CN219808443U - Flow control device and bubbler with same - Google Patents

Abstract

The utility model relates to the field of bubblers, in particular to a flow control device and a bubbler with the same, comprising a power generation assembly, an induction assembly, a flow regulating assembly and a shell, wherein a water inlet end and a water outlet end are arranged on the shell, a flow passage is arranged between the water inlet end and the water outlet end, the power generation assembly and the flow regulating assembly are arranged in the flow passage, and the power generation assembly is connected with the induction assembly and the flow regulating assembly. When water is introduced into the flow passage, the power generation assembly automatically generates power, synchronously electrifies the induction assembly and the flow regulating assembly, and controls the flow rate of the flow passage by the flow regulating assembly. The water outlet end of the flow control device is automatically activated when water is supplied, and the work is automatically stopped when the water outlet end is stopped.

Description

Flow control device and bubbler with same

Technical Field

The utility model relates to the field of bubblers, in particular to a flow control device and a bubbler with the same.

Background

The faucet is used as an essential device for daily production and living and widely applied to places such as kitchens, toilets and the like. The conventional faucet generally needs to cut off water supply temporarily in daily use, the operation can be completed by controlling the mixing valve, but the adjusted water temperature is easy to change by touching the mixing valve, and meanwhile, the handle of the mixing valve is touched under the state that both hands are coated with Man Xi liquid detergent or hand sanitizer, so that the overall operation is not sanitary and inconvenient.

In view of the above, it is necessary to install a flow control device and a bubbler having the same in a faucet, which solve the above problems.

Disclosure of Invention

The utility model aims at overcoming the defects of the prior art and provides a flow control device and a bubbler with the same.

In order to solve the technical problems, the following technical scheme is adopted:

the utility model provides a accuse flow device, includes power generation component, response subassembly, flow regulating assembly and casing, be equipped with inlet end and play water end on the casing, be equipped with the passageway that overflows between inlet end and the play water end, power generation component and flow regulating assembly set up in the passageway that overflows, power generation component connects response subassembly and flow regulating assembly.

When water is introduced into the flow passage, the power generation assembly automatically generates power, synchronously electrifies the induction assembly and the flow regulating assembly, and controls the flow rate of the flow passage by the flow regulating assembly.

Further, the power generation assembly is a hydroelectric generator.

Further, a sealing ring is arranged between the outer wall of the power generation assembly and the shell.

Further, the induction component comprises an induction panel and a compiler, the induction panel is electrically connected with the compiler, the compiler is connected with the power generation component, and the induction panel is arranged on the exposed surface of the side edge of the shell when in infrared induction or is arranged inside the shell when in radar induction.

Further, the flow regulating assembly comprises a flow regulating motor and a regulating shaft, the flow regulating motor is connected with the regulating shaft, and the regulating shaft is arranged at the water inlet end, the water outlet end or in the flow passage.

Further, the adjusting shaft enters or exits the water inlet end, the water outlet end or the flow passage under the drive of the flow adjusting motor;

when the adjusting shaft is driven by the flow adjusting motor to enter the water inlet end, the water outlet end or the flow passage, a fit clearance is formed between the adjusting shaft and the water inlet end, the water outlet end or the flow passage, and the fit clearance ensures that water flow is not interrupted and the power generation assembly is driven to continuously work;

when the adjusting shaft is driven by the flow adjusting motor to exit from the water inlet end, the water outlet end or the flow passage, the water outlet end is smooth to discharge water.

Further, the current regulating motor is a stepping motor or a direct current rotating motor.

Further, the water inlet end is further provided with a filter screen, and the filter screen is used for intercepting impurities from entering the flow passage.

Further, the power generation assembly, the induction assembly and the current regulating assembly are connected in series to form a closed circuit, and the closed circuit is further provided with a voltage stabilizing and rectifying device.

The utility model provides another technical scheme of a bubbler, which comprises the flow control device and further comprises a water outlet bubbler, wherein the water outlet bubbler is arranged at the upper part or the lower part of the shell.

Due to the adoption of the technical scheme, the method has the following beneficial effects:

the utility model relates to a flow control device and a bubbler with the same, wherein the flow control device is automatically activated when water is supplied to a water outlet end of the flow control device, and the work is automatically stopped when the water supply end is stopped. The utility model uses a power generation assembly to generate a current to drive an induction assembly and a current regulation assembly. When the faucet is used, the traditional switch is turned on, and the flow control device enters a standby state. When people send signals to the sensing panel through gestures, the flow regulating assembly can regulate the water passing amount of the waterway, so that the water passing amount is extremely small, and the waterway temporarily enters a state close to water cut-off. However, the water is not completely cut off, a small amount of water flows out, so that the water is prevented from cooling in winter, and bad experience is caused for the next boiled water of a user.

Drawings

The utility model is further described below with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of a bubbler with a flow control device according to an embodiment of the present utility model.

Fig. 2 is a state diagram of a flow regulating assembly disposed at a water inlet end according to an embodiment of the present utility model.

Fig. 3 is a second state diagram of the flow regulating assembly disposed at the water inlet end according to the first embodiment of the present utility model.

Fig. 4 is a first state diagram of the flow regulating assembly disposed at the water inlet end according to the second embodiment of the present utility model.

Fig. 5 is a second state diagram of the flow regulating assembly of the second embodiment of the present utility model disposed at the water inlet end.

The device comprises a 1-power generation assembly, a 2-induction assembly, a 3-flow regulating assembly, a 31-flow regulating motor, a 32-regulating shaft, a 4-shell, a 41-water inlet end, a 42-water outlet end, a 43-flow passage, a 6-sealing ring, a 7-filter screen, an 8-water outlet bubbler, a 9-faucet and a 10-fit gap.

Description of the embodiments

The present utility model will be further described in detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the detailed description and specific examples, while indicating the utility model, are intended for purposes of illustration only and are not intended to limit the scope of the utility model. In addition, in the following description, descriptions of well-known structures and techniques are omitted so as not to unnecessarily obscure the present utility model.

Examples

Referring to fig. 1, a flow control device comprises a power generation assembly 1, an induction assembly 2, a flow regulating assembly 3 and a shell 4, wherein a water inlet end 41 and a water outlet end 42 are arranged on the shell 4, a flow passage 43 is arranged between the water inlet end 41 and the water outlet end 42, the power generation assembly 1 and the flow regulating assembly 3 are arranged in the flow passage 43, and the power generation assembly 1 is connected with the induction assembly 2 and the flow regulating assembly 3. When water is introduced into the flow passage 43, the power generation assembly 1 automatically generates power, synchronously energizes the induction assembly 2 and the flow regulating assembly 3, and controls the flow rate of the flow passage 43 by the flow regulating assembly 3. The water outlet end 42 of the flow control device is automatically activated when water is supplied, and the water outlet end 42 automatically stops working when water is stopped. The utility model uses a power generation assembly 1 to generate a current to drive a sensing assembly 2 and a current regulating assembly 3. When the faucet 9 is used, the conventional switch is turned on, and the flow control device enters a standby state. When people send signals to the sensing panel through gestures, the flow regulating assembly 3 can regulate the water passing amount of the waterway, so that the water passing amount is extremely small, and the waterway temporarily enters a state close to water cut-off. However, the water is not completely cut off, a small amount of water flows out, so that the water is prevented from cooling in winter, and bad experience is caused for the next boiled water of a user.

As a further illustration of this embodiment, the power generation assembly 1 is a hydroelectric generator.

As a further explanation of the present embodiment, a seal ring 6 is provided between the outer wall of the power generation module 1 and the housing 4.

As a further explanation of this embodiment, the sensing assembly 2 includes a sensing panel and a compiler, the sensing panel is electrically connected to the compiler, and the compiler converts the signal received by the sensing panel into a set command to control the current regulating motor to act. The induction panel is arranged on the exposed surface of the side edge of the shell 4 when using infrared induction, or is arranged inside the shell 4 when using radar induction.

As a further explanation of this embodiment, the flow regulating assembly 3 includes a flow regulating motor 31 and a regulating shaft 32, where the flow regulating motor 31 is connected to the regulating shaft 32, and the regulating shaft 32 is disposed in the water inlet end 41, the water outlet end 42 or the flow passage 43.

As a further explanation of this embodiment, the adjusting shaft 32 is driven by the current adjusting motor 31 to enter or exit the water inlet end 41.

Referring to fig. 3, when the adjusting shaft 32 is driven by the flow-adjusting motor 31 to enter the water inlet end 41, a fit gap 10 is formed between the adjusting shaft 32 and the water inlet end 41, and the fit gap 10 ensures that the water flow is not interrupted and drives the power generation assembly 1 to continuously work.

Referring to fig. 2, when the adjusting shaft 32 is driven by the flow adjusting motor 31 to withdraw from the water inlet end 41, the water outlet end 42 is free of water.

As a further explanation of the present embodiment, the current adjusting motor 31 is a stepping motor or a dc rotating motor.

As a further illustration of this embodiment, the water inlet end 41 is further provided with a filter screen 7, and the filter screen 7 is used to intercept impurities from entering the flow passage 43.

As a further explanation of this embodiment, the power generation assembly 1, the induction assembly 2 and the current regulation assembly 3 are connected in series to form a closed circuit, and the closed circuit is further provided with a voltage stabilizing and rectifying device.

The utility model provides another technical scheme of the bubbler, which comprises the flow control device and further comprises a water outlet bubbler 8, wherein the water outlet bubbler 8 is arranged at the upper part or the lower part of the shell 4.

When the water faucet 9 is used, the traditional switch is turned on firstly, and the flow control device enters a standby state. When people send signals to the sensing panel through gestures, the flow regulating assembly 3 can regulate the water passing amount of the waterway, so that the water passing amount is extremely small, and the waterway temporarily enters a state close to water cut-off. However, the water is not completely cut off, a small amount of water flows out, so that the water is prevented from cooling in winter, and bad experience is caused for the next boiled water of a user. When a person sends a signal to the sensing panel again through gestures, the flow regulating component 3 can regulate the water passing quantity of the waterway, so that the water flow is smooth.

Examples

The point of difference from the first embodiment is that: the adjusting shaft 32 is driven by the flow adjusting motor 31 to enter or exit the water inlet end 41.

Referring to fig. 5, when the adjusting shaft 32 is driven by the flow-adjusting motor 31 to enter the water inlet end 41, a fit gap 10 is formed between the adjusting shaft 32 and the water inlet end 41, and the fit gap 10 ensures that the water flow is not interrupted and drives the power generation assembly 1 to continuously work.

Referring to fig. 4, when the adjusting shaft 32 is driven by the flow adjusting motor 31 to withdraw from the water inlet end 41, the water outlet end 42 is free of water.

Examples

The point of difference from the first embodiment is that: the adjusting shaft 32 is driven by the current adjusting motor 31 to enter or exit the current passing channel 43.

When the adjusting shaft 32 is driven by the current adjusting motor 31 to enter the current passing channel 43, a fit gap 10 is formed between the adjusting shaft 32 and the current passing channel 43, and the fit gap 10 ensures that the water flow is not interrupted and drives the power generating assembly 1 to continuously work.

When the adjusting shaft 32 is driven by the flow-adjusting motor 31 to withdraw from the flow-through channel 43, the water outlet end 42 is free of water.

The above is only a specific embodiment of the present utility model, but the technical features of the present utility model are not limited thereto. Any simple changes, equivalent substitutions or modifications made on the basis of the present utility model to solve the substantially same technical problems and achieve the substantially same technical effects are encompassed within the scope of the present utility model.

Claims (10)

1. A flow control device, characterized in that: the water inlet end and the water outlet end are arranged on the shell, a flow passage is arranged between the water inlet end and the water outlet end, the power generation assembly and the flow regulating assembly are arranged in the flow passage, and the power generation assembly is connected with the sensing assembly and the flow regulating assembly;

when water is introduced into the flow passage, the power generation assembly automatically generates power, synchronously electrifies the induction assembly and the flow regulating assembly, and controls the flow rate of the flow passage by the flow regulating assembly.

2. A flow control device according to claim 1, characterized in that: the power generation assembly is a hydroelectric generator.

3. A flow control device according to claim 2, characterized in that: and a sealing ring is arranged between the outer wall of the power generation assembly and the shell.

4. A flow control device according to claim 1, characterized in that: the induction component comprises an induction panel and a compiler, wherein the induction panel is electrically connected with the compiler, the compiler is connected with the power generation component, and the induction panel is arranged on the exposed surface of the side edge of the shell when in infrared induction or is arranged inside the shell when in radar induction.

5. A flow control device according to claim 1, characterized in that: the flow regulating assembly comprises a flow regulating motor and a regulating shaft, the flow regulating motor is connected with the regulating shaft, and the regulating shaft is arranged at the water inlet end, the water outlet end or in the flow passage.

6. A flow control device according to claim 5, wherein: the adjusting shaft is driven by the flow adjusting motor to enter or exit the water inlet end, the water outlet end or the flow passage;

when the adjusting shaft is driven by the flow adjusting motor to enter the water inlet end, the water outlet end or the flow passage, a fit clearance is formed between the adjusting shaft and the water inlet end, the water outlet end or the flow passage, and the fit clearance ensures that water flow is not interrupted and the power generation assembly is driven to continuously work;

when the adjusting shaft is driven by the flow adjusting motor to exit from the water inlet end, the water outlet end or the flow passage, the water outlet end is smooth to discharge water.

7. A flow control device according to claim 5, wherein: the current regulating motor is a stepping motor or a direct current rotating motor.

8. A flow control device according to claim 1, characterized in that: the water inlet end is also provided with a filter screen, and the filter screen is used for intercepting impurities from entering the flow passage.

9. A flow control device according to claim 1, characterized in that: the power generation assembly, the induction assembly and the current regulating assembly are connected in series to form a closed circuit, and the closed circuit is further provided with a voltage stabilizing and rectifying device.

10. A bubbler comprising a flow control device as claimed in any one of claims 1 to 9 wherein: the water outlet bubbler is arranged at the upper part or the lower part of the shell.