CN112074034A - Intelligent lamp control system and intelligent lamp comprising same - Google Patents

Abstract

The invention discloses an intelligent lamp control system which comprises a touch circuit, an illumination circuit, an anion generating circuit, a wireless communication circuit and a mobile client, wherein the touch circuit can control the on/off of the illumination circuit to realize the light emitting or the light extinguishing of the illumination circuit, the touch circuit can control the on/off of the anion generating circuit, the anion generating circuit can increase the anion component in the air and improve the air quality when working, the illumination circuit and the anion generating circuit are also controlled by the mobile client through the wireless communication circuit, and the illumination and anion functions can be intelligently started through the mobile client, so that the illumination requirement can be ensured, and the air quality can be improved. In addition, the invention further discloses an intelligent lamp, which can realize integration of intelligent illumination and an anion function, realize the multi-functionalization of the lamp, and meanwhile, the illumination and anion functions can be intelligently started through the mobile client, so that the use experience of a user on the intelligent lamp is improved.

Description

Intelligent lamp control system and intelligent lamp comprising same

Technical Field

The invention relates to an intelligent lamp control system and an intelligent lamp comprising the same.

Background

In the market of the present day, lamps basically still need active control of users, have reduced user experience, and current lamps and lanterns function is all more single moreover, can not satisfy masses' individualized demand more and more.

Disclosure of Invention

The invention aims to provide an intelligent lamp control system and an intelligent lamp comprising the same.

According to one aspect of the invention, an intelligent lamp control system is provided, and the intelligent lamp control system comprises a touch circuit, an illumination circuit, an anion generation circuit, a wireless communication circuit and a mobile client, wherein the touch circuit is connected with the illumination circuit, the touch circuit outputs a control command to the illumination circuit, the touch circuit is connected with the anion generation circuit, the touch circuit outputs a switch command to the anion generation circuit, the touch circuit is connected with the wireless communication circuit, and the mobile client interacts with the touch circuit through the wireless communication circuit to realize the operation of the illumination circuit and the anion generation circuit.

The intelligent lamp control system can control the on/off of the lighting circuit through the touch circuit to achieve the lighting or extinguishing of the lighting circuit, can control the on/off of the negative ion generating circuit through the touch circuit, can increase the negative ion components in the air when the negative ion generating circuit works, and therefore can improve the air quality.

In some embodiments, the air quality monitoring system may further include an environment monitoring circuit, the touch circuit is connected to the environment monitoring circuit, the mobile client interacts with the touch circuit through the wireless communication circuit to realize operation of the environment monitoring circuit, the environment monitoring circuit outputs the detected air quality signal to the touch circuit, and the touch circuit sends the current air quality data to the mobile client through the wireless communication circuit. Therefore, the environment monitoring circuit can detect the air quality in the environment and feed the air quality back to the mobile client side for displaying, so that a user can be assisted in improving the air quality, and the multifunctional function of the lamp is realized.

In some embodiments, the environment monitoring circuit may be an MAQ300C chip. Therefore, the MAQ300C chip has extremely high sensitivity to organic volatile gases such as formaldehyde, benzene, carbon monoxide, ammonia gas, hydrogen, alcohol, cigarette smoke, essence and the like, so that the quality of air can be detected comprehensively.

In some embodiments, the touch control circuit may further include a driving circuit a and a driving circuit B, the touch control circuit is connected to the driving circuit a, the touch control circuit is connected to the driving circuit B, the lighting circuit includes a lighting circuit a and a lighting circuit B, a color of light emitted by the lighting circuit a is different from a color of light emitted by the lighting circuit B, the driving circuit a is connected to the lighting circuit a, and the driving circuit B is connected to the lighting circuit B. From this, the touch control circuit can light the light source in the lighting circuit A through drive circuit A, and the touch control circuit can light the light source in the lighting circuit B through drive circuit B to, lighting circuit A and lighting circuit B send the light of different colours, and two kinds of light account for than the combination together can form multiple lighting mode according to different luminance, realize the multi-mode of lamps and lanterns illumination, promote the user and experience the use of intelligent lamps and lanterns.

In some embodiments, the driver circuit a and the driver circuit B may both employ PT4115 chips. Thus, when the driver circuit employs PT 4115: the larger the inductance is, the lower the working frequency is, and the better the constant current effect is; the larger the output current is, the smaller the required inductance value is, and the inductance is convenient to select; the higher the output voltage, the higher the efficiency; PT 4115's inside contains the excess temperature protect function, and the outside overtemperature protection circuit that can design has dual protection to the LED light source.

In some embodiments, the lighting circuit a may be a yellow LED lamp set, and the lighting circuit B may be a white LED lamp set, and the yellow LED lamp set and the white LED lamp set are alternately arranged. Therefore, the yellow light LED lamp group and the white light LED lamp group are arranged in a staggered mode at intervals, so that mixed light emitted by the lighting circuit is more uniform.

In some embodiments, the touch circuit may be an HC5F20AT chip. Therefore, the HC5F20AT chip is an 8-bit MCU chip with 20 touch channels and 26 general I/O ports, and is provided with an 8-bit MCU core and a FLASH-ROM (which can be repeatedly erased and written for more than 10 ten thousand times) and supports an 8-channel 12-bit SAR ADC, and a touch sensing controller is arranged in the HC5F20AT chip and supports 20-channel touch input, so that the anti-interference performance is high, the chip can normally work in a STOP mode and supports touch awakening in the STOP mode.

In some embodiments, the wireless communication circuit may be an optional chip, ESP 8266-S1. Therefore, the ESP8266-S1 WiFi module integrates Tensiica L106 ultra-low power consumption 32-bit micro MCU in the industry in a small-size package, has a 16-bit simplified mode, supports main frequency of 80MHz and 160MHz, supports RTOS, integrates Wi-Fi MAC/BB/RF/PA/LNA, an onboard antenna, an ESP8266-S1 chip supports a standard IEEE802.11 b/g/n protocol and a complete TCP/IP protocol stack, and can be used for adding a networking function to a lamp.

In some embodiments, the mobile client may be a cell phone with a corresponding APP installed. From this, through corresponding APP on the cell-phone just can intelligent start lamps and lanterns illumination, anion function, promoted the user and experienced to intelligent lamps and lanterns.

In some embodiments, the anion generator in the anion generating circuit can be selected from Nanbai NB-C. Therefore, the input voltage of the anion generator of the Nanbai NB-C is DC3.7-24V, AC90V-240V, the output concentration is 1-30 (10^6), the anion component in the air can be effectively increased, and the air quality is improved.

In some embodiments, a brightness shift key may be disposed on the touch circuit, and the brightness shift key controls the brightness of the illumination circuit. Therefore, according to the lighting requirements, the user can adjust the luminous brightness of the lighting circuit to the brightness suitable for the user.

In some embodiments, the number of brightness gear keys may be five, GN1, GN2, GN3, GN4, and GN5, respectively. From this, according to the lighting needs, the user can adjust five grades of luminance: GN1, GN2, GN3, GN4, GN 5.

In some embodiments, the touch circuit may be provided with a mode key and an anion switch key, the mode key controls a color temperature of the lighting circuit, and the anion switch key controls on/off of the anion generating circuit. Therefore, according to the illumination requirement, the brightness of the illumination circuit can be adjusted to be in a proper eye protection mode by touching the mode key, the operation can be completed on the mobile client, and when the air quality needs to be improved, the operation can be completed on the mobile client by touching the negative ion switch key.

In some embodiments, the number of mode keys may be four, namely, READ key, WORK key, RELAX key, and NIGHT key. Therefore, when reading, the user can touch the READ key, when working, the user can touch the WORK key, when relaxing, the user can touch the RELAX key, when sleeping, the user can touch the NIGHT key, different scenes can select proper lighting modes, and the use experience of the user on the lamp is improved.

In some embodiments, the touch control circuit may be provided with an indicator light set. Therefore, when different functions are realized, corresponding indicator lights are turned on, so that a user can observe and know conveniently, and when the corresponding functions stop working, the corresponding indicator lights are turned off.

According to another aspect of the invention, the invention also provides an intelligent lamp, which comprises a lamp body and the intelligent lamp control system, wherein the intelligent lamp control system is arranged on the lamp body.

The intelligent lamp can realize integration of intelligent illumination and an anion function, not only can ensure illumination requirements, but also can improve air quality and realize the multifunction of the lamp, and meanwhile, the illumination and anion functions can be intelligently started through the mobile client, so that the use experience of a user on the intelligent lamp is improved.

Drawings

FIG. 1 is a schematic block diagram of an intelligent light control system according to an embodiment of the present invention;

fig. 2 is a schematic diagram of a touch circuit in the intelligent lamp control system shown in fig. 1;

fig. 3 is a schematic diagram of a driving circuit a, an illumination circuit a, a driving circuit B, and an illumination circuit B in the intelligent lamp control system shown in fig. 1;

FIG. 4 is a schematic diagram of a negative ion generating circuit in the intelligent lamp control system shown in FIG. 1;

FIG. 5 is a schematic diagram of an environment monitoring circuit in the intelligent light fixture control system shown in FIG. 1;

FIG. 6 is a schematic diagram of a wireless communication circuit in the intelligent lighting control system shown in FIG. 1;

FIG. 7 is a schematic diagram of the indicator light set of the intelligent light control system of FIG. 1;

FIG. 8 is a schematic structural diagram of an intelligent lamp according to an embodiment of the present invention;

FIG. 9 is a schematic structural diagram of the intelligent lamp shown in FIG. 8 after a part of the housing is hidden;

FIG. 10 is a side view of the smart light fixture shown in FIG. 8;

fig. 11 is an interface display on the mobile client after the intelligent lighting fixture shown in fig. 8 interacts with the mobile client.

Detailed Description

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

Fig. 1 schematically shows the structure of an intelligent lamp control system according to an embodiment of the present invention.

Referring to fig. 1, the intelligent lamp control system includes a touch circuit 1, a lighting circuit, a negative ion generating circuit 3, a wireless communication circuit 4, and a mobile client 5. In addition, the intelligent lamp control system may further include an environment monitoring circuit 6, a driving circuit a7, a driving circuit B8, and an indicator light group 9.

Referring to fig. 1, the lighting circuit includes a lighting circuit a21 and a lighting circuit B22, the touch circuit 1 is connected to the lighting circuit a21 through a driving circuit a7, and the touch circuit 1 is connected to the lighting circuit B22 through a driving circuit B8; the touch circuit 1 is connected with the driving circuit A7, the driving circuit A7 is connected with the lighting circuit A21, the touch circuit 1 is connected with the driving circuit B8, and the driving circuit B8 is connected with the lighting circuit B22; the touch circuit 1 can output a control command to the lighting circuit a21, the touch circuit 1 can output a control command to the lighting circuit B22, the touch circuit 1 can light the light source in the lighting circuit a21 through the driving circuit a7, and the touch circuit 1 can light the light source in the lighting circuit B22 through the driving circuit B8.

The color of the light that lighting circuit A21 sent is different with the color of the light that lighting circuit B22 sent, and two kinds of light can form multiple lighting mode according to different luminance ratio combination together, realizes the multimode of lamps and lanterns illumination, promotes the user and experiences to the use of intelligent lamps and lanterns.

In this embodiment, the lighting circuit a21 adopts a yellow LED lamp group, the lighting circuit B22 adopts a white LED lamp group, and the yellow LED lamp group and the white LED lamp group may be alternately arranged, so that the light emitted from the lighting circuit a21 and the light emitted from the lighting circuit B22 may be more uniformly mixed. In other embodiments, the colors of the lights emitted by the lighting circuits a21 and B22 may be appropriately adjusted according to lighting needs. In other embodiments, the arrangement of the yellow LED lamp set and the white LED lamp set can be adjusted according to the lighting requirement.

The yellow light LED lamp group and the white light LED lamp group are arranged in a staggered mode at intervals, so that mixed light emitted by the lighting circuit is more uniform

Referring to fig. 1, the touch circuit 1 is connected to the anion generating circuit 3, and the touch circuit 1 can output a switching command to the anion generating circuit 3, so as to control on/off of the anion generating circuit 3.

Referring to fig. 1, the touch circuit 1 is connected to the wireless communication circuit 4 and performs two-way communication, the mobile client 5 is wirelessly connected to the wireless communication circuit 4 and performs two-way communication, the mobile client 5 can interact with the touch circuit 1 through the wireless communication circuit 4 to realize the operation of the lighting circuit a21, the lighting circuit B22 and the anion generating circuit 3, and the lighting and anion functions can be intelligently started through the mobile client 5.

Referring to fig. 1, the touch circuit 1 is connected to the environment monitoring circuit 6, and the two-way communication is performed, the environment monitoring circuit 6 can output the detected air quality signal to the touch circuit 1, the touch circuit 1 sends the current air quality data to the mobile client 5 through the wireless communication circuit 4 for displaying, the environment monitoring circuit 6 can detect the air quality in the environment where the environment is located, and feeds the air quality data back to the mobile client 5 for displaying, so as to assist the user in improving the air quality, and the switch of the environment monitoring circuit 6 can be controlled through the mobile client 5.

Referring to fig. 1, the touch circuit 1 is connected to the indicator light set 9, and when different functions are implemented, corresponding indicator lights are turned on in the indicator light set 9, so that a user can observe and know the functions conveniently, and when the corresponding functions stop working, the corresponding indicator lights are turned off.

Fig. 2 schematically shows the principle of the touch control circuit in the intelligent lamp control system shown in fig. 1.

Referring to fig. 2, in this embodiment, the touch circuit 1 selects an HC5F20AT chip, the HC5F20AT chip is an 8-bit MCU chip having 20 touch channels and 26 general I/O ports, and has an 8-bit MCU core and a FLASH-ROM (which can be repeatedly erased for more than 10 ten thousand times), which support an 8-channel 12-bit SAR ADC, and the HC5F20AT chip has a built-in touch sensing controller, supports 20-channel touch input, has high anti-interference performance, can normally operate in a STOP mode, and supports STOP mode touch wakeup. In other embodiments, the touch circuit 1 may also be other touch chips capable of implementing the same function.

Referring to fig. 2, pin P35 of the HC5F20AT chip connects the switch of the lighting circuit through R0(R0 ═ 1K): the "ON/OFF" key is touched when lighting is required, so that the ON/OFF of a lighting circuit can be controlled, and the key can be operated ON the mobile client 5.

Referring to fig. 2, pin P00 of the HC5F20AT chip is connected to the negative ion switch through R6(R6 ═ 1K): an "ION" bond; when the air quality needs to be improved, the ION generator in the anion generating circuit 3 starts to work by touching the "ION" key, and the anion generating circuit can also be operated on the mobile client 5 to control the on-off of the anion generating circuit 3.

Referring to fig. 2, pin P04 of the HC5F20AT chip is connected to the reading mode key through R10(R10 ═ 1K): the "READ" key, pin P03 of the HC5F20AT chip, is connected to the office mode key through R9(R9 ═ 1K): the "WORK" key, pin P02 of HC5F20AT chip, connects the leisure mode key through R8(R8 ═ 1K): the "RELAX" key, pin P01 of the HC5F20AT chip, is connected to the sleep mode key through R7(R7 ═ 1K): a "NIGHT" linkage; according to the lighting requirements, the light emitting brightness of the lighting circuit A21 and the lighting circuit B22 can be adjusted to be in an appropriate eye protection mode by touching the corresponding mode keys, the 'READ' key can be touched during reading, the 'WORK' key can be touched during working, the 'RELAX' key can be touched during relaxing, the 'NIGHT' key can be touched during sleeping, the appropriate lighting mode can be selected in different scenes, the use experience of a user on the lamp is improved, and the operation can be completed on the mobile client 5.

Referring to fig. 2, pin P36 of the HC5F20AT chip is connected to the first-gear brightness switch through R1(R1 ═ 1K): the key of "GN 1", pin P37 of the HC5F20AT chip is connected to the second-gear brightness switch through R2(R2 ═ 1K): the key of "GN 2", pin P17 of the HC5F20AT chip is connected to the three-step brightness switch through R3(R3 ═ 1K): the key of "GN 3", pin P16 of the HC5F20AT chip is connected to the four-step brightness switch through R4(R4 ═ 1K): the key of "GN 4", pin P15 of the HC5F20AT chip is connected to the five-step brightness switch through R5(R5 ═ 1K): the "GN 5" bond; according to the lighting requirements, the user can touch the keys of "GN 1", GN2 ", GN 3", GN4 "and GN 5" to adjust the brightness of the lighting circuit A21 and the lighting circuit B22.

Referring to fig. 2, pin P14 of the HC5F20AT chip is connected in series with R12(R12 ═ 1K) and led D2, and when the light emitting brightness of the lighting circuit a21 and the lighting circuit B22 is in the reading mode, the led D2 lights up; a pin P13 of the HC5F20AT chip is connected in series with R13(R13 equals 1K) and the led D3, and when the light emitting brightness of the lighting circuit a21 and the lighting circuit B22 is in the office mode, the led D3 lights up; a pin P12 of the HC5F20AT chip is connected in series with R14(R14 is 1K) and the light emitting diode D4, and when the light emitting brightness of the lighting circuit a21 and the lighting circuit B22 is in the relaxation and leisure mode, the light emitting diode D4 lights up; a pin P11 of the HC5F20AT chip is connected in series with R15(R15 equals 1K) and the light emitting diode D5, and when the light emitting brightness of the lighting circuit a21 and the lighting circuit B22 is in the sleep mode, the light emitting diode D5 lights up; the pin P10 of the HC5F20AT chip is connected in series with R11(R11 equals 1K) and the light emitting diode D1, and when the negative ion generating circuit 3 operates, the light emitting diode D1 lights up.

Referring to fig. 2, a pin P06 of the HC5F20AT chip is connected to the negative ion generating circuit 3, and the HC5F20AT chip outputs a control signal to the negative ion generating circuit 3 through the pin P06 to control the operation or stop of the negative ion generator in the negative ion generating circuit 3.

Referring to fig. 2, pin P05 of the HC5F20AT chip is connected to the environment monitoring circuit 6, and the environment monitoring circuit 6 selects an MAQ300C chip; port a of MAQ300C chip is connected to pin P32 of HC5F20AT chip through R21(R21 ═ 1.2K), pin P32 of HC5F20AT chip is grounded through R34(R34 ═ 3K), port B of MAQ300C chip can be reserved, pin P33 of HC5F20AT chip is connected to R22, the other end of R22 is vacant, pin P33 of HC5F20AT chip is connected to R35, the other end of R35 is vacant, the other end of R22 can be connected to port B of MAQ300C chip as required, and the other end of R35 is grounded; the HC5F20AT chip outputs a control signal to the environmental monitoring circuit 6 through the pin P05 for turning on or off the MAQ300C chip, and the MAQ300C chip outputs a detected air quality signal (PWM signal) to the HC5F20AT chip through the port a and the pin P32 of the HC5F20AT chip.

Referring to fig. 2, pins P30 and P31 of the HC5F20AT chip are connected to a WiFi module of the wireless communication circuit 4, the WiFi module of the wireless communication circuit 4 is selected from an ESP8266-S1 chip, pin P30 of the HC5F20AT chip is connected to pin TXD1 of the ESP8266-S1 chip, and pin P31 of the HC5F20AT chip is connected to pin RXD1 of the ESP8266-S1 chip.

Referring to fig. 2, pin P07 of the HC5F20AT chip is connected to the driving circuit B8, pin P34 of the HC5F20AT chip is connected to the driving circuit a7, the HC5F20AT chip controls the lighting circuit a21 (yellow LED lamp group) through pin P34, and the HC5F20AT chip controls the lighting circuit B22 (white LED lamp group) through pin P07.

Fig. 3 schematically shows the principle of the driving circuit a, the lighting circuit a, the driving circuit B and the lighting circuit B in the intelligent lamp control system shown in fig. 1.

Referring to fig. 3, a driving circuit a7 and a driving circuit B8 both use PT4115 chips, the driving circuit a7 is connected to pin P34 of the HC5F20AT chip, the driving circuit a7 is connected to a lighting circuit a21 (yellow LED lamp group), "Y-LED" in fig. 3 is a yellow LED lamp group, "B8 is connected to pin P07 of the HC5F20AT chip, the driving circuit B8 is connected to a lighting circuit B22 (white LED lamp group)," W-LED "in fig. 3 is a white LED lamp group; the HC5F20AT chip can light the yellow LED lamp group through the drive circuit A7, and the HC5F20AT chip can light the white LED lamp group through the drive circuit B8.

Fig. 4 schematically shows the principle of the negative ion generating circuit in the intelligent lamp control system shown in fig. 1.

Referring to fig. 4, the negative ion generator in the negative ion generating circuit 3 is selected from the south cypress NB-C negative ion generator, the input voltage of the south cypress NB-C negative ion generator is DC3.7-24V, AC90V-240V, and the output concentration is 1 × -30 ^ 10^6, which can effectively increase the negative ion component in the air and improve the air quality.

Referring to fig. 4, the negative ion generating circuit 3 is connected to pin P06 of the HC5F20AT chip, and the HC5F20AT chip outputs a control signal to the negative ion generating circuit 3 through pin P06 to control the operation or stop of the negative ion generator in the negative ion generating circuit 3.

Fig. 5 schematically shows the principle of the environment monitoring circuit in the intelligent luminaire control system shown in fig. 1.

Referring to fig. 5, the environment detection module in the environment monitoring circuit 6 selects an MAQ300C chip, and the MAQ300C chip has a very high sensitivity to organic volatile gases such as formaldehyde, benzene, carbon monoxide, ammonia, hydrogen, alcohol, cigarette smoke, and essence, and can detect the quality of air relatively comprehensively.

Referring to fig. 5, the port a of the MAQ300C chip is connected to pin P32 of the HC5F20AT chip through R21(R21 ═ 1.2K), the port B of the MAQ300C chip can be used as a reserved port, the port B of the MAQ300C chip can be connected to pin P33 of the HC5F20AT chip as required, and the pin P05 of the HC5F20AT chip is connected to the environment monitoring circuit 6; the HC5F20AT chip outputs a control signal to the environment monitoring circuit 6 through a pin P05 to turn on or off the MAQ300C chip, the MAQ300C chip outputs a detected air quality signal (PWM signal) to the HC5F20AT chip through an a port and a pin P32 of the HC5F20AT chip, and the HC5F20AT chip sends the current air quality data to the mobile client 5 through the wireless communication circuit 4 for display, which assists the user in improving the air quality.

Fig. 6 schematically shows the principle of the wireless communication circuit in the intelligent luminaire control system shown in fig. 1.

Referring to fig. 6, an ESP8266-S1 chip is selected as a WiFi module of the wireless communication circuit 4, the ESP8266-S1 chip integrates a tencilica L106 ultra-low power consumption 32-bit micro MCU in the industry in a small-sized package, has a 16-bit simplified mode, supports 80MHz and 160MHz for main frequencies, supports an RTOS, integrates Wi-Fi MAC/BB/RF/PA/LNA and an onboard antenna, and supports a standard IEEE802.11 b/g/n protocol and a complete TCP/IP protocol stack, and can use the WiFi module to add a networking function to a lamp.

Referring to fig. 6, pin TXD1 of the ESP8266-S1 chip is connected with pin P30 of the HC5F20AT chip, and pin RXD1 of the ESP8266-S1 chip is connected with pin P31 of the HC5F20AT chip, so that bidirectional communication between the HC5F20AT chip and the ESP8266-S1 chip is realized.

The mobile client 5 is wirelessly connected with the ESP8266-S1 chips and is in two-way communication, the mobile client 5 can interact with the HC5F20AT chip through the ESP8266-S1 chips, so that the operation of the lighting circuit a21 (yellow LED lamp group), the lighting circuit B22 (white LED lamp group), the anion generator in the anion generating circuit 3 and the MAQ300C chip in the environment monitoring circuit 6 can be realized, and the lighting, anion function and environment monitoring function can be intelligently started through the mobile client 5.

The mobile client 5 can be a mobile phone with a corresponding APP, and the lighting, the anion function and the environment monitoring function of the lamp can be started intelligently through the corresponding APP on the mobile phone.

After the anion function is started through the corresponding APP intelligence on the mobile phone, the APP interface on the mobile client 5 can display the accumulated release anion duration curve.

After starting the environmental monitoring function through corresponding APP intelligence on the cell-phone, the APP's on the mobile client 5 interface can in time show air quality data, air quality statistical chart, and the environmental monitoring time can be set for on APP, if set for 15 minutes.

Fig. 7 schematically illustrates the principle of the indicator light set in the intelligent light fixture control system shown in fig. 1.

Referring to fig. 7, the indicating lamp set 9 includes a light emitting diode D1, a light emitting diode D2, a light emitting diode D3, a light emitting diode D4, a light emitting diode D5, R11, R12, R13, R14, and R15.

Referring to fig. 7, one pin of the led D1 is connected to pin P10 of the HC5F20AT chip through R11(R11 ═ 1K), and the other pin of the led D1 is connected to a 3.3V power supply, so that the led D1 lights up when the anion generating circuit 3 operates.

Referring to fig. 7, one pin of the led D2 is connected to pin P14 of the HC5F20AT chip through R12(R12 ═ 1K), and the other pin of the led D2 is connected to the 3.3V power supply, so that the led D2 lights up when the brightness of the lighting circuit is in the reading mode.

Referring to fig. 7, one pin of the led D3 is connected to pin P13 of the HC5F20AT chip through R13(R13 ═ 1K), and the other pin of the led D3 is connected to the 3.3V power supply, so that the led D3 lights up when the brightness of the lighting circuit is in the office mode.

Referring to fig. 7, one pin of the led D4 is connected to pin P12 of the HC5F20AT chip through R14(R14 ═ 1K), and the other pin of the led D4 is connected to the 3.3V power supply, so that the led D4 lights up when the brightness of the lighting circuit is in the relaxation and leisure mode.

Referring to fig. 7, one pin of the led D5 is connected to pin P11 of the HC5F20AT chip through R15(R15 ═ 1K), the other pin of the led D5 is connected to the 3.3V power supply, and the led D5 lights up when the brightness of the lighting circuit is in the sleep mode.

When different functions are realized, corresponding indicator lights are lighted, so that a user can observe and know conveniently, and when the corresponding functions stop working, the corresponding indicator lights are turned off.

Fig. 8 to 10 schematically show the structure of an intelligent lamp according to an embodiment of the present invention.

Referring to fig. 8 to 10, the intelligent luminaire includes a luminaire body 101 and an intelligent luminaire control system. The intelligent light fixture control system is mounted on the light fixture body 101.

Referring to fig. 8, the lamp body 101 includes a base 1011, a base 1012 and a support rod 1013, wherein a lower end of the support rod 1013 is mounted on the base 1011, a lower end of the support rod 1013 is rotatably connected to the base 1011, and an upper end of the support rod 1013 is rotatably connected to the base 1012.

Referring to fig. 9, the touch circuit 1, the anion generating circuit 3, the wireless communication circuit 4, the environment monitoring circuit 6, the driving circuit a7, the driving circuit B8, and the indicator light group 9 of the intelligent lamp control system are all integrated ON the PCB board 1014 of the lamp body 101, the inductive probe 1015 of the MAQ300C chip of the environment monitoring circuit 6 is exposed from the base 1011 for detecting the quality of air, the anion generator 1016 of the anion generating circuit 3 is installed in the base 1011, the switch "ION" key 1017 of the anion generating circuit 3 is installed ON the base 1011, the switch "ON/OFF" key 1018 for illumination is also installed ON the base 1011, the "ION" key 1017 may be hollow, and the air anions generated by the anion generator 1016 may be released into the air through the hollow ON the "ION" key 1017.

Referring to fig. 10, a lighting circuit a21 (yellow LED lamp group) and a lighting circuit B22 (white LED lamp group) are mounted on the lamp head 1012, the yellow LED lamp group and the white LED lamp group are alternately arranged, and the alternate arrangement of the yellow LED lamp group and the white LED lamp group can make the mixed light emitted by the lighting circuit more uniform.

Referring to fig. 10, in the present embodiment, the yellow LED lamp set and the white LED lamp set are arranged in the following manner: four LEDs are arranged in each row, 12 rows of LEDs are provided, the first column and the third column in the first row are yellow LED lamps, the second column and the fourth column in the first row are white LED lamps, the first column and the third column in the second row are white LED lamps, the second column and the fourth column in the second row are yellow LED lamps, the first column and the third column in the third row are yellow LED lamps, the second column and the fourth column in the third row are white LED lamps, and so on, the yellow LED lamp groups and the white LED lamp groups are alternately arranged on the lamp head 1012. In other embodiments, the arrangement of the yellow LED lamp set and the white LED lamp set can be adjusted according to the lighting requirement.

Referring to fig. 9, the number of the brightness step keys 11 on the touch circuit 1 is five, which are GN1, GN2, GN3, GN4, and GN5, the five brightness step keys 11 are distributed on the base 1011, and are touch type, the five brightness step keys 11 control the brightness of the yellow LED lamp group and the white LED lamp group, and according to the lighting requirement, the user can adjust the brightness of the fifth step: GN1, GN2, GN3, GN4, GN 5.

Referring to fig. 9, the number of the mode keys 12 on the touch circuit 1 is four, which are READ keys, WORK keys, RELAX keys, and NIGHT keys, the READ keys, the WORK keys, the RELAX keys, and the NIGHT keys are distributed on the base 1011 and are touch type, and the mode keys 12 control the color temperatures of the yellow LED lamp set and the white LED lamp set; when a user READs the lamp, the user can touch the READ key, when the user WORKs, the user can touch the WORK key, when the user relaxes, the user can touch the RELAX key, when the user sleeps, the user can touch the NIGHT key, different scenes can select proper lighting modes, and the use experience of the user on the lamp is improved.

The READ key, the WORK key, the RELAX key and the NIGHT key respectively correspond to different yellow light brightness duty ratios and white light brightness duty ratios, and the color temperatures of five gears and the brightness duty ratios of all the gears of the yellow light LED lamp set and the white light LED lamp set are shown in the following table:

referring to fig. 9, the negative ion switch key 13 on the touch circuit 1 is disposed on the base 1011, and is of a touch type, and when the air quality needs to be improved, the negative ion switch key 13 is touched.

Install corresponding APP on the cell-phone, through corresponding APP on the cell-phone can intelligent start lamps and lanterns illumination, anion function, environmental monitoring function.

Initially powered up, none of the yellow LED light bank, white LED light bank, and indicator light bank 9 are on, and both the ionizer 1016 and the MAQ300C of the environmental monitoring circuit 6 are off by default. The switch "ON/OFF" key 1018 of the illumination and the switch "ION" key 1017 of the anion do not interfere with each other, can turn ON the yellow LED lamp group and the white LED lamp group when touching any mode key 12, and light up with the corresponding color temperature brightness of the key;

after power-ON, if the lamp is turned ON by pressing an ON/OFF key 1018 for the first time, the yellow LED lamp group and the white LED lamp group are lighted at four-grade brightness in a RELAX mode, meanwhile, the light-emitting diode D4 is lighted up, after power-ON, the LED lamp group enters any color temperature mode for the first time, and the initial brightness is the four-grade brightness in the mode;

when any one of the WORK key, the READ key, the RELAX key and the NIGHT key is touched, the yellow LED lamp set and the white LED lamp set can be adjusted to the color temperature corresponding to the key, meanwhile, the indicator lamps corresponding to the key are on, and the indicator lamps corresponding to the other three keys are off to indicate the current color temperature state;

GN1, GN2, GN3, GN4 and GN5 are brightness adjusting keys, and can be controlled by single-point touch or sliding touch; when the single-point touch is carried out, which key is touched, the brightness of the yellow LED lamp group and the white LED lamp group can be changed into the brightness corresponding to the key, and when the single-point touch is carried out, the brightness is changed from the sliding initial position to the brightness corresponding to the sliding termination position;

under the condition of no power failure, the brightness value in each color temperature mode is memorized and stored when the color temperature mode is tuned away from the mode, and the lamp is lightened according to the stored brightness when the color temperature mode is entered again;

when the yellow LED lamp group and the white LED lamp group are ON, the yellow LED lamp group and the white LED lamp group can be turned OFF by pressing the "ON/OFF" key 1018 for a short time (key duration <550mS), the "ON/OFF" key 10S is pressed for a long time, all the indicator lamps (D1, D2, D3, D4 and D5) start flashing, the APP system ON the mobile phone enters the distribution network state, when the WiFi module ESP8266-S1 chip responds, the indicator lamps (D1, D2, D3, D4 and D5) start to race, when any key is pressed, no distribution network is used, the indicator lamps (D1, D2, D3, D4 and D5) start to flash for three times and return to the state before the distribution network, the distribution network in 60S succeeds, all the indicator lamps (D1, D2, D3, D4 and D5) flash, the indicator lamps (D10172, D1 and D1, 1) return to the state before the distribution network, the distribution network successfully pressed for five times, and the key 3610 is equal to the state after the key 72 is pressed, the distribution network mode can be released;

switching on and off the lamp and dimming brightness buffering, wherein the buffering time from the dimming buffering to 100% is 1S, and the buffering of other brightness sections is distributed according to equal ratio;

the intelligent lamp has a function of memorizing the state without power failure (can be set by an HC5F20AT chip), under the condition of power failure, the color temperature brightness of the yellow LED lamp group and the white LED lamp group can be memorized and stored when the lamp is turned OFF by pressing an ON/OFF key 1018 every time, and the yellow LED lamp group and the white LED lamp group can be lighted up by the color temperature brightness before the lamp is turned OFF by pressing the ON/OFF key 1018 again;

touching the negative ION switch "ION" key 1017, the negative ION enable terminal (pin P06 of HC5F20AT chip) outputs high level, at the same time lights up the negative ION function indicator lamp D1, touching again, the negative ION enable terminal (pin P06 of HC5F20AT chip) outputs low level, at the same time lights off the negative ION function indicator lamp D1;

fig. 11 schematically shows an interface display on the mobile client after the intelligent luminaire shown in fig. 8 interacts with the mobile client.

The intelligent lamp is also controlled by the APP on the mobile phone through the WiFi module ESP8266-S1 chips;

referring to fig. 11, the switching on/off, mode adjustment (reading mode, office mode, leisure mode, sleep mode), brightness adjustment (GN 1-GN 5 five-grade), color temperature adjustment of the yellow LED light group and the white LED light group can be controlled by the APP on the mobile phone, if the yellow LED lamp set and the white LED lamp set are controlled by the touch key, the HC5F20AT chip of the touch circuit 1 feeds back to the APP to display the current states of the yellow LED lamp set and the white LED lamp set on the APP interface, the yellow LED lamp set and the white LED lamp set can be subjected to grading color mixing and grading brightness mixing through the APP on the mobile phone, when the APP sends out a color temperature (or brightness) adjusting instruction, the yellow light LED lamp group and the white light LED lamp group change correspondingly, after the instruction is finished, the yellow light LED lamp group and the white light LED lamp group stay in the current state, do not change after reaching the highest or lowest color temperature (or brightness), and can only be adjusted reversely;

referring to fig. 11, the APP on the mobile phone can control the on/off of the negative ions, and at the same time, an APP interface displays a duration curve of cumulative release of the negative ions, and only the APP can control the on/off of the MAQ300C chip of the environment monitoring circuit 6, the enable terminal of the powered default environment monitoring circuit 6 (pin P05 of the HC5F20AT chip) is turned off, after the powered default environment monitoring circuit is turned on, the pin P05 of the HC5F20AT chip outputs a high level, the working data of the MAQ300C chip is fed back to the pin P32 of the HC5F20AT chip through the a port of an output signal port of the chip, the HC5F20AT chip can timely send the current air quality data to the APP of the mobile phone through the WiFi module ESP8266-S1 chip, the APP interface timely displays the air quality data and an air quality statistical chart, and the environment monitoring time;

after the anion release duration and the air quality detection data are associated with the date, the anion release duration and the air quality detection data can be stored in an HC5F20AT chip of the intelligent lamp for a plurality of mobile phones to call historical data.

The intelligent lamp of the invention is characterized in that after the lamp is started, the wireless communication circuit 4 and the environment monitoring circuit 6 are tested: when a power supply is plugged, one finger presses a working mode key for about 3 seconds, a corresponding working mode indicator lamp is turned on, then a sleeping mode key 5 is clicked at the same time, each corresponding sleeping mode lamp flashes, two fingers are loosened at the same time, a yellow light LED lamp group and a white light LED lamp group can work for one cycle from a reading mode to a sleeping mode and from first-gear brightness to fifth-gear brightness, after one cycle of lighting work is finished, each mode lamp (D1, D2, D3 and D4) can start the running water horse lamp state for about 3 minutes, when a fault is detected in an environment monitoring circuit 6, the yellow light LED lamp group flashes, when a fault is detected in a wireless communication circuit 4, the white light LED lamp group flashes, if the fault is detected in the environment monitoring circuit 6 and the wireless communication circuit 4, the yellow light LED lamp group and the white light LED lamp group flash together.

The intelligent lamp can realize integration of intelligent illumination, an anion function and environment monitoring, can ensure illumination requirements, can monitor air quality, improve air quality and realize multiple functions of the lamp, and can intelligently start the illumination, the anion function and the environment monitoring function through the mobile client, so that the use experience of a user on the intelligent lamp is improved.

What has been described above are merely some embodiments of the present invention. It will be apparent to those skilled in the art that various changes and modifications can be made without departing from the inventive concept thereof, and these changes and modifications can be made without departing from the spirit and scope of the invention.

Claims (10)

1. The intelligent lamp control system is characterized by comprising a touch circuit (1), a lighting circuit, a negative ion generating circuit (3), a wireless communication circuit (4) and a mobile client (5), wherein,

the touch control circuit (1) is connected with the lighting circuit, the touch control circuit (1) outputs a control instruction to the lighting circuit,

the touch control circuit (1) is connected with the anion generating circuit (3), the touch control circuit (1) outputs a switch instruction to the anion generating circuit (3),

the touch control circuit (1) is connected with the wireless communication circuit (4), and the mobile client (5) interacts with the touch control circuit (1) through the wireless communication circuit (4) to realize the operation of the lighting circuit and the anion generating circuit (3).

2. The intelligent lamp control system according to claim 1, further comprising an environment monitoring circuit (6), wherein the touch control circuit (1) is connected with the environment monitoring circuit (6),

the mobile client (5) interacts with the touch control circuit (1) through the wireless communication circuit (4) to realize the operation of the environment monitoring circuit (6),

the environment monitoring circuit (6) outputs the detected air quality signal to the touch control circuit (1), and the touch control circuit (1) sends the current air quality data to the mobile client (5) through the wireless communication circuit (4).

3. The intelligent luminaire control system of claim 2 wherein the environment monitoring circuit (6) is implemented using a MAQ300C chip.

4. The intelligent light fixture control system of claim 1 further comprising a driver circuit A (7) and a driver circuit B (8),

the touch control circuit (1) is connected with the drive circuit A (7), the touch control circuit (1) is connected with the drive circuit B (8),

the lighting circuit comprises a lighting circuit A (21) and a lighting circuit B (22), the color of light emitted by the lighting circuit A (21) is different from the color of light emitted by the lighting circuit B (22),

the drive circuit A (7) is connected with the lighting circuit A (21), and the drive circuit B (8) is connected with the lighting circuit B (22).

5. The intelligent lamp control system according to claim 4, wherein the driving circuit A (7) and the driving circuit B (8) both use PT4115 chips.

6. The intelligent lamp control system according to claim 4, wherein the lighting circuit A (21) is a yellow LED lamp set, the lighting circuit B (22) is a white LED lamp set, and the yellow LED lamp set and the white LED lamp set are arranged in a staggered manner.

7. The intelligent lamp control system according to any one of claims 1-6, wherein the touch circuit (1) is an HC5F20AT chip;

preferably, the wireless communication circuit (4) adopts an ESP8266-S1 chip;

preferably, the negative ion generator in the negative ion generating circuit (3) is south cypress NB-C.

8. The intelligent lamp control system according to any one of claims 1-6, wherein a brightness gear key (11) is arranged on the touch circuit (1), and the brightness gear key (11) controls the brightness of the lighting circuit;

preferably, the number of the brightness shift keys (11) is five, and the keys are GN1, GN2, GN3, GN4 and GN 5.

9. The intelligent lamp control system according to any one of claims 1-6, wherein a mode key (12) and an anion switch key (13) are arranged on the touch circuit (1), the mode key (12) controls the color temperature of the lighting circuit, and the anion switch key (13) controls the on-off of the anion generating circuit (3);

preferably, the number of the mode keys (12) is four, namely a READ key, a WORK key, a RELAX key and a NIGHT key.

10. The intelligent lamp is characterized by comprising a lamp body and the intelligent lamp control system as claimed in any one of claims 1 to 9, wherein the intelligent lamp control system is arranged on the lamp body.

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