wall lamp of first aspect, preferably, include the step:

and S1, setting the shift of the brightness of the wall lamp in a light touch mode.

When the solar wall lamp works normally, a user firstly sets the gear of the solar wall lamp through the light touch switch 110, and the mode adopts hand touch. The tact switch 110 records the number of touches by the user, and corresponds the number of touches to a corresponding shift position. For example, if the number of touches is 1, the first gear is corresponded, and if the number of touches is two, the second gear is corresponded; or changing to the next gear every 1 touch. The first processing module 120 reads the gear value and transmits it to the second processing module 130.

S2, the first processing module 120 reads the gear value, stores it in the storage unit with power down protection, and transmits it to the second processing module 130.

The tact switch 110 sets a gear of the brightness of the wall lamp in a touch manner, and transmits the gear value to the first processing module 120. The first processing module 120 is configured to record a gear value of the tact switch 110 when the circuit is powered on, store the gear value when the circuit is powered off, and transmit the gear value to the second processing module 130 when a request instruction of the second processing module 130 is received. The second processing module 130 obtains the sensing signal and the gear value, and outputs a PWM signal to drive and light the LEDs of the wall lamp.

The battery module provides power for the wall lamp circuit by using the stored electric quantity. The protection module 140 performs electrical protection on the battery module, and is mainly used for over-discharge protection of the battery module 150. The LED module 170 outputs a bright light with a corresponding intensity in response to the PWM signal output from the second processing module 130. The sensing module 160 senses the human body signal and transmits the signal to the second processing module 130.

When the solar wall lamp works normally, a user firstly sets the gear of the solar wall lamp through the light touch switch 110, and the mode adopts hand touch. The tact switch 110 records the number of touches by the user, and corresponds the number of touches to a corresponding shift position. For example, the number of touches is 1, which corresponds to the first gear, and two times, which corresponds to the second gear. The first processing module 120 reads the gear value and transmits it to the second processing module 130. When the sensing module 160 senses a human body signal, the sensing signal is transmitted to the second processing module 130, and according to the gear value, the second processing module 130 outputs a corresponding PWM signal to drive the LED module 170 to operate and output light with corresponding brightness.

Preferably, step S2 includes the sub-steps of:

and S21, after the power is off and the power is on, the second storage module sends a request for acquiring the gear value to the first processing module 120. And S22, the first processing module 120 sends the gear value before power failure to the second storage module at a certain frequency according to the request. S23, after receiving the gear value, the second storage module decodes the gear value, outputs a PWM signal according to the decoded gear value, drives the LED module 170 to work, and sends a decoding response signal to the first processing module 120. S24, after the first processing module 120 receives the decoding response signal, it stops sending the gear value until a new gear value is received.

When the protection module 140 performs overdischarge protection on the wall lamp circuit or has other problems or power failure, the first processing module 120 has a memory function and stores the currently acquired gear value. When the wall lamp is powered on, the second processing module 130 sends a data request to the first processing module 120, and the second processing module 130 responds to the request and sends the wall lamp gear value before power failure once every 400 ms. Therefore, after the second processing module 130 decodes the data, the gear numerical information before power failure is obtained, and the synchronization function is realized.

And S3, the second processing module 130 outputs a PWM signal corresponding to the pulse width according to the gear value to drive the LED module 170 to work. After receiving the human body sensing signal, i.e., the infrared information, the LED lamp set in the LED module 170 is turned on by outputting a PWM signal with a certain pulse width.

Implement the utility model provides an intelligence solar energy wall lamp uses to dabber and realizes many gears memory function, sets up the gear that the wall lamp needs through the mode of dabbing, and the mechanical switch structure of having solved current solar energy wall lamp is complicated, is difficult to effective waterproof problem, also improves the precision of gear numerical value simultaneously, realizes the accurate control to the wall lamp. The gear values are memorized by adopting the MCU 122 integrated with the EERPOM 121 or a mode that the MCU 122 and the EERPOM are separately arranged, so that the gear values before power failure can be obtained after wall lamp over-discharge protection or other problems are powered down, and the state of the gear values is synchronized to the state before power failure. The effective memory of the LED gear value is realized, and the user experience is improved.

The above description is only for the preferred embodiment of the present invention, and should not be construed as limiting the present invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included within the protection scope of the present invention.

Claims (7)

1. The intelligent solar wall lamp is characterized by comprising a first processing module, a second processing module, an LED module and a light touch switch, wherein the first processing module is electrically connected with the light touch switch and the second processing module respectively;

the touch switch is used for setting the gear of the brightness of the wall lamp in a touch mode and transmitting the gear value to the first processing module;

the first processing module is used for storing the gear value of the tact switch, transmitting the gear value to the second processing module and transmitting the gear value to the second processing module according to a request instruction of the second processing module after the circuit is powered off and powered on;

the LED module is used for responding to the PWM signal which is output by the second processing module and corresponds to the pulse width and outputting bright light with corresponding intensity;

and the second processing module is used for acquiring the induction signal and the gear value, outputting a PWM signal and driving the LED module to work.

2. An intelligent solar wall lamp as defined in claim 1, further comprising a battery module and a protection module, the protection module being electrically connected between the battery module and the second processing module,

a battery module for providing power to the circuit;

and the protection module is used for carrying out overdischarge protection on the battery module.

3. An intelligent solar wall lamp as defined in claim 1, further comprising a sensing module electrically connected to the second processing module for sensing a human signal and transmitting the signal to the second processing module.

4. An intelligent solar wall lamp as defined in claim 3, wherein the sensing module is an infrared sensing module and the second processing module is an infrared processing module.

5. An intelligent solar wall lamp as claimed in any one of claims 1 to 4, wherein the tact switch comprises four steps of no-light, low-light, normal-light and high-light.

6. An intelligent solar wall lamp as defined in claim 5, wherein the first processing module comprises an MCU, and the MCU has an EERPOM integrated thereon.

7. The intelligent solar wall lamp as claimed in claim 5, wherein the first processing module comprises an MCU and an EERPOM, and the EERPOM is electrically connected with the MCU.