CN211203267U

CN211203267U - Intelligent vertical electric heating faucet

Info

Publication number: CN211203267U
Application number: CN201922380741.8U
Authority: CN
Inventors: 赵清占; 王方超
Original assignee: Ningbo Happy Electric Appliance Industry And Trade Co ltd
Current assignee: Ningbo Happy Electric Appliance Industry And Trade Co ltd
Priority date: 2019-08-28
Filing date: 2019-12-26
Publication date: 2020-08-07
Anticipated expiration: 2029-12-26

Abstract

The utility model provides an intelligent vertical electric heating faucet, which comprises a vertical main body, a heating cavity is arranged in the main body, a heating body is vertically arranged in the heating cavity, the heating body is electrically connected with a control circuit, a water inlet piece for water inlet is arranged at the lower end of the main body, a water outlet piece for water outlet is arranged at the upper end of the main body, the utility model discloses a heating device, including inlet member, inlet passage, control circuit, inlet detection body, control circuit, inlet piece intercommunication inlet passage, the rivers break-make between inlet passage and the heating chamber is controlled by the case, still is equipped with the inlet detection passageway by case control and inlet passage break-make in the main part, establishes the water inlet start-up work of an electricity connection control circuit in the inlet detection passageway, and control circuit is equipped with the silicon controlled rectifier of electricity connection heating member and control its heating power, opens the case is to hot water state, and inlet detection passageway intercommunication inlet detection passageway and heating chamber, rivers get into inlet detection passageway and trigger the start switch work of intaking.

Description

Intelligent vertical electric heating faucet

Technical Field

The utility model relates to an instant heating type tap.

Background

The instant electric heating faucet is popular with consumers because the instant electric heating faucet can discharge hot water in 3 to 5 seconds after being started. The electric heating faucet in the current market is generally controlled by a handle, the handle rotates to a cold water state, cold water directly flows out, the handle rotates to a hot water state, water flow is heated, and the cold and hot degree is mainly adjusted by the flow. In the in-service use in-process, user's family income water temperature water pressure is relatively unstable, and the excessive scalding easily causes the scald when having now, and sometimes supercooling again can not reach the heating effect, will adjust suitable temperature, needs adjustment handle many times, and is very inconvenient in the use.

Along with the continuous improvement of the intelligent level, the intelligent home is also continuously popularized at present, and various intelligent devices are also appeared in each family, wherein the intelligent household electric heating faucet also comprises an electric heating faucet, so that the intelligent household electric heating faucet is more convenient for users.

Disclosure of Invention

In order to overcome the defects in the prior art, the invention provides the intelligent vertical electric heating faucet with reasonable temperature.

The utility model discloses a following technical scheme realizes:

the utility model provides an intelligence vertical electric heating faucet, includes vertical main part, establishes the heating chamber in the main part, the vertical heating member of establishing in the heating chamber, heating member electric connection control circuit, and the main part lower extreme is equipped with the piece of intaking that is used for intaking, and the play water spare that is used for going out water is established to the main part upper end, the piece intercommunication of intaking has water inlet channel, and water outlet channel intercommunication has the water outlet channel in intercommunication heating chamber, and the rivers break-make between water inlet channel and the heating chamber is controlled its characterized in that by the case: still be equipped with the measuring channel that intakes by case control and inhalant canal break-make in the main part, establish a start switch that intakes in the measuring channel, the start switch electricity that intakes connect control circuit, control circuit is equipped with the silicon controlled rectifier of electricity connection heating member and control its heating power, opens the case is to hot water state, and inhalant canal intercommunication inhalant canal and heating chamber, rivers get into the measuring channel that intakes and trigger the start switch work that intakes, silicon controlled rectifier control heating member work.

Preferably, the thyristor is disposed on a heat sink that transfers heat generated from the thyristor to the water flow.

Preferably, the heat sink is installed outside the sidewall of the water inlet channel or the heating cavity or the water outlet channel, and extends with an extension part, and the extension part is inserted into the water inlet channel or the heating cavity or the water outlet channel.

Preferably, the control circuit comprises a central controller, the input end of the central controller is connected with a key input module, the controllable silicon is connected with the output end of the central controller through a controllable silicon control module, the central controller receives a temperature or power adjusting signal input by the key input module, outputs a signal to the controllable silicon control module according to the received adjusting signal, and controls the heating power of the heating body through the controllable silicon.

Preferably, a temperature probe used for detecting the temperature of water is arranged in the main body, the temperature probe is connected with the input end of the central controller through a temperature detection module, the output end of the central controller is connected with a display module, the central controller receives the outlet water temperature detected by the temperature probe and displays the outlet water temperature through the display module, the outlet water temperature is compared with the set temperature set by the key input module, the heating power of the heating body is calculated according to the comparison result, the central controller outputs a signal to the silicon controlled control module according to the calculated result, the heating power of the heating body is controlled through the silicon controlled, and the operation is repeated until the outlet water temperature is constant at the set temperature.

Preferably, the control circuit comprises a first circuit board and a second circuit board, the central controller, the silicon controlled control module and the temperature detection module are arranged on the first circuit board, the key input module and the display module are arranged on the second circuit board, the main body is provided with a panel, the second circuit board is arranged on the inner side of the panel and electrically connected with the panel, and the first circuit board is arranged on the inner side of the second circuit board and electrically connected with the first circuit board through a connector assembly or a lead.

Preferably, the water inlet starting switch is a water pressure switch, the water pressure switch comprises a movable contact and a fixed contact which are respectively connected into the control circuit, the water pressure switch further comprises a switch pressing piece in transmission connection with the movable contact, the switch pressing piece is arranged in the water inlet detection channel, water flows enter the water inlet detection channel and act on the switch pressing piece, and the switch pressing piece is pressed and drives the movable contact to move to contact with the fixed contact to conduct the control circuit.

Preferably, the water inlet detection channel is communicated with a switch pressing piece cavity, the switch pressing piece comprises a pressure adhesive film which is arranged in the switch pressing piece cavity in a sealing mode, the pressure adhesive film is connected with one end of a push rod, the other end of the push rod is connected with the movable contact, water flows into the switch pressing piece cavity through the water inlet detection channel and acts on the pressure adhesive film, and the pressure adhesive film is pressed and drives the movable contact to move and contact with the fixed contact through the push rod.

As the preferred, the start switch of intaking is established to the rivers switch, the rivers switch include electric connection control circuit's hall sensor and arrange the flow rotation magnet in the measuring channel of intaking in, rivers get into the measuring channel drive flow and rotate magnet and rotate, hall sensor response rivers signal conduction control circuit.

Preferably, the thyristor and the heat sink are arranged on the top of the water inlet part.

The utility model discloses when hot water state, trigger the closure through intaking starting switch pressurized, control circuit intercommunication, then silicon controlled rectifier and heating member work, the heating power of heating member is controlled through the silicon controlled rectifier, through the key input, realizes that power is adjustable, realizes constant temperature even. Be different from prior art, control out water temperature through the flow size, the utility model discloses it is more intelligent, more humanized. During the working process of the controllable silicon, a large amount of heat can be generated, and if the heat dissipation is not ideal, the whole working performance can be influenced, and even devices can be damaged. The utility model discloses take away the heat of silicon controlled rectifier through rivers, because the silicon controlled rectifier during operation, the temperature is higher, and the rivers can be cold water, also can be hot water. The thyristor is preferably arranged to remove heat from the cold water, i.e. outside the water inlet channel, for example at the top of the water inlet member.

The water inlet starting switch can be a water pressure switch, namely a switch triggered by water flow pressure, and a movable contact is in contact connection with a fixed contact by the water flow pressure, and can also be a water flow switch, wherein the water flow switch is a switch triggered by water flow and is generally realized by a Hall sensor.

The beneficial effects of the utility model reside in that: the utility model discloses a silicon controlled rectifier control heating member heating power to rationally set up the silicon controlled rectifier position, the utility model discloses realize electric heat tap intelligent control, the power is adjustable realizes constant temperature even, and excellent performance.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a schematic sectional structure diagram of the first embodiment.

Fig. 3 is a schematic sectional structure diagram of the second embodiment.

Fig. 4 is a partial structural schematic diagram of the second embodiment.

FIG. 5 is a schematic cross-sectional view of another thyristor according to an embodiment.

Fig. 6 is another angular cross-sectional structural schematic of fig. 5.

FIG. 7 is a schematic cross-sectional view of another position of a thyristor according to an embodiment.

Fig. 8 is another angular cross-sectional structural schematic of fig. 7.

Fig. 9 is a schematic diagram of the structure of the control circuit.

Detailed Description

The following provides a more detailed description of the present invention with reference to the accompanying drawings and detailed description.

The first embodiment is as follows: as shown in fig. 1, 2, 7 and 8, an intelligent vertical electric heating faucet comprises a vertical main body 1, a heating cavity 8 is arranged in the main body, a heating body 9 which is vertically arranged is arranged in the heating cavity, and the heating body is electrically connected with a control circuit. The vertical main part lower extreme is equipped with the piece of intaking 5 that is used for into water, and the upper end of vertical main part is equipped with the play water spare that is used for going out water, goes out the water spare and establishes to go out water return bend 2, and the piece intercommunication of intaking has inhalant canal 19, and play water spare intercommunication has water outlet channel 6, and water outlet channel intercommunication heating chamber 8. The panel 3 is arranged on the surface of the main body, and the display 26 and the touch keys 25 are arranged on the panel 3. The main body is internally provided with a water inlet detection channel 18, and the water inlet channel 19 is controlled to be connected with the heating cavity 8 and the water inlet detection channel 18 through a valve core 17. The control circuit is electrically connected with a water inlet starting switch, and the water inlet starting switch is arranged in the water inlet detection channel. The control circuit is also provided with a controllable silicon, and the controllable silicon 14 controls the heating power of the heating body. The valve core is connected with a handle 4, when the valve core 17 is rotated by the handle 4 to a cold water state, the water inlet channel 19 is communicated with the heating cavity 8 through the valve core, the water inlet detection channel 18 is blocked, the water inlet starting switch is not triggered, the control circuit is in a disconnected state, the heating body 9 does not work, and water flow is not heated after entering the heating cavity and comes out through the water outlet piece. When the valve core is rotated to a hot water state by the handle 4, the water inlet detection channel 18 is communicated with the water inlet channel 19, the heating cavity 8 is also communicated with the water inlet channel, the water inlet starting switch is triggered to be closed, the control circuit is conducted, the silicon controlled rectifier controls the heating body to work, water flow enters the heating cavity and then is heated by the heating body, and the heated water flow flows out from the water outlet piece.

The controllable silicon is mainly used for controlling the heating power of the heating body, a large amount of heat can be released in the working process, the controllable silicon 14 is arranged on the radiating fins 15 for reasonable heat dissipation, the radiating fins conduct the heat of the controllable silicon to flowing water, and the heat is taken away by the flowing water.

The controllable silicon is arranged on one side of the main body, the radiating fins 15 and the controllable silicon 14 are arranged through bolts and fixed outside the side wall of the water inlet channel 19, the sealing rings 27 are arranged between the radiating fins and the side wall, the extending parts 16 extend from the radiating fins, and the extending parts 16 are inserted into the water inlet channel. Of course, it is preferable to locate the thyristor on the top of the water inlet member, as shown in fig. 2, in addition to taking away the heat of the thyristor by the cold water in the water inlet passage, the space in the main body can be fully utilized. The cooling fin of silicon controlled rectifier can paste the top of intaking the piece and insert into water channel, and the inside water that flows of water intaking is to its rapid cooling, has improved tap's reliability. And heat-conducting silica gel is arranged between the radiating fin 15 and the water inlet part 5, so that the radiating fin 15 is attached to the water inlet part, and the heat-conducting efficiency can be improved.

The controllable silicon can radiate heat through cold water in the water inlet channel and hot water in the heating cavity or the water outlet channel. The radiating fins 15 and the controllable silicon 14 are arranged through bolts and fixed on the side wall of the heating cavity or the water outlet channel, and the extending parts 16 of the radiating fins are inserted in the heating cavity or the water outlet channel. As shown in fig. 7 and 8, the thyristor is arranged outside the outer wall of the heating cavity. The controllable silicon is cooled by water flow in the heating cavity 8 or the water outlet channel 6, although the water temperature in the heating cavity 8 or the water outlet channel is higher than that in the water inlet channel, the controllable silicon can reach more than 100 ℃ in the working state, the water temperature is far lower than the working temperature of the controllable silicon, and the cooling function of the controllable silicon can still be achieved.

The control circuit can realize that the heating power of the electric heating faucet is adjustable and is realized by the controllable silicon. As shown in fig. 9, the control circuit includes a central controller, an input end of the central controller is connected to a key input module, a touch key on the panel is connected to the key input module, or a mechanical key, an output end of the central controller is connected to a thyristor through a thyristor control module, and the thyristor controls the heating power of the heating body. The central controller outputs a signal to the silicon controlled rectifier control module according to the adjusting signal, and controls the heating power of the heating body through the silicon controlled rectifier, so that the temperature of the outlet water is controlled, the power of the heating body is adjustable, and the temperature is controllable. Compared with the prior art, the instant electric heating faucet with the adjustable power has the advantages that the outlet water temperature is controlled through the flow, and the instant electric heating faucet with the adjustable power is more convenient to use. The output end of the central controller is connected with a display module, a display screen on the panel is connected with the display module, and a power indicator lamp used for displaying power gears is further arranged on the panel. A temperature probe is arranged in the water outlet channel or the heating cavity and is connected with the input end of the central controller through a temperature detection module, the temperature probe displays the detected water outlet temperature through a display module, and a power indicator lamp displays the working power of the heating body.

For more humanization, the embodiment can not only realize that the heating power is adjustable, but also realize that the water outlet temperature is constant, the central controller compares the water outlet temperature detected by the temperature probe 7 with the set temperature of the key input module, the central controller calculates the heating power of the heating body according to the comparison result, outputs a signal to the silicon controlled rectifier control module, adjusts the heating power of the heating body through the silicon controlled rectifier, and repeats the steps in such a way, and finally keeps the water outlet temperature constant at the set temperature.

In order to realize the function of adjustable power or constant temperature, the structure space of the water faucet needs to be reasonably planned, and all the components are integrated in the electric heating water faucet with smaller integral volume. As shown in fig. 8, the control circuit is configured as a first circuit board 28 and a second circuit board 24, the central controller, the thyristor control module and the temperature detection module are disposed on the first circuit board 28, the key input module and the display module are disposed on the second circuit board 24, the second circuit board 24 is disposed inside the panel 3 and electrically connected to the panel, and the first circuit board is disposed inside the second circuit board and electrically connected to the first circuit board through a connector or a wire. The space inside the faucet is greatly utilized by the arrangement mode of the first circuit board and the second circuit board, the touch screen panel is arranged on the surface of the pipe body and can be flexibly detached, and the first circuit board and the second circuit board are flexibly replaced and maintained.

The temperature which can be set by the touch key 25 is set between 30-50 degrees, and can be adjusted at will within the set temperature range value through the touch key as required, the touch key is provided with a heating key and a temperature reducing key, and the set temperature is increased or reduced by 1 degree every time the touch key is adjusted. The central controller automatically calculates the heating power of the heating body according to the received adjusting signal and the detected water outlet temperature, and sends the heating power to the silicon controlled control module, the heating power of the heating body is automatically adjusted through the silicon controlled control module until the temperature probe detects that the water outlet temperature is the same as the set temperature, and therefore the electric heating faucet automatically realizes the constant water outlet temperature under the conditions of different water inlet temperatures and different flow rates.

The control circuit further comprises a power supply module, the power supply module is an ACDC module, and the power supply module supplies power to the first circuit board, the second circuit board and the heating body through external voltage.

In this embodiment, the water inlet starting switch is a water pressure switch, as shown in fig. 2 and 7, the water pressure switch comprises a movable contact 13 and a fixed contact 20 which are respectively connected in the circuit and oppositely arranged, and a switch pressing member which is in transmission connection with the movable contact, and the switch pressing member is in transmission connection with the movable contact and seals and isolates the movable contact from the water inlet detection channel. The water inlet detection channel is communicated with a switch pressing piece cavity 10, the switch pressing piece is arranged in the switch pressing piece cavity, the switch pressing piece comprises a pressure adhesive film 11 sealed in the switch pressing piece cavity, the pressure adhesive film is connected with one end of a push rod 12, and the other end of the push rod 12 is connected with a movable contact 13. When no water flows through the water inlet detection channel 18, the pressure adhesive film 11 is not pressed, the switch pressing piece does not act, the movable contact and the fixed contact are in a separated state, and the control circuit is in a disconnected state. After water flow enters the water inlet detection channel, the water flow acts on the pressure rubber film 11, the pressure rubber film is pressed to drive the ejector rod 12 to move, the ejector rod drives the movable contact 13 to move towards the direction of the fixed contact 20, and the movable contact is in contact connection with the fixed contact, so that communication of a control circuit is realized. The water pressure switch can be realized by a water pressure switch with other structures, as long as the movable contact is triggered by water flow pressure to contact and connect the fixed contact.

Example two: as shown in fig. 3, 4, 5, and 6, in this embodiment, the water inlet start switch is a water flow switch, the water flow switch includes a hall sensor 23 electrically connected to the control circuit, and further includes a flow rotating magnet 22 disposed in the water inlet detection channel, the water flow enters the water inlet detection channel 18 to drive the flow rotating magnet to rotate, and the hall sensor senses a water flow signal to turn on the control circuit.

The Hall sensor can be connected with the input end of the central controller, the central controller calculates the heating power of the heating body according to the flow signal detected by the Hall sensor, the water outlet temperature detected by the temperature probe and the set temperature of the key input module, and the silicon controlled control module controls the working state of the silicon controlled rectifier, so that the water outlet temperature detected by the temperature probe is constant at the set temperature set by the key input module. The heating power of the heating body is controlled according to the flow, the water outlet temperature and the set temperature, and the method is more accurate. Here, the water inlet detection channel 18 communicates with the heating chamber 8, the valve core is opened to the cold water state, the water inlet channel 19 communicates with the heating chamber 8, the water inlet detection channel 18 is blocked with the water inlet channel 19, and water flows into the heating chamber 8 through the water inlet channel, which is the same as the embodiment. However, when the valve core is opened to a hot water state, the water inlet channel 19 is blocked from the heating cavity 8, the water inlet detection channel is communicated with the water inlet channel and the heating cavity, water flows into the heating cavity through the water inlet detection channel, and the Hall sensor can detect the flow of the water flows entering the heating cavity.

Similarly, the thyristor 14 is disposed on the heat sink 15, and the heat sink conducts the heat of the thyristor to the flowing water, so that the heat is carried away by the flowing water. The controllable silicon can be arranged in a plurality of places, the radiating fins 15 and the controllable silicon 14 are arranged through bolts and fixed outside the side wall of the water inlet channel 19, the radiating fins extend to form extension parts 16, and the extension parts 16 are inserted in the water inlet channel. Of course, it is preferable to locate the thyristor on top of the water inlet 5, as shown in fig. 3 and 4, and the cold water passing through the water inlet channel takes away the heat from the thyristor. The cooling fin of silicon controlled rectifier can paste the top of intaking the piece and insert into water channel, and the inside water that flows of water intaking is to its rapid cooling, has improved tap's reliability. The controllable silicon can radiate heat through cold water in the water inlet channel and hot water in the heating cavity or the water outlet channel. The radiating fins 15 and the controllable silicon 14 are arranged through bolts and fixed on the side wall of the heating cavity or the water outlet channel, and the extending parts 16 of the radiating fins are inserted in the heating cavity or the water outlet channel. As shown in fig. 5 and 6, the thyristor is arranged outside the outer wall of the heating cavity. The controllable silicon is cooled by water flow in the heating cavity 8 or the water outlet channel 6, although the water temperature in the heating cavity 8 or the water outlet channel is higher than that in the water inlet channel, the controllable silicon can reach more than 100 ℃ in the working state, the water temperature is far lower than the working temperature of the controllable silicon, and the cooling function of the controllable silicon can still be achieved.

The rest is the same as the first embodiment.

While the embodiments of the invention have been disclosed above, it is not limited to the applications set forth in the description and embodiments, but is capable of being applied in all kinds of fields adapted to the invention, and further modifications may readily be made by those skilled in the art, and the invention is therefore not limited to the details shown and described herein, without departing from the general concept defined by the claims and their equivalents.

Claims

1. The utility model provides an intelligence vertical electric heating faucet, includes vertical main part, establishes the heating chamber in the main part, the vertical heating member that is equipped with in the heating chamber, heating member electric connection control circuit, and the main part lower extreme is equipped with the piece of intaking that is used for intaking, and the play water spare that is used for going out water is established to the main part upper end, the piece intercommunication of intaking has the inhalant canal, and the exhalant canal intercommunication has the exhalant canal that feeds through the heating chamber, and the rivers break-make between inhalant canal and the heating chamber is controlled its characterized in that by the case: still be equipped with the measuring channel that intakes by case control and inhalant canal break-make in the main part, establish a start switch that intakes in the measuring channel, the start switch electricity that intakes connect control circuit, control circuit is equipped with the silicon controlled rectifier of electricity connection heating member and control its heating power, opens the case is to hot water state, and inhalant canal intercommunication inhalant canal and heating chamber, rivers get into the measuring channel that intakes and trigger the start switch work that intakes, silicon controlled rectifier control heating member work.

2. The intelligent vertical electric heating faucet of claim 1, wherein: the controllable silicon is arranged on the radiating fin, and the radiating fin transmits heat generated by the controllable silicon to water flow.

3. The intelligent vertical electric heating faucet of claim 2, wherein: the radiating fins are arranged outside the side wall of the water inlet channel, the heating cavity or the water outlet channel, and extend to form extension parts, and the extension parts are inserted into the water inlet channel, the heating cavity or the water outlet channel.

4. The intelligent vertical electric heating faucet of claim 3, wherein: the control circuit comprises a central controller, the input end of the central controller is connected with a key input module, the controlled silicon is connected with the output end of the central controller through a controlled silicon control module, the central controller receives a temperature or power adjusting signal input by the key input module, outputs the signal to the controlled silicon control module according to the received adjusting signal, and controls the heating power of the heating body through the controlled silicon.

5. The intelligent vertical electric heating faucet of claim 4, wherein: the temperature probe used for detecting the temperature of water is arranged in the main body, the temperature probe is connected with the input end of the central controller through the temperature detection module, the output end of the central controller is connected with the display module, the central controller receives the water outlet temperature detected by the temperature probe and displays the water outlet temperature through the display module, the water outlet temperature is compared with the set temperature set by the key input module, the heating power of the heating body is calculated according to the comparison result, the central controller outputs a signal to the silicon controlled control module according to the calculated result, the heating power of the heating body is controlled through the silicon controlled, and the operation is repeated until the water outlet temperature is constant at the set temperature.

6. The intelligent vertical electric heating faucet of claim 5, wherein: control circuit includes first circuit board and second circuit board, central controller, silicon controlled rectifier control module, temperature-detecting module locate on the first circuit board, key input module, display module locate on the second circuit board, set up the panel in the main part, the panel inboard and electric connection panel are located to the second circuit board, first circuit board is located the second circuit board inboard and is connected first circuit board through connector or wire electricity.

7. The intelligent vertical electric heating faucet of any one of claims 1 to 6, wherein: the water inlet starting switch is a water pressure switch, the water pressure switch comprises a movable contact and a fixed contact which are respectively connected into the control circuit, and the water pressure switch also comprises a switch pressing piece which is in transmission connection with the movable contact, the switch pressing piece is arranged in the water inlet detection channel, water flow enters the water inlet detection channel and acts on the switch pressing piece, and the switch pressing piece is pressed and drives the movable contact to move to contact with the fixed contact to conduct the control circuit.

8. The intelligent vertical electric heating faucet of claim 7, wherein: the water inlet detection channel is communicated with a switch pressing piece cavity, the switch pressing piece comprises a pressure adhesive film which is arranged in the switch pressing piece cavity in a sealing mode, the pressure adhesive film is connected with one end of an ejector rod, the other end of the ejector rod is connected with the movable contact, water flows enter the switch pressing piece cavity through the water inlet detection channel and act on the pressure adhesive film, and the pressure adhesive film is pressed and drives the movable contact to move and contact with the fixed contact through the ejector rod.

9. The intelligent vertical electric heating faucet of any one of claims 1 to 6, wherein: the start switch of intaking establish to the rivers switch, the rivers switch include electric connection control circuit's hall sensor and arrange the flow rotation magnet in the water detection passageway in, rivers get into water detection passageway drive flow and rotate magnet and rotate, hall sensor response rivers signal switches on control circuit.

10. The intelligent vertical electric heating faucet of any one of claims 1 to 6, wherein: the controllable silicon and the radiating fins are arranged on the top of the water inlet part.