CN210804128U - Intelligent temperature control water cup - Google Patents

Abstract

The utility model discloses an intelligent temperature control water cup, which is provided with a controller, the controller is electrically connected with a crystal oscillator circuit, a power supply module and a light sensor, the outer surface of the water cup is provided with a light display circuit, the light display circuit is electrically connected with the output end of the controller, the controller is provided with a preset brightness value, the power supply module supplies power for the whole circuit, the clock frequency required by the work of the controller is provided by the crystal oscillator circuit, the light sensor is used for detecting the brightness of the current environment, the controller is used for controlling the whole circuit and processing data, the light display circuit is used for providing the light illumination effect, so that a user can find the water cup without turning on the light, when the brightness value of the current environment is not more than the preset brightness value, the light sensor sends a signal to the controller, the controller controls the light display circuit, the light source does not need to be turned on manually, so that a user can find the water cup conveniently for use, and the water cup is very simple and convenient.

Description

Intelligent temperature control water cup

Technical Field

The utility model relates to a drinking cup, especially an intelligence control by temperature change drinking cup.

Background

Chinese patent CN202739536U discloses a temperature-regulating cup, which comprises a cup body and a cup cover, wherein the cup cover covers the cup body, the cup body is divided into an upper cup body and a lower cup body, the upper and lower cup bodies are clamped and connected, a stop spring pin is arranged at one side of the joint, the upper cup body is a single-layer body, the lower cup body is a double-layer heat insulation body, a projected water outlet is arranged at the upper end of the lower cup body, a sealing ring is arranged at the contact part of the projected water outlet and the upper cup body, the cup body is divided into an upper body and a lower body, the upper part is a single; the lower extreme is double-deck heat preservation cup, place hot water, can protect the temperature, lower body protrusion delivery port can be with leading-in upper cup of hot water, adjust the temperature in the upper cup, compare current ordinary cup, can keep warm winter and use, relative thermos cup drinks water, adjustable suitable temperature drinks, convenient and practical, however, this realization temperature regulation in the cup needs to utilize the water in the lower cup to come the temperature in the neutralization regulation upper cup, in the in-process of neutralization, inevitably can make the temperature in the lower cup reduce, after adjusting the temperature many times, the temperature in the lower cup can be unanimous with the temperature in the upper cup very fast, thereby play the effect of adjusting the temperature.

Chinese utility model patent CN204600096U discloses an intelligence coaster that adjusts temperature, be provided with microprocessor unit module in the coaster, temperature control module, touch-sensitive screen display module, switch module and power module, temperature control module can heat the coaster and measure the temperature of current coaster, give microprocessor unit module with temperature data transfer, microprocessor unit module and then give the temperature that touch-sensitive screen display module shows current coaster with temperature data transfer, thereby this cup mat that adjusts temperature only can heat the water in the cup on the coaster, and the function of cooling does not, can only carry out natural cooling when needs drink cold water, but the cooling process that the coaster can delay hot water on the contrary on the coaster under the drinking cup, reduce the cooling effect.

The Chinese utility model patent CN205338463U discloses an intelligent temperature-regulating water cup, wherein a microprocessor control module, a touch screen display control module, a temperature detection module, a heating module, a refrigeration module, a wifi module, a software APP module and a power module are arranged on the cup body; the microprocessor control module is connected with the temperature detection module, collects the current temperature and transmits the current temperature to the touch screen display control module for display; the touch screen display control module is connected with the microprocessor control module to carry out bidirectional communication of data and control signals; the microprocessor control module is connected with the heating module and the refrigerating module through the switch module; the wifi module realizes two-way communication between microprocessor control module and the software APP module as communication module, carries out comparison judgement according to the temperature that touch screen display control module set up and current temperature, then selects to open heating module and heaies up or the refrigeration module cools down, realizes the accurate control to the temperature, when the luminance ratio of surrounding environment is lower, if the user wants to drink water, just need manually to open the light source and just can find this drinking cup (for example can find this drinking cup if turning on the light), it is not very convenient.

Disclosure of Invention

In order to overcome the defects of the prior art, the utility model provides an intelligent temperature control water cup with a light display effect, a heating function, a cooling function and a water temperature.

The utility model provides a technical scheme that its technical problem adopted is:

the utility model provides an intelligence control by temperature change drinking cup, the drinking cup is provided with the controller, the input electric connection of controller has crystal oscillator circuit and power module, the input of controller still electric connection has light sensor CK1, the surface of drinking cup is provided with light display circuit, light display circuit with the output electric connection of controller, the controller is provided with the luminance default.

The controller is a single chip microcomputer U1, the model of the single chip microcomputer U1 is STM32F103RCT6, the model of the light ray sensor CK1 is CK003, a first pin of the light ray sensor CK1 is electrically connected with a fifteenth pin of the single chip microcomputer U1, a second pin of the light ray sensor CK1 is connected with a +3.3V direct current output end, a third pin of the light ray sensor CK1 is divided into three paths, the first path is grounded, the second path is connected with one end of a capacitor C23, one end of a third connecting resistor R42 is connected, and the other end of the capacitor C23 and the other end of the resistor R42 are both connected with a node between the first pin of the light ray sensor CK1 and the fifteenth pin of the single chip microcomputer U1.

The input end of the controller is electrically connected with a temperature sensor DS18, the temperature sensor DS18 is arranged in the water cup, the type of the temperature sensor DS18 is DS18B20, a first pin of the temperature sensor DS18 is connected with a +3.3V direct current output end, a second pin of the temperature sensor DS18 is divided into two paths, one path is connected with a node between the first pin of the temperature sensor DS18 and the +3.3V direct current output end through a resistor R12, the other path is connected with a fourteenth pin of the single chip microcomputer U1, and a third pin of the temperature sensor DS18 is grounded.

The output end of the controller is electrically connected with two switching circuits, the output end of one switching circuit is electrically connected with a heating component HT1, the output end of the other switching circuit is electrically connected with a refrigerating component HT2, the heating component HT1 surrounds the outer surface of the water cup, the refrigerating component HT2 is arranged at the bottom of the water cup, one switching circuit comprises a relay J8, a diode D7, an NPN type triode Q2, a resistor R10 and a resistor R9, a first pin of the relay J8 is divided into two paths, one path is connected with the collector electrode of the NPN type triode Q2, the other path is connected with the anode of the diode D7, a second pin of the relay J8 is connected with a +12V direct current output end, a fourth pin of the relay J8 is divided into two paths, one path is connected with the cathode of the diode D7, the other path is connected with a +5V direct current output end, a fifth pin of the relay J8 is connected with the anode input end of the heating component, one end of the resistor R10 is divided into two paths, one path is connected with the base electrode of the NPN type triode Q2, the other path is connected with the forty-fourth pin of the singlechip U1 through the resistor R9, the other end of the resistor R10 is divided into two paths, one path is grounded, and the other path is connected with the emitter electrode of the NPN type triode Q2; the other switching circuit comprises a relay J9, a diode D8, an NPN triode Q3, a resistor R14 and a resistor R3, wherein a first pin of the relay J9 is divided into two paths, one path is connected with a collector of the NPN triode Q3, the other path is connected with an anode of the diode D8, a second pin of the relay J9 is connected with a +12V direct current output end, a fourth pin of the relay J9 is divided into two paths, one path is connected with a cathode of the diode D8, the other path is connected with a +5V direct current output end, a fifth pin of the relay J9 is connected with an anode input end of the refrigerating assembly HT2, one end of the resistor R14 is divided into two paths, one path is connected with a base of the NPN triode Q3, the other path is connected with a fifth forty pin of the singlechip U1 through the resistor R13, the other end of the resistor R14 is divided into two paths, one path is grounded, and the other path is connected with an emitter of the, the negative input end of the heating assembly HT1 and the negative input end of the refrigerating assembly HT2 are both grounded.

The heating assembly HT1 is the silicon rubber heater wire, refrigeration assembly HT2 is the thermoelectric cooling piece, the model of thermoelectric cooling piece is TEC 1-12705.

The bottom of drinking cup still is provided with fin and radiator fan, refrigeration subassembly HT2, fin and radiator fan set gradually from top to bottom the bottom of drinking cup.

The input end of the controller is also electrically connected with a temperature and humidity sensor DHT1, the temperature and humidity sensor DHT1 is DHT11 in model, the temperature and humidity sensor DHT1 is arranged on the outer surface of the water cup, a first pin of the temperature and humidity sensor DHT1 is connected with a +3.3V direct current output end, a second pin of the temperature and humidity sensor DHT1 is divided into two paths, one path is connected with a node between the first pin of the temperature and humidity sensor DHT1 and the +3.3V direct current output end through a resistor R11, the other path is connected with a seventeenth pin of the single-chip microcomputer U1, and a third pin and a fourth pin of the temperature and humidity sensor DHT1 are both grounded.

The output end of the controller is electrically connected with a display module and an alarm module, the display module and the alarm module are both arranged on the outer surface of the water cup, the display module is a touch display screen LCD, a first pin of the touch display screen LCD is connected with a fortieth pin of the singlechip U1, a second pin of the touch display screen LCD is connected with a thirty-ninth pin of the singlechip U1, a third pin of the touch display screen LCD is connected with a thirty-eight pin of the singlechip U1, a fourth pin of the touch display screen LCD is connected with a thirty-seventh pin of the singlechip U1, a fifth pin of the touch display screen LCD is connected with a seventh pin of the singlechip U1, a sixth pin of the touch display screen LCD is connected with a twenty-sixth pin of the singlechip U1, and the seventh pin of the touch display screen LCD is connected with a twenty-seventh pin of the singlechip U1, an eighth pin of the touch display screen LCD is connected with a twenty-eighth pin of the singlechip U1, a ninth pin of the touch display screen LCD is connected with a fifty-fifth pin of the singlechip U1, a tenth pin of the touch display screen LCD is connected with a fifty-sixth pin of the singlechip U1, an eleventh pin of the touch display screen LCD is connected with a fifty-seventh pin of the singlechip U1, a twelfth pin of the touch display screen LCD is connected with a fifty-eighth pin of the singlechip U1, a thirteenth pin of the touch display screen LCD is connected with a fifty-ninth pin of the singlechip U1, a fourteenth pin of the touch display screen LCD is connected with a sixty-one pin of the singlechip U1, a fifteenth pin of the touch display screen LCD is connected with a sixty-second pin of the singlechip U1, a sixteenth pin of the touch display screen LCD is connected with a twenty ninth pin of the singlechip U1, a seventeenth pin of the touch display screen LCD is connected with a thirty fourth pin of the singlechip U1, an eighteenth pin of the touch display screen LCD is connected with a thirty third pin of the singlechip U1, a nineteenth pin of the touch display screen LCD is connected with a thirty fourth pin of the singlechip U1, a twentieth pin of the touch display screen LCD is connected with a thirty fifth pin of the singlechip U1, a twenty eighth pin of the touch display screen LCD is connected with a thirty sixth pin of the singlechip U1, a twenty second pin, a twenty sixth pin and a twenty seventh pin of the touch display screen LCD are connected together, a twenty third pin of the touch display screen LCD is connected with a first pin of the singlechip U1, a twenty-fourth pin of the touch display screen LCD is connected with a +3.3V direct current output end, a twenty-fifth pin of the touch display screen LCD is connected with a +3.3V direct current output end, a twenty-eighth pin of the touch display screen LCD is connected with a +5V direct current output end, a twenty-ninth pin of the touch display screen LCD is connected with a tenth pin of the singlechip U1, a thirtieth pin of the touch display screen LCD is connected with an eleventh pin of the singlechip U1, a thirty-first pin of the touch display screen LCD is connected with a ninth pin of the singlechip U1, a thirty-third pin of the touch display screen LCD is connected with a second pin of the singlechip U1, and a thirty-fourth pin of the touch display screen LCD is connected with an eighth pin of the singlechip U1; the alarm module comprises a resistor R16, an NPN triode Q1, a resistor R21, a diode D6 and a buzzer B2, wherein the cathode of the diode D6 and one end of the buzzer B2 are both connected with a +5V direct current output end, the collector of the NPN triode Q1 is divided into two paths, one path is connected with the anode of the diode D6, the other path is connected with the other end of the buzzer B2, one end of the resistor R21 is divided into two paths, one path is connected with the twenty-fourth pin of the singlechip U1 through the resistor R16, the other path is connected with the base of the NPN triode Q1, the other end of the resistor R21 is divided into two paths, the other path is grounded, and the other path is connected with the emitter of the NPN triode Q1.

The controller is further electrically connected with a WIFI module, a reset circuit and a standby power supply, the WIFI module includes a WIFI chip U5, a capacitor C27, a capacitor C26, a resistor R5, a resistor R3, a resistor R6, a diode D23, a resistor R36, a resistor R37, a resistor R38, a resistor R41 and a resistor R29, the model ESP of the WIFI chip U5 is 8266, one end of the resistor R5 is divided into two paths, one path is grounded through the capacitor C27, the other path is connected with a +5V dc output terminal, one end of the resistor R3 is divided into three paths, the first path is connected with a node between one end of the resistor R5 and the capacitor C27, the second path is connected with an eighth pin of the WIFI chip U5, the third path is grounded through the capacitor C26, the other end of the resistor R5 is connected with the first pin of the WIFI chip U5, the other end of the resistor R5 is connected with the third pin of the dc chip U5, the eighteen pin of the WIFI chip U5 is connected with the eighteen V output terminal of the WIFI chip U5, one end of the resistor R29 is connected with a sixteenth pin of the WIFI chip U5, the other end of the resistor R29 is divided into three paths, the first path is connected with a fifteenth pin of the WIFI chip U5, the second path is grounded, the third path is connected with a +5V direct current output end, the twenty-first pin of the WIFI chip U5 is connected with the anode of the diode D23, the cathode of the diode D23 is divided into two paths, one path is connected with the +5V direct current output end through the resistor R37, the other path is connected with the forty-second pin of the singlechip U1 through the resistor R41, the twenty-second pin of the WIFI chip U5 is divided into two paths, one path is connected with the +5V direct current output end through the resistor R38, the other path is connected with the forty-third pin of the singlechip U1 through the resistor R36, the RESET circuit comprises a resistor R25, a RESET key and a capacitor C7, and one end of the resistor R25 is connected with a sixteenth pin, One end of a RESET key RESET and one end of a capacitor C7 are both connected with a seventh pin of the single chip microcomputer U1, the other end of the resistor R25 is connected with a +3.3V direct current output end, the other end of the RESET key RESET and the other end of the capacitor C7 are both grounded, the standby power supply comprises a storage battery BAT2, a diode D9 and a diode D10, the cathode of the diode D9 and the cathode of the diode D10 are both connected with a first pin of the single chip microcomputer U1, the anode of the diode D9 is connected with the anode of the storage battery BAT2, the cathode of the storage battery BAT2 is grounded, and the anode of the diode D10 is connected with a +3.3V direct current output end.

The crystal oscillator circuit comprises a crystal oscillator X1, a capacitor C15, a capacitor C11, a crystal oscillator X2, a capacitor C16 and a capacitor C17, one end of the crystal oscillator X1 is divided into two paths, one path is connected with the third pin of the singlechip U1, the other path is grounded through the capacitor C15, the other end of the crystal oscillator X1 is divided into two paths, one path is connected with the 4 pin of the singlechip U1, the other path is grounded through the capacitor C11, one end of the crystal oscillator X2 is divided into two paths, one path is connected with the fifth pin of the singlechip U1, the other path is grounded through the capacitor C16, the other end of the crystal oscillator X2 is divided into two paths, one path is connected with the sixth pin of the singlechip U1, the other path is grounded through the capacitor C17, the lamp light display circuit comprises a light emitting diode D1, a resistor R36 2, a light emitting diode D3687458, a resistor R1, a light emitting diode D1 and a direct current resistor R1, the positive pole of the light emitting diode D1 is connected with the output, the positive pole of the light emitting diode D2 is connected with a +3.3V direct current output end through the resistor R1, the positive pole of the light emitting diode D3 is connected with a +3.3V direct current output end through the resistor R4, the negative pole of the light emitting diode D1 is connected with the forty-first pin of the singlechip U1, the negative pole of the light emitting diode D2 is connected with the twentieth pin of the singlechip U1, and the negative pole of the light emitting diode D3 is connected with the fifty-fourth pin of the singlechip U1.

The utility model has the advantages that: the utility model discloses a power module is the power supply of whole circuit, the required clock frequency of controller during operation is provided by the crystal oscillator circuit, light sensor CK1 is used for detecting the luminance of current environment, the controller is used for controlling whole circuit and processing data, light display circuit is used for providing light illuminating effect, make the user need not turn on the light can find the drinking cup, when the luminance value of current environment is not more than the luminance default, light sensor CK1 sends a signal and gives the controller, controller control light display circuit, make light display circuit send light, do not need the manual light source of opening, convenience of customers finds the drinking cup and uses, and is very simple and convenient.

Drawings

The present invention will be further explained with reference to the drawings and examples.

FIG. 1 is a block diagram of the system of the present invention;

fig. 2 is a first schematic circuit diagram of the present invention;

fig. 3 is a second schematic circuit diagram of the present invention;

fig. 4 is a third schematic circuit diagram of the present invention;

fig. 5 is a fourth schematic circuit diagram of the present invention;

fig. 6 is a fifth schematic circuit diagram of the present invention.

Detailed Description

Referring to fig. 1 to 6, an intelligent temperature control water cup is provided with a controller, an input end of the controller is electrically connected with a crystal oscillator circuit and a power supply module, an input end of the controller is also electrically connected with a light sensor CK1, a light display circuit is arranged on the outer surface of the water cup and is electrically connected with an output end of the controller, the controller is provided with a preset brightness value, the power supply module supplies power to the whole circuit, a clock frequency required by the controller during working is provided by the crystal oscillator circuit, the light sensor CK1 is used for detecting the brightness of the current environment, the controller is used for controlling the whole circuit and processing data, the light display circuit is used for providing a light illumination effect, so that a user can find the water cup without turning on the light, when the brightness value of the current environment is not more than the preset brightness value, the light sensor CK1 sends a signal to the, the controller controls the light display circuit, so that the light display circuit emits light, a light source does not need to be manually turned on, a user can find the water cup conveniently, the water cup is simple and convenient to use, the water cup and an existing water cup are of the same structure, and the water cup is made of aluminum.

The controller is a single chip microcomputer U1, the single chip microcomputer U1 is STM32F103RCT6, the light sensor CK1 is CK003, a first pin of the light sensor CK1 is electrically connected with a fifteenth pin of the single chip microcomputer U1, a second pin of the light sensor CK1 is connected with a +3.3V direct current output end, a third pin of the light sensor CK1 is divided into three paths, the first path is grounded, the second path is connected with one end of a capacitor C23 and one end of a third path is connected with one end of a resistor R42, the other end of the capacitor C23 and the other end of the resistor R42 are both connected with a node between the first pin of the light sensor CK1 and the fifteenth pin of the single chip microcomputer U1, the single chip microcomputer U1 is integrated with an analog-to-digital converter, the photoelectric sensor adopts a photoelectric element as a detection element, the measured change is firstly converted into the change of an optical signal, and then the optical signal is further converted into an electric signal by the photoelectric element, the photoelectric sensor generally consists of three parts, namely a light source, an optical path and a photoelectric element.

The input end of the controller is electrically connected with a temperature sensor DS18, the temperature sensor DS18 is arranged in the water cup, the type of the temperature sensor DS18 is DS18B20, a first pin of the temperature sensor DS18 is connected with a +3.3V direct current output end, a second pin of the temperature sensor DS18 is divided into two paths, one path is connected with a node between the first pin of the temperature sensor DS18 and the +3.3V direct current output end through a resistor R12, the other path is connected with a fourteenth pin of the single chip microcomputer U1, a third pin of the temperature sensor DS18 is grounded, the temperature sensor DS18 is used for detecting the water temperature in the water cup, and the temperature sensor DS18 is used for detecting the temperature of the water in the water cup, namely the water temperature.

The output end of the controller is electrically connected with two switching circuits, the output end of one switching circuit is electrically connected with a heating component HT1, the output end of the other switching circuit is electrically connected with a refrigerating component HT2, the heating component HT1 surrounds the outer surface of the water cup, the refrigerating component HT2 is arranged at the bottom of the water cup, one switching circuit comprises a relay J8, a diode D7, an NPN type triode Q2, a resistor R10 and a resistor R9, a first pin of the relay J8 is divided into two paths, one path is connected with the collector electrode of the NPN type triode Q2, the other path is connected with the anode of the diode D7, a second pin of the relay J8 is connected with a +12V direct current output end, a fourth pin of the relay J8 is divided into two paths, one path is connected with the cathode of the diode D7, the other path is connected with a +5V direct current output end, a fifth pin of the relay J8 is connected with the anode input end of the heating component, one end of the resistor R10 is divided into two paths, one path is connected with the base electrode of the NPN type triode Q2, the other path is connected with the forty-fourth pin of the singlechip U1 through the resistor R9, the other end of the resistor R10 is divided into two paths, one path is grounded, and the other path is connected with the emitter electrode of the NPN type triode Q2; the other switching circuit comprises a relay J9, a diode D8, an NPN triode Q3, a resistor R14 and a resistor R3, wherein a first pin of the relay J9 is divided into two paths, one path is connected with a collector of the NPN triode Q3, the other path is connected with an anode of the diode D8, a second pin of the relay J9 is connected with a +12V direct current output end, a fourth pin of the relay J9 is divided into two paths, one path is connected with a cathode of the diode D8, the other path is connected with a +5V direct current output end, a fifth pin of the relay J9 is connected with an anode input end of the refrigerating assembly HT2, one end of the resistor R14 is divided into two paths, one path is connected with a base of the NPN triode Q3, the other path is connected with a fifth forty pin of the singlechip U1 through the resistor R13, the other end of the resistor R14 is divided into two paths, one path is grounded, and the other path is connected with an emitter of the, the negative input end of the heating assembly HT1 and the negative input end of the refrigerating assembly HT2 are grounded, when the current water temperature (water temperature, which is the temperature value of water in a water cup) is lower than a preset water temperature value (a preset water temperature value, namely the temperature of water in the water cup required by a user), the heating assembly HT1 works to generate a large amount of heat to improve the water temperature, when the current water temperature is higher than the preset water temperature value, the refrigerating assembly HT2 works to generate low temperature to low water temperature, specifically, the singlechip U1 controls the heating assembly HT1 and the refrigerating assembly HT2 through two switching circuits, wherein the singlechip U1 controls the relay J8 through an NPN type triode Q2, the relay J8 determines whether the heating assembly HT1 is started, the singlechip U1 controls the relay J9 through an NPN type triode Q3, and the relay J9 determines whether the refrigerating assembly HT2 is.

The heating assembly HT1 is a silicon rubber heating wire, the refrigerating assembly HT2 is a thermoelectric refrigerating piece, the type of the thermoelectric refrigerating piece is TEC1-12705, the silicon rubber heating wire can be used for preventing water and high temperature, heating air, heating water and other occasions with low temperature needing to be heated, the outer skin of the thermoelectric refrigerating piece is soft and can be bent into various types, the thermoelectric refrigerating piece is a heat pump, the thermoelectric refrigerating piece has the advantages that no sliding part is arranged, the thermoelectric refrigerating piece is applied to the occasions with limited space, high reliability requirement and no refrigerant pollution, a radiating fin and a radiating fan are further arranged at the bottom of the water cup, and the refrigerating assembly HT2, the radiating fin and the radiating fan are sequentially arranged at the bottom of the water cup from top to bottom, and the refrigerating assembly HT2, the radiating fin and the.

The input end of the controller is also electrically connected with a temperature and humidity sensor DHT1, the temperature and humidity sensor DHT1 is DHT11 in model, the temperature and humidity sensor DHT1 is arranged on the outer surface of the water cup, a first pin of the temperature and humidity sensor DHT1 is connected with a +3.3V direct current output end, a second pin of the temperature and humidity sensor DHT1 is divided into two paths, one path is connected with a node between the first pin of the temperature and humidity sensor DHT1 and the +3.3V direct current output end through a resistor R11, the other path is connected with a seventeenth pin of the single-chip microcomputer U1, and a third pin and a fourth pin of the temperature and humidity sensor DHT1 are both grounded.

The output end of the controller is electrically connected with a display module and an alarm module, the display module and the alarm module are both arranged on the outer surface of the water cup, the display module is a touch display screen LCD, a first pin of the touch display screen LCD is connected with a fortieth pin of the singlechip U1, a second pin of the touch display screen LCD is connected with a thirty-ninth pin of the singlechip U1, a third pin of the touch display screen LCD is connected with a thirty-eight pin of the singlechip U1, a fourth pin of the touch display screen LCD is connected with a thirty-seventh pin of the singlechip U1, a fifth pin of the touch display screen LCD is connected with a seventh pin of the singlechip U1, a sixth pin of the touch display screen LCD is connected with a twenty-sixth pin of the singlechip U1, and the seventh pin of the touch display screen LCD is connected with a twenty-seventh pin of the singlechip U1, an eighth pin of the touch display screen LCD is connected with a twenty-eighth pin of the singlechip U1, a ninth pin of the touch display screen LCD is connected with a fifty-fifth pin of the singlechip U1, a tenth pin of the touch display screen LCD is connected with a fifty-sixth pin of the singlechip U1, an eleventh pin of the touch display screen LCD is connected with a fifty-seventh pin of the singlechip U1, a twelfth pin of the touch display screen LCD is connected with a fifty-eighth pin of the singlechip U1, a thirteenth pin of the touch display screen LCD is connected with a fifty-ninth pin of the singlechip U1, a fourteenth pin of the touch display screen LCD is connected with a sixty-one pin of the singlechip U1, a fifteenth pin of the touch display screen LCD is connected with a sixty-second pin of the singlechip U1, a sixteenth pin of the touch display screen LCD is connected with a twenty ninth pin of the singlechip U1, a seventeenth pin of the touch display screen LCD is connected with a thirty fourth pin of the singlechip U1, an eighteenth pin of the touch display screen LCD is connected with a thirty third pin of the singlechip U1, a nineteenth pin of the touch display screen LCD is connected with a thirty fourth pin of the singlechip U1, a twentieth pin of the touch display screen LCD is connected with a thirty fifth pin of the singlechip U1, a twenty eighth pin of the touch display screen LCD is connected with a thirty sixth pin of the singlechip U1, a twenty second pin, a twenty sixth pin and a twenty seventh pin of the touch display screen LCD are connected together, a twenty third pin of the touch display screen LCD is connected with a first pin of the singlechip U1, a twenty-fourth pin of the touch display screen LCD is connected with a +3.3V direct current output end, a twenty-fifth pin of the touch display screen LCD is connected with a +3.3V direct current output end, a twenty-eighth pin of the touch display screen LCD is connected with a +5V direct current output end, a twenty-ninth pin of the touch display screen LCD is connected with a tenth pin of the singlechip U1, a thirtieth pin of the touch display screen LCD is connected with an eleventh pin of the singlechip U1, a thirty-first pin of the touch display screen LCD is connected with a ninth pin of the singlechip U1, a thirty-third pin of the touch display screen LCD is connected with a second pin of the singlechip U1, and a thirty-fourth pin of the touch display screen LCD is connected with an eighth pin of the singlechip U1; the alarm module comprises a resistor R16, an NPN triode Q1, a resistor R21, a diode D6 and a buzzer B2, wherein the cathode of the diode D6 and one end of the buzzer B2 are both connected with a +5V direct current output end, the collector of the NPN triode Q1 is divided into two paths, one path is connected with the anode of the diode D6, the other path is connected with the other end of the buzzer B2, one end of the resistor R21 is divided into two paths, one path is connected with the twenty-fourth pin of the singlechip U1 through the resistor R16, the other path is connected with the base of the NPN triode Q1, the other end of the resistor R21 is divided into two paths, the other path is grounded, and the other path is connected with the emitter of the NPN triode Q1; the touch display screen LCD is an LCD display screen and is used for displaying a preset water temperature value, displaying the current water temperature and some prompt information (for example, a red label is set, a green label appears, a heating component HT1 works to improve the water temperature, a green label appears, a refrigerating component HT2 works to reduce the water temperature, a yellow label appears, the current water temperature is equal to the preset water temperature value and can be drunk), obtaining information and using more simply and conveniently, and optimizing user experience; when the current water temperature value is equal to the set water temperature value, the twenty-fourth pin of the single chip microcomputer U1 outputs a low level, the NPN type triode Q1 amplifies current, and therefore the buzzer B2 is driven to alarm, the buzzer B2 alarms, it is shown that the current water temperature value is equal to the set water temperature value, a user can drink the drink water, otherwise, the twenty-fourth pin of the single chip microcomputer U1 outputs a high level, the NPN type triode Q1 is not conducted, and the buzzer B2 does not alarm due to the fact that the current water temperature value is not driven.

Specifically, the singlechip U1 automatically counts time, and at intervals, the singlechip U1 starts the buzzer B2 to remind the user of drinking water.

The controller is further electrically connected with a WIFI module, a reset circuit and a standby power supply, the WIFI module includes a WIFI chip U5, a capacitor C27, a capacitor C26, a resistor R5, a resistor R3, a resistor R6, a diode D23, a resistor R36, a resistor R37, a resistor R38, a resistor R41 and a resistor R29, the model ESP of the WIFI chip U5 is 8266, one end of the resistor R5 is divided into two paths, one path is grounded through the capacitor C27, the other path is connected with a +5V dc output terminal, one end of the resistor R3 is divided into three paths, the first path is connected with a node between one end of the resistor R5 and the capacitor C27, the second path is connected with an eighth pin of the WIFI chip U5, the third path is grounded through the capacitor C26, the other end of the resistor R5 is connected with the first pin of the WIFI chip U5, the other end of the resistor R5 is connected with the third pin of the dc chip U5, the eighteen pin of the WIFI chip U5 is connected with the eighteen V output terminal of the WIFI chip U5, one end of the resistor R29 is connected with a sixteenth pin of the WIFI chip U5, the other end of the resistor R29 is divided into three paths, the first path is connected with a fifteenth pin of the WIFI chip U5, the second path is grounded, the third path is connected with a +5V direct current output end, the twenty-first pin of the WIFI chip U5 is connected with the anode of the diode D23, the cathode of the diode D23 is divided into two paths, one path is connected with the +5V direct current output end through the resistor R37, the other path is connected with the forty-second pin of the singlechip U1 through the resistor R41, the twenty-second pin of the WIFI chip U5 is divided into two paths, one path is connected with the +5V direct current output end through the resistor R38, the other path is connected with the forty-third pin of the singlechip U1 through the resistor R36, the RESET circuit comprises a resistor R25, a RESET key and a capacitor C7, and one end of the resistor R25 is connected with a sixteenth pin, One end of a RESET button RESET and one end of a capacitor C7 are both connected with a seventh pin of the singlechip U1, the other end of the resistor R25 is connected with a +3.3V direct current output end, the other end of the RESET button RESET and the other end of the capacitor C7 are both grounded, the standby power supply comprises a storage battery BAT2, a diode D9 and a diode D10, the cathode of the diode D9 and the cathode of the diode D10 are both connected with a first pin of the singlechip U1, the anode of the diode D9 is connected with the anode of the storage battery BAT2, the cathode of the storage battery BAT2 is grounded, the anode of the diode D10 is connected with a +3.3V direct current output end, the storage battery BAT2 is used for supplying power to a crystal oscillator circuit, so that the crystal oscillator circuit of the singlechip U1 always records time, specifically, the U1 automatically records a set value of the water temperature and automatically records time for setting the water temperature increase or decrease of the water temperature of the singlechip, the temperature and humidity sensor DHT1 is used for detecting data such as temperature value and humidity value of the surrounding environment of the water cup, the single chip microcomputer U1 sends the data to the cloud processor through the WIFI module for processing (the cloud processor and how the cloud processor processes the data belong to the prior art, details are not described here), the cloud processor estimates how much water in a temperature range is needed by a user next time according to the data, an operation rule is formulated, the operation rule is fed back to the single chip microcomputer U1 through the WIFI module, the single chip microcomputer U1 controls the heating assembly HT1 and the refrigerating assembly HT2 according to the operation rule, a proper water temperature is provided before the user uses the next time, the water temperature does not need to be set every time, besides, the WIFI module serves as a communication module, bidirectional communication between the APP client and the single chip microcomputer U1 is achieved, the single chip microcomputer U1 obtains a water temperature set value input by the, and send present temperature to APP customer end through the WIFI module, temperature sensor DS18 cooperates singlechip U1 to detect present temperature always, and when present temperature is less than the water temperature set value, then singlechip U1 starts heating element HT1 and improves the temperature, and if not, singlechip U1 starts refrigeration element HT2 and reduces the temperature, and until present temperature value equals the water temperature set value.

The crystal oscillator circuit comprises a crystal oscillator X1, a capacitor C15, a capacitor C11, a crystal oscillator X2, a capacitor C16 and a capacitor C17, one end of the crystal oscillator X1 is divided into two paths, one path is connected with the third pin of the singlechip U1, the other path is grounded through the capacitor C15, the other end of the crystal oscillator X1 is divided into two paths, one path is connected with the 4 pin of the singlechip U1, the other path is grounded through the capacitor C11, one end of the crystal oscillator X2 is divided into two paths, one path is connected with the fifth pin of the singlechip U1, the other path is grounded through the capacitor C16, the other end of the crystal oscillator X2 is divided into two paths, one path is connected with the sixth pin of the singlechip U1, the other path is grounded through the capacitor C17, the lamp light display circuit comprises a light emitting diode D1, a resistor R36 2, a light emitting diode D3687458, a resistor R1, a light emitting diode D1 and a direct current resistor R1, the positive pole of the light emitting diode D1 is connected with the output, the positive electrode of the light emitting diode D2 is connected to the +3.3V dc output terminal through the resistor R1, the positive electrode of the light emitting diode D3 is connected to the +3.3V dc output terminal through the resistor R4, the negative electrode of the light emitting diode D1 is connected to the forty-first pin of the single chip microcomputer U1, the negative electrode of the light emitting diode D2 is connected to the twentieth pin of the single chip microcomputer U1, the negative electrode of the light emitting diode D3 is connected to the fifty-fourth pin of the single chip microcomputer U1, specifically, the light sensor CK1 outputs an analog signal (voltage or current) to the single chip microcomputer U1, the analog-to-digital converter of the single chip microcomputer U1 converts the analog signal into a digital signal corresponding to the single chip microcomputer U1, and converts the digital signal into a brightness value corresponding to the single chip microcomputer U1, and when the brightness value is not greater than a preset value, the single chip microcomputer 85u 25, The cathode of the light emitting diode D2 and the cathode of the light emitting diode D3 are both low level, the anode of the light emitting diode D1, the anode of the light emitting diode D2 and the anode of the light emitting diode D3 are both high level, that is, the tube voltage drops of the three light emitting diodes (the light emitting diode D1, the light emitting diode D2 and the light emitting diode D3) reach conduction voltage, so that the light emitting diode D1, the light emitting diode D2 and the light emitting diode D3 are lighted, a lighting effect is provided, a user can conveniently search a water cup, when the brightness value is greater than a preset value, the single chip microcomputer U1 outputs high level, and the tube voltage drops of the three light emitting diodes (the light emitting diode D1, the light emitting diode D2 and the light emitting diode D3) are less than the conduction voltage; the crystal oscillator X1, the capacitor C15 and the capacitor C11 form a first parallel resonant circuit, the crystal oscillator X2, the capacitor C16 and the capacitor C17 form a second parallel resonant circuit, and the clock frequency required by the single chip microcomputer U1 during working is provided by the first parallel resonant circuit and the second parallel resonant circuit.

The power supply module comprises a switching power supply J6, a switch S6, a fuse F6, a diode D4 6, a capacitor C6, a voltage reduction chip U6, a voltage regulator diode D6, a capacitor C6, a voltage reduction chip U6, a capacitor C6, an inductor L6, a resistor R6 and a power indicator lamp D6, wherein the voltage reduction chip U6 is LM2576 6 in model, the voltage reduction chip U6 is SPX1117M 6 in model, the input end of the switching power supply J6 is connected with 220V alternating current, the output end of the switching power supply J6 outputs +12V direct current, the output end of the switching power supply J6 is connected with a first pin of the voltage reduction chip U6 sequentially through the switch S6 and the fuse F6, the negative electrode of the switching power supply J6 is connected with the other path of the voltage regulator diode D6, and the negative electrode of the voltage reduction chip D6 is grounded, one of the two pins is connected with the second pin of the voltage-reducing chip U3, the other one of the two pins is connected with one end of the capacitor C2 through the inductor L3, the fourth pin of the voltage-reducing chip U3 is connected with a node between the inductor L3 and one end of the capacitor C2, a node between the inductor L3 and one end of the capacitor C2 outputs a +5V direct current output terminal, the third pin of the voltage-reducing chip U2 can be connected with a node between the inductor L3 and one end of the capacitor C2, the second pin of the voltage-reducing chip U2 is connected with the anode of the power indicator lamp D22 through the resistor R7, the cathode of the diode D4 68642, one end of the capacitor C10, one end of the capacitor C599, one end of the capacitor C3 and one end of the capacitor C8 are all connected with a node between the fuse F1 and the first pin of the voltage-reducing chip U3, the cathode of the diode D5, one end of the capacitor C14 and one end of the capacitor C13 are all connected with the three pins of the, one end of the capacitor C4 and one end of the capacitor C6 are connected to a node between the second pin of the buck chip U2 and the resistor R7, the anode of the diode D4S, the other end of the capacitor C10, the other end of the capacitor C9, the other end of the capacitor C2, the other end of the capacitor C3, the other end of the capacitor C8, the anode of the zener diode D4, the anode of the diode D5, the other end of the capacitor C14, the other end of the capacitor C13, the other end of the capacitor C4, the other end of the capacitor C6, the third pin of the buck chip U3, the fifth pin of the buck chip U3 and the first pin of the buck chip U2 are connected to a node between the cathode output terminal of the switching power supply J6 and the cathode of the power indicator lamp D22, a node between the second pin of the buck chip U2 and the resistor R7 outputs a +3.3V dc output terminal, when the power indicator lamp D22 is turned on and emits light, the switching power supply J6 belongs to the prior art, and the detailed circuit configuration is not described herein.

The single chip microcomputer U1 is also electrically connected with a storage module and a serial port circuit.

The memory module comprises a memory chip U10, a memory chip U9, a capacitor C20, a capacitor C29, a resistor R15 and a resistor R18, wherein the model of the memory chip U10 is W25Q64, the model of the memory chip U9 is 24C02, a first pin of the memory chip U10 is electrically connected with a sixteenth pin of the singlechip U1, a second pin of the memory chip U10 is electrically connected with a twenty-second pin of the singlechip U1, a third pin of the memory chip U10 is connected with a +3.3V direct current output end, a fourth pin of the memory chip U10 is grounded, a fifth pin of the memory chip U10 is electrically connected with a twenty-third pin of the singlechip U1, a sixth pin of the memory chip U10 is electrically connected with a twenty-first pin of the singlechip U1, a seventh pin of the memory chip U10 is divided into three paths, and the first path is connected with an eighth pin of the memory chip U10, the second circuit is connected with a +3.3V direct current output end, the third circuit is connected with one end of a capacitor C30, a first pin, a second pin, a third pin and a third pin of a memory chip U9 are all connected with the other end of the capacitor C30, the other end of the capacitor C30 is also grounded, a fifth pin of the memory chip U9 is divided into two circuits, one circuit is connected with a fifty-second pin of the singlechip U1, the other circuit is connected with the +3.3V direct current output end through the resistor R18, a sixth pin of the memory chip U9 is divided into two circuits, one circuit is connected with a fifty-third pin of the singlechip U1, the other circuit is connected with the +3.3V direct current output end through the resistor R18, a seventh pin of the memory chip U9 is grounded, an eighth pin of the memory chip U9 is grounded through the capacitor C29, and the memory chip U10 and the memory chip U9 are used for storing data, such as storing a preset value of water temperature, water temperature in the cup, brightness and preset values of the current environment, etc.

The serial port circuit comprises a USB interface U6, a capacitor C20, a switching chip U8, a resistor R39, a resistor R40, a diode D24, a crystal oscillator X3, a capacitor C12 and a capacitor C19, wherein the model of the switching chip U8 is CH340G, a first pin of the USB interface U6 is connected with a +5V direct current output end, a second pin of the USB interface U6 is connected with a sixth pin of the switching chip U8, a third pin of the USB interface U6 is connected with a fifth pin of the switching chip U8, a fifth pin of the USB interface U6 is divided into three paths, a first path is connected with a fourth pin of the switching chip U8 through the capacitor C20, a second path is connected with a first pin of the switching chip U8, a third path is grounded, one end of the crystal oscillator X3 is divided into two paths, one path is connected with a seventh pin of the switching chip 8, the other path is connected with the other end of the crystal oscillator X12 and the other end of the crystal oscillator X3, one path is connected with the eighth pin of the switching chip U8, the other path is grounded through the capacitor C19, one end of the resistor R39 and one end of the resistor R40 are both connected to a +5V dc output terminal, the other end of the resistor R39 is divided into two paths, one path is connected to the second pin of the switching chip U8, the other path is connected to the cathode of the diode D24, the anode of the diode D24 is connected to the anode of the diode D23, the other end of the resistor R40 is divided into two paths, one path is connected to the third pin of the switching chip U8, the other path is connected to the forty-third pin of the single chip U1 through the resistor R36, the USB interface U6 is connected to other electronic devices to realize information exchange, the voltage-reduced signal of the switching chip U8 is converted into a TTL level corresponding to the switching chip, so that the controller exchanges information with other electronic devices (for example, the temperature of the water in the cup).

The utility model discloses the sensor that arrives (for example, temperature sensor DS18, temperature and humidity sensor DHT1) all can output analog signal (for example, current signal or voltage signal) after data collection (for example, the temperature in the drinking cup), singlechip U1's analog-to-digital converter converts this analog signal into the digital signal who corresponds with it, singlechip U1 converts this digital signal into the numerical value that corresponds with it again, it is prior art to utilize sensor data collection.

The forty-ninth pin of the singlechip U1 is grounded through a resistor R44, and the forty-sixth pin of the singlechip U1 is connected with a +3.3V direct current output end through a resistor R43.

The nineteenth pin, the sixty-fourth pin, the forty-eighth pin and the thirty-second pin of the single chip microcomputer U1 are all connected with a +3.3V direct current output end, and the thirteenth pin of the single chip microcomputer U1 is connected with the +3.3V direct current output end through the inductor L2.

The twenty-fifth pin of the single chip microcomputer U1 is grounded after passing through the resistor R48 and the switch SW1 in sequence, a node between the resistor R48 and the switch SW1 is connected with a +3.3V direct current output end through the resistor R47, the switch SW1 is used for setting a preset water temperature value, and the preset water temperature value is increased or reduced when the switch SW1 is closed once.

In the figure, "DHT 1" represents temperature and humidity sensor DHT1, "DS 18" represents temperature sensor DS18, "CK 1" represents light sensor CK1, and "LCD" in the figure represents touch display screen LCD.

Because the circuit schematic diagram is too large, the circuit schematic diagram is divided into five circuit schematic diagrams.

The above embodiments do not limit the scope of the present invention, and those skilled in the art can make equivalent modifications and variations without departing from the overall concept of the present invention.

Claims (10)

1. The utility model provides an intelligence control by temperature change drinking cup, the drinking cup is provided with the controller, the input electric connection of controller has crystal oscillator circuit and power module, its characterized in that the input of controller still electric connection has light sensor (CK 1), the surface of drinking cup is provided with light display circuit, light display circuit with the output electric connection of controller, the controller is provided with the luminance default.

2. The intelligent temperature-controlled water cup as claimed in claim 1, wherein the controller is a single chip microcomputer (U1), the model of the single chip microcomputer (U1) is STM32F103RCT6, the model of the light sensor (CK 1) is CK003, a first pin of the light sensor (CK 1) is electrically connected with a fifteenth pin of the single chip microcomputer (U1), a second pin of the light sensor (CK 1) is connected with a +3.3V direct-current output terminal, a third pin of the light sensor (CK 1) is divided into three paths, the first path is grounded, the second path is connected with one end of a capacitor (C23), one end of a third connecting resistor (R42), and the other end of the capacitor (C23) and the other end of the resistor (R42) are both connected with a node between the first pin of the light sensor (CK 1) and the fifteenth pin of the single chip microcomputer (U1).

3. The intelligent temperature-controlled water cup as claimed in claim 2, wherein the input terminal of the controller is electrically connected with a temperature sensor (DS 18), the temperature sensor (DS 18) is arranged in the water cup, the type of the temperature sensor (DS 18) is DS18B20, the first pin of the temperature sensor (DS 18) is connected with the +3.3V dc output terminal, the second pin of the temperature sensor (DS 18) is divided into two paths, one path is connected with the node between the first pin of the temperature sensor (DS 18) and the +3.3V dc output terminal through a resistor (R12), the other path is connected with the fourteenth pin of the single chip microcomputer (U1), and the third pin of the temperature sensor (DS 18) is grounded.

4. The intelligent temperature-controlled water cup as claimed in claim 3, wherein the output terminal of the controller is electrically connected with two switch circuits, the output terminal of one switch circuit is electrically connected with a heating component (HT 1), the output terminal of the other switch circuit is electrically connected with a refrigerating component (HT 2), the heating component (HT 1) surrounds the outer surface of the water cup, the refrigerating component (HT 2) is arranged at the bottom of the water cup, one switch circuit comprises a relay (J8), a diode (D7), an NPN triode (Q2), a resistor (R10) and a resistor (R9), the first pin of the relay (J8) is divided into two paths, one path is connected with the collector of the NPN triode (Q2), the other path is connected with the anode of the diode (D7), and the second pin of the relay (J8) is connected with a DC output terminal of +12V, a fourth pin of the relay (J8) is divided into two paths, one path is connected with a negative electrode of the diode (D7), the other path is connected with a +5V direct current output end, a fifth pin of the relay (J8) is connected with a positive electrode input end of the heating component (HT 1), one end of the resistor (R10) is divided into two paths, one path is connected with a base electrode of the NPN type triode (Q2), the other path is connected with a forty-fourth pin of the single chip microcomputer (U1) through the resistor (R9), the other end of the resistor (R10) is divided into two paths, one path is grounded, and the other path is connected with an emitter electrode of the NPN type triode (Q2); the other switch circuit comprises a relay (J9), a diode (D8), an NPN triode (Q3), a resistor (R14) and a resistor (R3), wherein a first pin of the relay (J9) is divided into two paths, one path is connected with a collector of the NPN triode (Q3), the other path is connected with a positive electrode of the diode (D8), a second pin of the relay (J9) is connected with a +12V direct current output end, a fourth pin of the relay (J9) is divided into two paths, one path is connected with a negative electrode of the diode (D8), the other path is connected with a +5V direct current output end, a fifth pin of the relay (J9) is connected with a positive electrode input end of the refrigeration component (HT 2), one end of the resistor (R14) is divided, one path is connected with a base of the NPN triode (Q3), and the other path is connected with a fifth forty pin of the single chip microcomputer (U1) through the resistor (R13), the other end of the resistor (R14) is divided into two paths, one path is grounded, the other path is connected with an emitting electrode of the NPN type triode (Q3), and the negative input end of the heating assembly (HT 1) and the negative input end of the refrigerating assembly (HT 2) are both grounded.

5. The intelligent temperature-controlled water cup according to claim 4, characterized in that the heating component (HT 1) is a silicon rubber heating wire, the refrigerating component (HT 2) is a thermoelectric refrigerating piece, and the type of the thermoelectric refrigerating piece is TEC 1-12705.

6. The intelligent temperature control water cup according to claim 5, wherein a heat sink and a heat dissipation fan are further arranged at the bottom of the water cup, and the refrigeration component (HT 2), the heat sink and the heat dissipation fan are sequentially arranged at the bottom of the water cup from top to bottom.

7. The intelligent temperature-control water cup according to claim 6, wherein an input end of the controller is further electrically connected with a temperature and humidity sensor (DHT 1), the temperature and humidity sensor (DHT 1) is DHT11, the temperature and humidity sensor (DHT 1) is arranged on the outer surface of the water cup, a first pin of the temperature and humidity sensor (DHT 1) is connected with a +3.3V direct-current output end, a second pin of the temperature and humidity sensor (DHT 1) is divided into two paths, one path is connected with a node between the first pin of the temperature and humidity sensor (DHT 1) and the +3.3V direct-current output end through a resistor (R11), the other path is connected with a seventeenth pin of the single chip microcomputer (U1), and a third pin and a fourth pin of the temperature and humidity sensor (DHT 1) are both grounded.

8. The intelligent temperature control water cup according to claim 7, wherein the output end of the controller is electrically connected with a display module and an alarm module, the display module and the alarm module are both arranged on the outer surface of the water cup, the display module is a touch display screen (LCD), a first pin of the touch display screen (LCD) is connected with a forty-th pin of the singlechip (U1), a second pin of the touch display screen (LCD) is connected with a thirty-ninth pin of the singlechip (U1), a third pin of the touch display screen (LCD) is connected with a thirty-eighth pin of the singlechip (U1), a fourth pin of the touch display screen (LCD) is connected with a thirty-seventh pin of the singlechip (U1), a fifth pin of the touch display screen (LCD) is connected with a seventh pin of the singlechip (U1), a sixth pin of the touch display screen (LCD) is connected with a twenty-sixth pin of the single chip microcomputer (U1), a seventh pin of the touch display screen (LCD) is connected with a twenty-seventh pin of the single chip microcomputer (U1), an eighth pin of the touch display screen (LCD) is connected with a twenty-eighth pin of the single chip microcomputer (U1), a ninth pin of the touch display screen (LCD) is connected with a fifty-fifth pin of the single chip microcomputer (U1), a tenth pin of the touch display screen (LCD) is connected with a fifty-sixth pin of the single chip microcomputer (U1), an eleventh pin of the touch display screen (LCD) is connected with a fifty-seventh pin of the single chip microcomputer (U1), a twelfth pin of the touch display screen (LCD) is connected with an eighth pin of the single chip microcomputer (U1), and a thirteenth pin of the touch display screen (LCD) is connected with a ninth pin of the single chip microcomputer (U1) Then, a fourteenth pin of the touch display screen (LCD) is connected with a sixteenth pin of the single chip microcomputer (U1), a fifteenth pin of the touch display screen (LCD) is connected with a sixty-second pin of the single chip microcomputer (U1), a sixteenth pin of the touch display screen (LCD) is connected with a twenty-ninth pin of the single chip microcomputer (U1), a seventeenth pin of the touch display screen (LCD) is connected with a thirtieth pin of the single chip microcomputer (U1), an eighteenth pin of the touch display screen (LCD) is connected with a thirty-third pin of the single chip microcomputer (U1), a nineteenth pin of the touch display screen (LCD) is connected with a thirty-fourth pin of the single chip microcomputer (U1), a twentieth pin of the touch display screen (LCD) is connected with a thirtieth pin of the single chip microcomputer (U1), a twenty-first pin of the touch display screen (LCD) is connected with a thirty-sixth pin of the single chip microcomputer (U1), a twenty-second pin, a twenty-sixth pin and a twenty-seventh pin of the touch display screen (LCD) are connected together, a twenty-third pin of the touch display screen (LCD) is connected with a fifty-first pin of the single chip microcomputer (U1), a twenty-fourth pin of the touch display screen (LCD) is connected with a +3.3V direct current output end, a twenty-fifth pin of the touch display screen (LCD) is connected with a +3.3V direct current output end, a twenty-eighth pin of the touch display screen (LCD) is connected with a +5V direct current output end, a twenty-ninth pin of the touch display screen (LCD) is connected with a tenth pin of the single chip microcomputer (U1), and a thirty-third pin of the touch display screen (LCD) is connected with an eleventh pin of the single chip microcomputer (U1), a thirty-first pin of the touch display screen (LCD) is connected with a ninth pin of the single chip microcomputer (U1), a thirty-third pin of the touch display screen (LCD) is connected with a second pin of the single chip microcomputer (U1), and a thirty-fourth pin of the touch display screen (LCD) is connected with an eighth pin of the single chip microcomputer (U1); the alarm module comprises a resistor (R16), an NPN type triode (Q1), a resistor (R21), a diode (D6) and a buzzer (B2), wherein the cathode of the diode (D6) and one end of the buzzer (B2) are connected with a +5V direct current output end, the collector of the NPN type triode (Q1) is divided into two paths, one path is connected with the anode of the diode (D6), the other path is connected with the other end of the buzzer (B2), one end of the resistor (R21) is divided into two paths, one path is connected with the twenty-fourth pin of the single chip microcomputer (U1) through the resistor (R16), the other path is connected with the base of the NPN type triode (Q1), the other end of the resistor (R21) is divided into two paths, the other path is grounded, and the other path is connected with the emitter of the NPN type triode (Q1).

9. The intelligent temperature-controlled water cup as claimed in claim 8, wherein the controller is further electrically connected with a WIFI module, a reset circuit and a standby power supply, the WIFI module comprises a WIFI chip (U5), a capacitor (C27), a capacitor (C26), a resistor (R5), a resistor (R3), a resistor (R6), a diode (D23), a resistor (R36), a resistor (R37), a resistor (R38), a resistor (R41) and a resistor (R29), the type of the WIFI chip (U5) is ESP8266, one end of the resistor R5 is connected in two paths, one path is connected with the capacitor (C27) and the other path is connected with a +5V DC output terminal, one end of the resistor (R3) is connected in three paths, the first path is connected with a node between one end of the resistor R5 and the capacitor (C27), the second path is connected with an eighth pin of the WIFI chip (U5), and the third path is connected with the capacitor (C26), the other end of the resistor R5 is connected with a first pin of the WIFI chip (U5), the other end of the resistor R3 is connected with a third pin of the WIFI chip (U5), an eighteenth pin of the WIFI chip (U5) is connected with a +5V direct current output end through the resistor R6, one end of the resistor R29 is connected with a sixteenth pin of the WIFI chip (U5), the other end of the resistor R29 is divided into three paths, the first path is connected with a fifteenth pin of the WIFI chip (U5), the second path is grounded, the third path is connected with the +5V direct current output end, the twenty-first pin of the WIFI chip (U5) is connected with the anode of the diode D23, the cathode of the diode D23 is divided into two paths, one path is connected with the +5V direct current output end through the resistor R37, and the other path is connected with a second pin forty of the single chip microcomputer (U1) through the resistor R41, the twenty-second pin of the WIFI chip (U5) is divided into two paths, one path is connected with a +5V direct current output end through the resistor (R38), the other path is connected with the forty-third pin of the singlechip (U1) through the resistor (R36), the RESET circuit comprises a resistor (R25), a RESET key (RESET) and a capacitor (C7), one end of the resistor (R25), one end of the RESET key (RESET) and one end of the capacitor (C7) are all connected with the seventh pin of the singlechip (U1), the other end of the resistor (R25) is connected with the +3.3V direct current output end, the other end of the RESET key (RESET) and the other end of the capacitor (C7) are all grounded, the standby power supply comprises a storage battery (BAT 2), a diode (D9) and a diode (D10), the cathode of the diode (D9) and the cathode of the diode (D10) are all connected with the first pin of the singlechip (U1), the positive electrode of the diode (D9) is connected with the positive electrode of the storage battery (BAT 2), the negative electrode of the storage battery (BAT 2) is grounded, and the positive electrode of the diode (D10) is connected with the +3.3V direct current output end.

10. The intelligent temperature-controlled water cup according to claim 9, wherein the crystal oscillator circuit comprises a crystal oscillator (X1), a capacitor (C15), a capacitor (C11), a crystal oscillator (X2), a capacitor (C16) and a capacitor (C17), one end of the crystal oscillator (X1) is divided into two paths, one path is connected with the third pin of the single chip microcomputer (U1), the other path is grounded through the capacitor (C15), the other end of the crystal oscillator (X1) is divided into two paths, one path is connected with the 4 pins of the single chip microcomputer (U1), the other path is grounded through the capacitor (C11), one end of the crystal oscillator (X2) is divided into two paths, one path is connected with the fifth pin of the single chip microcomputer (U1), the other path is grounded through the capacitor (C16), the other end of the crystal oscillator (X2) is divided into two paths, one path is connected with the six pins of the single chip microcomputer (U1), the other path is grounded through the capacitor (C17), and the lamp light display circuit comprises a light emitting diode (D1), The LED driving circuit comprises a resistor (R2), a light emitting diode (D2), a resistor (R1), a light emitting diode (D3) and a resistor (R4), wherein the anode of the light emitting diode (D1) is connected with a +3.3V direct current output end through the resistor (R2), the anode of the light emitting diode (D2) is connected with a +3.3V direct current output end through the resistor (R1), the anode of the light emitting diode (D3) is connected with a +3.3V direct current output end through the resistor (R4), the cathode of the light emitting diode (D1) is connected with the forty-first pin of the singlechip (U1), the cathode of the light emitting diode (D2) is connected with the twentieth pin of the singlechip (U1), and the cathode of the light emitting diode (D3) is connected with the fourth pin of the singlechip (U1).

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