CN210636519U - Intelligent integrated shower screen - Google Patents

Intelligent integrated shower screen Download PDF

Info

Publication number
CN210636519U
CN210636519U CN201921324017.7U CN201921324017U CN210636519U CN 210636519 U CN210636519 U CN 210636519U CN 201921324017 U CN201921324017 U CN 201921324017U CN 210636519 U CN210636519 U CN 210636519U
Authority
CN
China
Prior art keywords
capacitor
circuit
resistor
water
shower screen
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
CN201921324017.7U
Other languages
Chinese (zh)
Inventor
洪晖堂
洪晖推
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Wenzhou Yuanfan Technology Co Ltd
Original Assignee
Wenzhou Yuanfan Technology Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Wenzhou Yuanfan Technology Co Ltd filed Critical Wenzhou Yuanfan Technology Co Ltd
Priority to CN201921324017.7U priority Critical patent/CN210636519U/en
Application granted granted Critical
Publication of CN210636519U publication Critical patent/CN210636519U/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Landscapes

  • Control Of Resistance Heating (AREA)

Abstract

The utility model provides an integrated shower screen of intelligence, includes shower screen main part, gondola water faucet, heating element and control part, heating element sets up the inside in the shower screen main part, the control part includes operating panel, be equipped with integrated circuit in the operating panel, integrated circuit connects heating element, and the front portion top of shower screen main part is equipped with the top shower plate, and the front portion below of shower screen main part is equipped with side shower plate and end shower nozzle, operating panel sets up the anterior middle zone in the shower screen main part, operating panel includes display area and control area, integrated circuit includes power supply circuit, single chip microcomputer controller, LED drive display, detection circuitry, buzzer circuit and heating control circuit, power supply circuit, LED drive display, detection circuitry, buzzer circuit and heating control circuit all connect single chip microcomputer controller, detection circuitry includes zero cross detection circuitry, The water temperature and water flow detection device comprises an electric leakage detection circuit, a water temperature and water flow detection circuit and a water flow control circuit.

Description

Intelligent integrated shower screen
Technical Field
The utility model relates to a bathroom product field, concretely relates to integrated shower screen of intelligence.
Background
At present, it needs shower equipment, heating equipment and water pipeline cooperation to reach to bathe, and shower equipment, heating equipment and water pipeline need the cooperation installation after purchasing one by one, and the purchase is troublesome and probably appear not being suitable for or the condition of not supporting, and shower equipment is too mechanized and the function singleness, also can't directly operate heating equipment when bathing.
SUMMERY OF THE UTILITY MODEL
In order to solve the problem, the utility model provides an integrated shower screen of intelligence:
the utility model provides an integrated shower screen of intelligence, includes shower screen main part, gondola water faucet, heating element and control part, the shower screen main part is obtuse angle L shape, and the side of shower screen main part is provided with the rack of gondola water faucet, the gondola water faucet passes through hose connection shower screen main part, heating element sets up the inside in the shower screen main part, the control part includes operating panel, total water intaking valve and goes out water control valve group, be equipped with integrated circuit in the operating panel, integrated circuit connects heating element, and the anterior top of shower screen main part is equipped with the top shower plate, and the anterior below of shower screen main part is equipped with side shower plate and end shower nozzle, operating panel sets up the anterior middle zone in the shower screen main part, operating panel includes display area and control area, the display area shows control signal, the control area is used for controlling integrated circuit operation, integrated circuit includes power supply circuit, The LED water flow detection device comprises a single chip microcomputer controller, an LED driving display, a detection circuit, a buzzer circuit and a heating control circuit, wherein the power supply circuit, the LED driving display, the detection circuit, the buzzer circuit and the heating control circuit are all connected with the single chip microcomputer controller, and the detection circuit comprises a zero-crossing detection circuit, a leakage detection circuit, a water temperature and water flow detection circuit and a water flow control circuit.
Preferably, the heating assembly comprises a water pipeline and a heating element, the water pipeline is provided with a cold water inlet and a hot water outlet, the heating element is used for heating water in the water pipeline, and the heating element is connected with the heating control circuit.
Preferably, the integrated circuit is further provided with a radio frequency connector and a wire holder, the single chip microcomputer controller is a BS84C12A-3/SOP20 touch key single chip microcomputer, the LED driving display is a TM1640 light emitting diode driving display, the buzzer circuit comprises a buzzer and an eleventh capacitor, the positive electrode of the buzzer is connected with the negative electrode of the eleventh capacitor, the negative electrode of the buzzer is connected with a ground wire, the positive electrode of the eleventh capacitor, the BS84C12A-3/SOP20 touch key single chip microcomputer, the TM1640 light emitting diode driving display and the wire holder are all connected with the radio frequency connector, and the wire holder is connected with a five-volt power supply and the ground wire.
Preferably, the zero-cross detection circuit is a circuit with an S8050 triode as a core, the leakage detection circuit is a circuit with a 54123SOP8 leakage protection chip as a core, and the power supply circuit is connected to the power supply from a mains supply: the live wire is connected with one end of a breaker, the other end of the breaker is connected with one end of a piezoresistor, one end of a high-voltage film capacitor and the input end of a transformer, the zero line is connected with the other end of the piezoresistor, the other end of the high-voltage film capacitor and the input end of the transformer, the output end of the transformer is connected with a bridge rectifier circuit, the anode of the bridge rectifier circuit is connected with one end of a second resistor and the anode of a diode, the cathode of the bridge rectifier circuit is connected with the cathode of a first chip capacitor, the cathode of the first capacitor, the ground end of an L7805 voltage stabilizer, the cathode of the second chip capacitor, the cathode of a seventh capacitor, one end of a seventh resistor and the ground wire, the other end of the second resistor is connected with one end of a first resistor and the base of a first S8050 triode, the emitting electrode of the first S8050 triode, the cathode of the diode, the anode of the first chip capacitor and the anode of the first capacitor are all connected with one end of a nineteenth resistor and a twelve-volt power supply, the other end of the nineteenth resistor is connected with the input end of an L7805 voltage stabilizer, the output end of the L7805 voltage stabilizer is connected with the anode of the second chip capacitor, the anode of a seventh capacitor, the other end of a seventh resistor, one end of a sixth resistor and a five-volt power supply, the other end of the sixth resistor is connected with the collector of a second S8050 triode and one end of a twelfth resistor, the other end of the twelfth resistor is connected with a connector base, the emitter of the second S8050 triode is connected with a ground wire, the base of the second S8050 triode is connected with one end of an eighteenth resistor, the other end of the eighteenth resistor is connected with the cathode of the ninth capacitor and the seventh interface of the leakage protection chip, the anode of the ninth capacitor, the third interface of the leakage protection chip is connected with the negative electrode of an eighth capacitor, the eighth interface of the leakage protection chip is connected with the positive electrode of a third patch capacitor, the positive electrode of a third capacitor, the negative electrode of a voltage stabilizing diode and one end of a thirteenth resistor, the other end of the thirteenth resistor is connected with a twelve-volt power supply, the positive electrode of the voltage stabilizing diode is connected with the negative electrode of the third patch capacitor, the negative electrode of a third capacitor, the negative electrode of a tenth capacitor and a ground wire, the second interface of the leakage protection chip is connected with one end of a seventeenth resistor, the other end of the seventeenth resistor is connected with the positive electrode of a fourth capacitor, one end of a sixteenth resistor and the positive electrode of a light emitting diode, and the first interface of the leakage protection.
Preferably, heating control circuit connects between commercial power and heating element, heating element's the piece that generates heat has two, heating control circuit contains two bidirectional thyristor and two relays: one ends of the two relays are connected in parallel and then are connected with a mains supply through a circuit breaker and a voltage dependent resistor, the other ends of the two relays are respectively connected with two bidirectional thyristors, the two bidirectional thyristors are respectively connected with two heating pieces, the two bidirectional thyristors are controlled to be conducted through photoelectric couplers connected with a wire holder, the heating control circuit is further provided with a relay driving circuit, the relay driving circuit is a circuit with an ULN2001D relay driver as a core, coils of the two relays are respectively connected with the ULN2001D relay driver, the ULN2001D relay driver is connected with a twelve-volt power supply and a ground wire, a second capacitor is connected between the twelve-volt power supply and the ground wire, and the wire holder is connected with the ULN 2001D.
Preferably, temperature rivers detection circuitry uses temperature rivers sensor as the core, tenth resistance one end and fourth resistance one end are connected to temperature rivers sensor output, and the connection terminal is connected to the tenth resistance other end, and the five volts of power and the fourth resistance other end are connected to temperature rivers sensor input, temperature rivers sensor sets up inside heating element's water pipeline.
Preferably, rivers control circuit uses the rivers sensor as the core, the rivers sensor includes into rivers sensor and goes out rivers sensor, it is anodal that sixth electric capacity, eighth resistance one end and fifteenth resistance one end are connected to into rivers sensor one end, sixth electric capacity negative pole and ground wire are connected to the into rivers sensor other end, it is anodal that fifth electric capacity, ninth resistance one end and fourteenth resistance one end are connected to play rivers sensor one end, it connects fifth electric capacity negative pole and ground wire to go out the rivers sensor other end, it sets up the cold water inlet at the water pipeline to advance rivers sensor, it sets up the hot water export at the water pipeline to go out rivers sensor.
The utility model discloses following beneficial effect has: the whole shower system of integrated control, a key intelligence operation in the shower process improves shower experience.
Drawings
Fig. 1 is a schematic structural diagram of the embodiment.
Fig. 2 is a schematic view of the inside of the shower screen main body of the embodiment.
Fig. 3 is a schematic structural diagram of a heating assembly according to an embodiment.
FIGS. 4-7 are diagrams of integrated circuits according to embodiments.
1. A shower screen cylinder; 2. a shower head; 3. a top jet plate; 4. a heating assembly; 5. an operation panel; 6. a water outlet changeover valve; 7. a water outlet control valve; 8. a side jet plate; 9. a water outlet tap; 10. a water flow pipe set; 11. a water pipeline; 12. a heat generating member; 13. intelligent mechanical switch.
Detailed Description
The present invention will be further described with reference to the accompanying drawings 1 to 7 and the embodiments.
The utility model provides an integrated shower screen of intelligence, includes shower screen main part, gondola water faucet 2, heating element 4 and control part, the shower screen main part is obtuse angle L shape, and the side of shower screen main part is provided with the rack of gondola water faucet 2, gondola water faucet 2 passes through hose connection shower screen main part. Heating element 4 sets up the inside at the shower screen main part, heating element 4 includes water pipeline 10 and heating element 11, water pipeline 10 is equipped with cold water inlet and hot water export, heating element 11 is used for heating the inside water of water pipeline 10, heating element 11 connects heating control circuit.
The control part comprises an operation panel 5, a main water inlet valve 6 and a water outlet control valve group 7, the operation panel 5 comprises a display area and a control area, the display area is an electronic display screen for displaying real-time dynamic, the control area is 8 intelligent keys, 4 keys above the intelligent keys are an on-off key, a temperature rising key, a temperature lowering key and a mode gear key respectively, and the lower 4 keys are a top spray plate water outlet control key, a side spray plate water outlet control key, a bottom spray head water outlet control key and a shower head water outlet control key respectively. The user controls the operation of the main water inlet valve 6, the water outlet control valve group 7 and the integrated circuit through the keys. The main water inlet valve 6 is controlled to be started and stopped by an on-off key, the water outlet control valve group 7 comprises a top spray plate water outlet control valve, a side spray plate water outlet control valve, a bottom spray head water outlet control valve and a shower head water outlet control valve, and the valves are respectively controlled to be started and stopped by a top spray plate water outlet control key, a side spray plate water outlet control key, a bottom spray head water outlet control key and a shower head water outlet control key.
Integrated circuit connects heating element 4, and the anterior top of shower screen main part is equipped with top shower plate 3, and the anterior below of shower screen main part is equipped with side shower plate 8 and end shower nozzle 9, operating panel 5 sets up the anterior middle zone in shower screen main part, integrated circuit includes power supply circuit, single chip microcomputer controller, LED drive display, detection circuitry, buzzer circuit and heating control circuit, single chip microcomputer controller is all connected to power supply circuit, LED drive display, detection circuitry, buzzer circuit and heating control circuit, detection circuitry includes zero cross detection circuitry, electric leakage detection circuitry, temperature rivers detection circuitry and rivers control circuit.
The integrated circuit is further provided with a radio frequency connector SMP1 and a wire holder CN4, the single chip microcomputer controller is a BS84C12A-3/SOP20 touch key single chip microcomputer U1, the LED driving display is a TM1640 light emitting diode driving display U2, the buzzer circuit comprises a buzzer BUZ and an eleventh capacitor C11, the positive electrode of the buzzer BUZ is connected with the negative electrode of the eleventh capacitor C11, the negative electrode of the buzzer BUZ is connected with a ground wire, the positive electrode of the eleventh capacitor C11, the BS84C12A-3/SOP20 touch key single chip microcomputer U1, the TM1640 light emitting diode driving display U2 and the wire holder CN4 are connected with the radio frequency connector SMP1, and the wire holder CN4 is connected with a five-volt power supply and a ground wire.
The zero-crossing detection circuit is a circuit with an S8050 triode as a core, the leakage detection circuit is a circuit with a 54123SOP8 leakage protection chip U4 as a core, and the power supply circuit is connected with a mains supply: the live wire L is connected with one end of a breaker F1, the other end of the breaker F1 is connected with one end of a piezoresistor RV1, one end of a high-voltage film capacitor CX1 and the input end of a transformer T1, a zero line N is connected with the other end of a piezoresistor RV1, the other end of a high-voltage film capacitor CX1 and the input end of a transformer T1, the output end of the transformer T1 is connected with a bridge rectifier circuit DB1, the positive pole of the bridge rectifier circuit DB1 is connected with one end of a second resistor R2 and the positive pole of a diode D1, the negative pole of the bridge rectifier circuit DB1 is connected with the negative pole of a first patch capacitor EC1, the negative pole of a first capacitor C1, the ground terminal of an L7805 voltage stabilizer U1, the negative pole of a second patch capacitor EC1, the negative pole of a seventh capacitor C1, one end of a seventh resistor R1 and the ground terminal of a first S8050 triode Q1, the emitter of the first S8050 triode 1 is connected with the other end of the first resistor R1, the other end of a third resistor R3 is connected with a five-volt power supply, the other end of an eleventh resistor R2 is connected to a wire holder CN4, the cathode of a diode D1, the anode of a first chip capacitor EC1 and the anode of a first capacitor C1 are connected to one end of a nineteenth resistor R19 and the twelve-volt power supply, the other end of the nineteenth resistor R19 is connected to the input end of a L7805 voltage stabilizer U3, the output end of the L7805 voltage stabilizer U3 is connected to the anode of a second chip capacitor EC2, the anode of a seventh capacitor C7, the other end of a seventh resistor R7, one end of a sixth resistor R6 and the five-volt power supply, the other end of the sixth resistor R6 is connected to the collector of a second S8050 triode Q2 and one end of a twelfth resistor R12, the other end of the twelfth resistor R12 is connected to the wire holder CN4, the emitter of the second S8050Q 4 is connected to the ground wire, the base of the second S8050 triode Q4 is connected to one end of a ninth resistor R4, the cathode of the ninth resistor R4 and the ninth leakage protection chip U, the fourth interface of the leakage protection chip U4 is connected with the fifth interface, the fourth interface of the leakage protection chip U4 is connected with the anode of an eighth capacitor C8, the third interface of the leakage protection chip U4 is connected with the cathode of the eighth capacitor C8, the eighth interface of the leakage protection chip U4 is connected with the anode of a third patch capacitor EC3, the anode of a third capacitor C3, the cathode of a voltage stabilizing diode ZD1 and one end of a thirteenth resistor R13, the other end of the thirteenth resistor R13 is connected with a twelve-volt power supply, the anode of the voltage stabilizing diode ZD1 is connected with the cathode of the third patch capacitor EC3 and the cathode of the third capacitor C3, the negative electrode of a tenth capacitor C10 and the ground wire, the second interface of the leakage protection chip U4 is connected with one end of a seventeenth resistor R17, the other end of the seventeenth resistor R17 is connected with the positive electrode of a fourth capacitor C4, one end of a sixteenth resistor R16 and the positive electrode of a light emitting diode CN5, and the first interface of the leakage protection chip U4 is connected with the positive electrode of the tenth capacitor C10, the negative electrode of a fourth capacitor C4, the other end of the sixteenth resistor R16 and the negative electrode of the light emitting diode CN 5.
The heating control circuit is connected between a commercial power supply and the heating component 4, the number of the heating components 11 of the heating component 4 is two, and the heating control circuit comprises two bidirectional thyristors and two relays: one ends of the two relays are connected in parallel and then are connected with a mains supply through a circuit breaker F1 and a voltage dependent resistor RV1, the other ends of the two relays are respectively connected with two bidirectional thyristors, the two bidirectional thyristors are respectively connected with the two heating parts 11, the two bidirectional thyristors are controlled to be conducted through a photoelectric coupler U6 connected with a wiring base CN4, the heating control circuit is further provided with a relay driving circuit, the relay driving circuit is a circuit with an ULN2001D relay driver U5 as a core, coils of the two relays are respectively connected with an ULN2001D relay driver U5, the ULN2001D relay driver U5 is connected with a twelve-volt power supply and a ground wire, a second capacitor C2 is connected between the twelve-volt power supply and the ground wire, and the wiring base CN4 is connected into the ULN 2001D.
The water temperature and water flow detection circuit takes a water temperature and water flow sensor CN3 as a core, the output end of the water temperature and water flow sensor CN3 is connected with one end of a tenth resistor R10 and one end of a fourth resistor R4, the other end of the tenth resistor R10 is connected with a wire holder CN4, the input end of the water temperature and water flow sensor CN3 is connected with a five-volt power supply and the other end of the fourth resistor R4, and the water temperature and water flow sensor CN3 is arranged inside a water pipeline 10 of the heating component 4.
The water flow control circuit uses a water flow sensor as a core, the water flow sensor comprises a water inflow sensor CN1 and a water outflow sensor CN2, one end of the water inflow sensor CN1 is connected with the anode of a sixth capacitor C6, one end of an eighth resistor R8 and one end of a fifteenth resistor R15, the other end of the water inflow sensor CN1 is connected with the cathode of the sixth capacitor C6 and the ground wire, one end of the water outflow sensor CN2 is connected with the anode of a fifth capacitor C5, one end of a ninth resistor R9 and one end of a fourteenth resistor R14, the other end of the water outflow sensor CN2 is connected with the cathode of a fifth capacitor C5 and the ground wire, the water inflow sensor CN1 is arranged at a cold water inlet of the water pipeline 10, and the water outflow sensor CN2 is arranged at a hot water outlet of the water pipeline 10.
It is obvious that the above embodiments of the present invention are only examples for illustrating the present invention, and are not intended to limit the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. There is no need or no way to give poor examples of all embodiments. And that such obvious changes and modifications are within the scope of the present invention as defined by the appended claims.

Claims (7)

1. The utility model provides an integrated shower screen of intelligence, includes shower screen main part, gondola water faucet (2), heating element (4) and control part, its characterized in that: the shower screen main body is in an obtuse angle L shape, a placing rack of the shower head (2) is arranged on the side face of the shower screen main body, the shower head (2) is connected with the shower screen main body through a hose, the heating assembly (4) is arranged inside the shower screen main body, the control portion comprises an operation panel (5), a main water inlet valve (6) and a water outlet control valve group (7), an integrated circuit is arranged in the operation panel (5), the integrated circuit is connected with the heating assembly (4), a top spray plate (3) is arranged above the front portion of the shower screen main body, a side spray plate (8) and a bottom spray head (9) are arranged below the front portion of the shower screen main body, the operation panel (5) is arranged in the middle area of the front portion of the shower screen main body, the operation panel (5) comprises a display area and a control area, the display area displays control signals, and the, the integrated circuit comprises a power circuit, a single chip microcomputer controller, an LED driving display, a detection circuit, a buzzer circuit and a heating control circuit, wherein the power circuit, the LED driving display, the detection circuit, the buzzer circuit and the heating control circuit are all connected with the single chip microcomputer controller, and the detection circuit comprises a zero-crossing detection circuit, a leakage detection circuit, a water temperature and water flow detection circuit and a water flow control circuit.
2. The intelligent integrated shower screen of claim 1, wherein: the heating assembly (4) comprises a water pipeline (10) and a heating piece (11), the water pipeline (10) is provided with a cold water inlet and a hot water outlet, the heating piece (11) is used for heating water inside the water pipeline (10), and the heating piece (11) is connected with a heating control circuit.
3. The intelligent integrated shower screen of claim 2, wherein: the integrated circuit is further provided with a radio frequency connector (SMP1) and a wire holder (CN4), the single chip microcomputer controller is a BS84C12A-3/SOP20 touch key single chip microcomputer (U1), the LED driving display is a TM1640 light-emitting diode driving display (U2), the buzzer circuit comprises a Buzzer (BUZ) and an eleventh capacitor (C11), the positive electrode of the Buzzer (BUZ) is connected with the negative electrode of the eleventh capacitor (C11), the negative electrode of the Buzzer (BUZ) is connected with a ground wire, the positive electrode of the eleventh capacitor (C11), the BS84C12A-3/SOP20 touch key single chip microcomputer (U1), the TM1640 light-emitting diode driving display (U2) and the wire holder (CN4) are connected with the radio frequency connector (SMP1), and the wire holder (CN4) is connected with a five-volt power supply and the ground wire.
4. The intelligent integrated shower screen of claim 3, wherein: the zero-crossing detection circuit is a circuit with an S8050 triode as a core, the leakage detection circuit is a circuit with a 54123SOP8 leakage protection chip (U4) as a core, and the power supply circuit is connected with a mains supply: the live wire (L) is connected with one end of a breaker (F1), the other end of the breaker (F1) is connected with one end of a piezoresistor (RV1), one end of a high-voltage film capacitor (CX1) and the input end of a transformer (T1), the zero wire (N) is connected with the other end of the piezoresistor (RV1), the other end of the high-voltage film capacitor (CX1) and the input end of the transformer (T1), the output end of the transformer (T1) is connected with a bridge rectifier circuit (DB1), the positive pole of the bridge rectifier circuit (DB1) is connected with one end of a second resistor (R2) and the positive pole of a diode (D1), the negative pole of the bridge rectifier circuit (DB1) is connected with the negative pole of a first patch capacitor (EC1), the negative pole of the first capacitor (C1), the ground terminal of an L7805 (U3), the negative pole of a second patch capacitor (EC2), the negative pole of a seventh capacitor (C7), the negative pole of the seventh capacitor (R7), one end of a triode (R7, an emitter of a first S8050 triode (Q1) is connected with the other end of a first resistor (R1) and the ground wire, a collector of the first S8050 triode (Q1) is connected with one end of a third resistor (R3) and one end of an eleventh resistor (R10), the other end of the third resistor (R3) is connected with a five-volt power supply, the other end of the eleventh resistor (R2) is connected with a connector base (CN4), a cathode of a diode (D1), an anode of a first chip capacitor (EC1) and an anode of a first capacitor (C1) are connected with one end of a nineteenth resistor (R19) and a twelve-volt power supply, the other end of the nineteenth resistor (R19) is connected with an input end of an L7805 voltage stabilizer (U3), an output end of the L7805 voltage stabilizer (U3) is connected with an anode of a second chip capacitor (EC2), an anode of a seventh capacitor (C7), an anode of the seventh resistor (R7), one end of a sixth resistor (R6) and one end of a fifth voltage power supply, and the other end of a sixth resistor (R58 6) are connected with a, the other end of a twelfth resistor (R12) is connected with a wire holder (CN4), the emitter of a second S8050 triode (Q2) is connected with the ground wire, the base of the second S8050 triode (Q2) is connected with one end of an eighteenth resistor (R18), the other end of an eighteenth resistor (R18) is connected with the negative electrode of a ninth capacitor (C9) and a seventh interface of a leakage protection chip (U4), the positive electrode of a ninth capacitor (C9) is connected with a sixth interface of the leakage protection chip (U4), the fourth interface of the leakage protection chip (U4) is connected with a fifth interface, the fourth interface of the leakage protection chip (U4) is connected with the positive electrode of an eighth capacitor (C8), the third interface of the leakage protection chip (U4) is connected with the negative electrode of an eighth capacitor (C8), the eighth interface of the leakage protection chip (U4) is connected with the positive electrode of a third capacitor (EC3), the positive electrode of a third capacitor (C3), the negative electrode of a voltage stabilizing diode (ZD1) and the other end of the thirteenth resistor (R13) are connected with a power supply, the anode of the voltage-stabilizing diode (ZD1) is connected with the cathode of the third chip capacitor (EC3), the cathode of the third capacitor (C3), the cathode of the tenth capacitor (C10) and the ground wire, the second interface of the leakage protection chip (U4) is connected with one end of a seventeenth resistor (R17), the other end of the seventeenth resistor (R17) is connected with the anode of the fourth capacitor (C4), one end of a sixteenth resistor (R16) and the anode of the light-emitting diode (CN5), and the first interface of the leakage protection chip (U4) is connected with the anode of the tenth capacitor (C10), the cathode of the fourth capacitor (C4), the other end of the sixteenth resistor (R16) and the cathode of the light-emitting diode (CN 5).
5. The intelligent integrated shower screen of claim 4, wherein: the heating control circuit is connected between a commercial power supply and a heating assembly (4), the number of heating elements (11) of the heating assembly (4) is two, and the heating control circuit comprises two bidirectional thyristors and two relays: one ends of the two relays are connected in parallel and then are connected with a mains supply through a circuit breaker (F1) and a voltage dependent resistor (RV1), the other ends of the two relays are respectively connected with two bidirectional thyristors, the two bidirectional thyristors are respectively connected with the two heating parts (11), the two bidirectional thyristors are controlled to be conducted by a photoelectric coupler (U6) connected with a wire holder (CN4), the heating control circuit is further provided with a relay driving circuit, the relay driving circuit is a circuit taking an ULN2001D relay driver (U5) as a core, coils of the two relays are connected with an ULN2001D relay driver (U5), the ULN2001D relay driver (U5) is connected with a twelve-volt power supply and a ground wire, a second capacitor (C2) is connected between the twelve-volt power supply and the ground wire holder (CN4) and is connected with the ULN2001D relay driver (U5.
6. The intelligent integrated shower screen of claim 5, wherein: the water temperature and water flow detection circuit takes a water temperature and water flow sensor (CN3) as a core, the output end of the water temperature and water flow sensor (CN3) is connected with one end of a tenth resistor (R10) and one end of a fourth resistor (R4), the other end of the tenth resistor (R10) is connected with a wire holder (CN4), the input end of the water temperature and water flow sensor (CN3) is connected with a five-volt power supply and the other end of the fourth resistor (R4), and the water temperature and water flow sensor (CN3) is arranged inside a water pipeline (10) of a heating assembly (4).
7. The intelligent integrated shower screen of claim 6, wherein: the water flow control circuit takes a water flow sensor as a core, the water flow sensor comprises an inlet water flow sensor (CN1) and an outlet water flow sensor (CN2), one end of the water inflow sensor (CN1) is connected with the anode of a sixth capacitor (C6), one end of an eighth resistor (R8) and one end of a fifteenth resistor (R15), the other end of the inlet water flow sensor (CN1) is connected with the negative electrode of a sixth capacitor (C6) and the ground wire, one end of the effluent water flow sensor (CN2) is connected with the anode of a fifth capacitor (C5), one end of a ninth resistor (R9) and one end of a fourteenth resistor (R14), the other end of the effluent water flow sensor (CN2) is connected with the negative electrode of a fifth capacitor (C5) and the ground wire, the inlet water flow sensor (CN1) is arranged at the cold water inlet of the water pipeline (10), the water outlet flow sensor (CN2) is arranged at a hot water outlet of the water pipeline (10).
CN201921324017.7U 2019-08-15 2019-08-15 Intelligent integrated shower screen Active CN210636519U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201921324017.7U CN210636519U (en) 2019-08-15 2019-08-15 Intelligent integrated shower screen

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201921324017.7U CN210636519U (en) 2019-08-15 2019-08-15 Intelligent integrated shower screen

Publications (1)

Publication Number Publication Date
CN210636519U true CN210636519U (en) 2020-05-29

Family

ID=70796731

Family Applications (1)

Application Number Title Priority Date Filing Date
CN201921324017.7U Active CN210636519U (en) 2019-08-15 2019-08-15 Intelligent integrated shower screen

Country Status (1)

Country Link
CN (1) CN210636519U (en)

Similar Documents

Publication Publication Date Title
CN103398465B (en) The instant heated constant temperature outlet system of intelligent water
CN103075811B (en) Direct-heating type electric heater
CN210636519U (en) Intelligent integrated shower screen
CN201218564Y (en) Multi-use instant electric water heater
CN201066203Y (en) Quick-heating type electric water heater temperature-fixing water outlet device
CN203413806U (en) Intelligent water instant-heating constant-temperature water outlet system
CN201423007Y (en) Nasal-cavity pulse-type flushing machine
CN103511730A (en) Intelligent electric heating faucet
CN101538880A (en) Instantaneous intelligent washbasin
CN203824102U (en) Electric water heater system
CN209926591U (en) Novel water heater
CN207438919U (en) A kind of gas-heating water heater sectional combustion control device
CN202630363U (en) Instantaneous electric water heater
CN2283089Y (en) Fully automatic hand washer
CN111623509A (en) AC/DC integrated water heater
CN2780057Y (en) Convenient shower apparatus
CN102374334A (en) Energy-saving electric heating water tap device
CN217502739U (en) Kitchen induction faucet capable of automatically heating
CN2625424Y (en) Standing steam ironing machine with power regulation
CN212839668U (en) Touch control type faucet control box
CN221072864U (en) Purifying type quick-heating electric water tap
CN2576766Y (en) Double-type electric heating steam ironing machine
CN201406704Y (en) Instant heat intelligent washbasin
CN210069080U (en) Connection type electric heating faucet
CN219556951U (en) Instant heating type water dispenser with UV sterilization function

Legal Events

Date Code Title Description
GR01 Patent grant
GR01 Patent grant