CN216642528U - Low-power consumption ventilation fan assembly for shower room - Google Patents

Abstract

The utility model discloses a low-power consumption ventilation fan assembly for a shower room, which comprises a ventilation fan body, wherein the ventilation fan body is arranged in the shower room, the low-power consumption ventilation fan assembly for the shower room also comprises a switch and a circuit breaker, the switch is arranged on a door frame of the shower room, the circuit breaker is arranged on a door body of the shower room, and the circuit breaker is in contact with the switch so as to enable the circuit breaker to break the switch; the ventilator body is provided with a controller and an inductor, and the controller is connected with the inductor; the switch is electrically connected with the controller, and the controller triggers the ventilator body and the inductor. The utility model has the advantages of energy saving, environmental protection and low energy consumption.

Description

Low-power consumption ventilation fan assembly for shower room

Technical Field

The utility model relates to the technical field of ventilation equipment, in particular to a low-power consumption ventilation fan assembly for a shower room.

Background

At present, in order to realize ventilation, a ventilation fan is often arranged in a shower room. However, the operation of the ventilator requires power consumption, and if the ventilator is turned on for a long time when no one is in use, unnecessary energy loss is caused. Furthermore, after the user uses the shower room, the user often forgets to turn off the ventilation fan, so that the ventilation fan is still turned on when the user does not use the shower room, electric energy is wasted, and the shower room is not beneficial to environmental protection.

Disclosure of Invention

The utility model aims to solve the technical problem of providing a low-power consumption ventilation fan component for a shower room, which can save energy, is environment-friendly and realizes low energy consumption.

In order to solve the technical problem, the utility model provides a low-power consumption ventilation fan component for a shower room, which comprises a ventilation fan body, wherein the ventilation fan body is arranged in the shower room,

the low-power consumption ventilation fan assembly for the shower room further comprises a switch and a circuit breaker, wherein the switch is installed on a door frame of the shower room, the circuit breaker is installed on a door body of the shower room, the door body is located in the door frame, so that the circuit breaker is in contact with the switch, and the circuit breaker disconnects the switch;

the ventilator body is provided with a controller and an inductor, and the controller is connected with the inductor; the switch is electrically connected with the controller, and the controller triggers the inductor.

Preferably, the circuit breaker is provided with a circuit breaking rod, the switch is provided with a groove and a trigger button positioned in the groove, and the circuit breaking rod is inserted into the groove and is abutted against the trigger button.

Preferably, the circuit breaking rod comprises a transition section and an abutting section, wherein the transition section is horizontally arranged, the abutting section is vertically arranged, the transition section is directly connected with the abutting section, and the abutting section is inserted into the groove and abuts against the trigger button.

Preferably, the switch is provided with a trigger bulge, and the circuit breaker is abutted against the trigger bulge.

Preferably, a timer is arranged on the sensor and connected with the controller.

Preferably, the sensor is an infrared sensor.

Preferably, the low-power consumption ventilation fan assembly for the shower room further comprises a ventilation pipe, and the outlet end of the ventilation pipe is provided with a wind energy collecting device.

Preferably, the wind energy collecting device comprises a wind driven generator, a storage capacitor and a transformer, the wind driven generator is connected with the storage capacitor, and the storage capacitor is connected with the ventilator body through the transformer.

The implementation of the utility model has the following beneficial effects:

according to the utility model, the switch and the circuit breaker are arranged, the switch is arranged on the door frame of the shower room, and the circuit breaker is arranged on the door body of the shower room, so that when the door body is positioned in the door frame, the circuit breaker is in contact with the switch, the switch can be disconnected by the circuit breaker, the switch is kept closed, and the ventilation fan body is kept in a closed state.

The ventilator body is provided with a controller and an inductor, and the controller is connected with the inductor; when the door body is far away from the door frame, the breaker is also far away from the switch, so that the switch is opened and is electrically connected with the controller, and the controller sends an opening signal to start the ventilator body, thereby realizing the function of automatically opening and closing the ventilator body.

The controller can trigger the sensor to sense whether the user is in the shower room or not, so that when the user is in the shower room, the sensor can feed back a signal to the controller, and even if the door body is closed to the door frame, the controller can reject a closing signal sent by the switch, so that the ventilator body can continuously run when the user uses the shower room; on the contrary, when the inductor does not detect that the user is in the shower room, once the door body is closed, the switch is contacted with the switch through the circuit breaker, and the switch can send a closing signal to the controller, so that the closing signal is received through the controller, the ventilator body is closed, and the effects of reducing energy consumption and saving energy are realized.

Drawings

FIG. 1 is a structural view of a low power consumption ventilation fan assembly for a shower room according to the present invention;

fig. 2 is a combined structure view of the switch and the circuit breaker shown in fig. 1;

FIG. 3 is a schematic block diagram of a low power consumption ventilation fan assembly for a shower room according to the present invention;

fig. 4 is a functional block diagram of the inductor shown in fig. 3.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings. It is only noted that the utility model is intended to be limited to the specific forms set forth herein, including any reference to the drawings, as well as any other specific forms of embodiments of the utility model.

With reference to fig. 1 to 4, the utility model provides a low-power consumption ventilator assembly for a shower room, which comprises a ventilator body 2, wherein the ventilator body 2 is installed in the shower room. The shower room comprises a door body 11 and a door frame 12, wherein the door body 11 can rotate relative to the door frame 12.

According to the utility model, the switch 31 and the circuit breaker 32 are arranged, the switch 31 is arranged on the door frame 12 of the shower room, and the circuit breaker 32 is arranged on the door body 11 of the shower room, so that when the door body 11 is positioned in the door frame 12, the circuit breaker 32 is in contact with the switch 31, and the switch 31 can be disconnected by the circuit breaker 32, so that the switch 31 is kept closed, and the ventilation fan body 2 is kept in a closed state.

The ventilator body 2 is provided with a controller 21 and an inductor 22, and the controller 21 is connected with the inductor 22; when the door 11 is far from the door frame 12, the circuit breaker 32 is also far from the switch 31, so that the switch 31 is opened and electrically connected with the controller 21, and the controller 21 sends an opening signal to start the ventilator body 2, thereby realizing the function of automatically opening and closing the ventilator body 2.

In addition, the controller 21 can also trigger the sensor 22 to sense whether the user is in the shower room, so that when the user is in the shower room, the sensor 22 can feed back a signal to the controller 21, and even if the door body 11 is closed to the door frame 12, the controller 21 can also reject the closing signal sent by the switch 31, so that the ventilator body 2 can continuously operate when the user uses the shower room; on the contrary, when the sensor 22 does not detect that the user is in the shower room, after the door 11 is closed, the circuit breaker 32 contacts the switch 31, and the switch 31 sends a closing signal to the controller 21, so that the controller 21 receives the closing signal to close the ventilator body 2, thereby reducing energy consumption and saving energy.

Specifically, with reference to fig. 1 and fig. 2, in order to implement the control function of the circuit breaker 32 on the switch 31, the circuit breaker 32 is provided with a breaking rod 321, the switch 31 is provided with a groove 311 and a trigger button located in the groove 311, the breaking rod 321 passes through the groove 311 and abuts against the trigger button, and by pressing the trigger button, the switch 31 sends a closing signal to the controller 21 and is in a closing state; on the contrary, when the breaking rod 321 leaves the groove 311 and the trigger button is not stressed, the switch 31 is turned on and sends an on signal to the controller 21, so as to turn on the ventilator body 2, realize automatic switching of the ventilator body 2, prevent the ventilator body 2 from being turned on during an unmanned period, and reduce energy consumption. Further, the trip bar 321 includes a horizontally disposed transition section 322 and a vertically disposed abutment section 323, and the transition section 322 and the abutment section 323 are directly connected, so that the abutment section 323 can be inserted into the recess 311 and abut against the trigger button. Preferably, in order to further ensure that the breaker 32 can trigger the switch 31, a trigger protrusion 312 is arranged on the switch 31, and the switch 31 is enabled to send a closing signal to the controller 21 and be in a closing state by abutting the breaker 32 against the trigger protrusion 312; on the contrary, when the door 11 is far away from the door frame 12, the circuit breaker 32 is far away from the switch 31, and the switch 31 is turned on and sends an on signal to the controller 21, so as to turn on the ventilator body 2.

It should be noted that the breaker 32 needs to be abutted against the trigger protrusion 312, and when the trip lever 321 presses the trigger button, the switch 31 is in the off state, otherwise, the switch 31 is kept in the on state.

On the other hand, referring to fig. 3 and 4, in order to make the sensor 22 to sense whether the user is in the shower room, the sensor 22 is an infrared sensor 22. Preferably, in order to prevent the sensor 22 from detecting no user and generating a signal to turn off the ventilator body 2, the sensor 22 is provided with a timer 23, and the timer 23 is connected with the controller 21, so that when the sensor 22 does not detect a user and the door 11 is far away from the door frame 12, the timer 23 is started and starts to time; and when the timing time exceeds the preset time, the timer 23 sends a signal to the controller 21 to enable the controller 21 to close the ventilator body 2, so that even if the door 11 is not closed into the door frame 12, the ventilator body 2 stops operating after running for a certain time, thereby further preventing the ventilator body 2 from being started for a long time when no one is in use, and saving energy. Preferably, when the user returns to the bathroom within the preset time, the timer 23 stops timing and resets to zero, and the ventilator body 2 is kept turned on.

In addition, with reference to fig. 1, the utility model further includes a ventilation pipe 13, the ventilation pipe 13 is installed on the shower room, and the ventilator body 2 is located in the ventilation pipe 13, in order to further improve the environmental protection and energy saving effect, the outlet end of the ventilation pipe 13 is further provided with a wind energy collecting device 4 for converting the wind discharged from the ventilator body 2 into electric energy and transmitting the electric energy back to the ventilator body 2. Specifically, the wind energy collecting device 4 comprises a wind driven generator, a storage capacitor and a transformer, the wind driven generator is connected with the storage capacitor, electric energy converted from wind power is stored in the storage capacitor, and then the storage capacitor is connected with the ventilator body 2 through the transformer to provide power for the motor of the ventilator body 2, so that energy circulation is realized, and energy consumption is further reduced.

The utility model has the following examples:

in the first embodiment, when the user is not in the shower room and the door 11 is located in the door frame 12, the circuit breaker 32 contacts the switch 31, so that the circuit breaker 32 can disconnect the switch 31, and the switch 31 is kept closed, thereby ensuring that the ventilator body 2 is kept in a closed state.

In the second embodiment, when the door 11 is far away from the door frame 12, the circuit breaker 32 is also far away from the switch 31, so that the switch 31 is turned on and electrically connected to the controller 21, so as to send an on signal to the controller 21 to start the ventilator body 2. At this time, the controller 21 also triggers the sensor 22 to sense whether the user is in the shower room, and if the user is not in the shower room for a long time, the ventilator body 2 is automatically turned off.

In the third embodiment, when the user is in the shower room and the door 11 is in the door frame 12, the sensor 22 senses the user and feeds back a signal to the controller 21, so that even if the door 11 is closed in the door frame 12, the controller 21 can reject the closing signal sent by the switch 31, so that the ventilator body 2 can continuously operate when the user uses the shower room.

While the foregoing is directed to the preferred embodiment of the present invention, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the utility model.

Claims (8)

1. A low-power consumption ventilation fan component for a shower room comprises a ventilation fan body, the ventilation fan body is arranged in the shower room, and is characterized in that,

the low-power consumption ventilation fan assembly for the shower room further comprises a switch and a circuit breaker, wherein the switch is installed on a door frame of the shower room, the circuit breaker is installed on a door body of the shower room, and the circuit breaker is in contact with the switch so as to enable the circuit breaker to break the switch;

the ventilator body is provided with a controller and an inductor, and the controller is connected with the inductor; the switch is electrically connected with the controller, and the controller triggers the ventilator body and the inductor.

2. The low power consumption ventilator assembly for shower cubicle according to claim 1, characterized in that said circuit breaker is provided with a breaking rod, said switch is provided with a recess and a triggering button located in said recess, said breaking rod is inserted in said recess and abuts against said triggering button.

3. The low power consumption ventilator assembly for shower enclosure as claimed in claim 2, wherein said circuit breaking bar comprises a horizontally disposed transition section and a vertically disposed abutment section, said transition section and abutment section being directly connected, said abutment section being inserted into said recess and abutting against said trigger button.

4. The low power consumption ventilator assembly for a shower enclosure as claimed in claim 1, wherein said switch is provided with a triggering protrusion, and said circuit breaker abuts against said triggering protrusion.

5. The low power consumption ventilator assembly for shower enclosure as claimed in claim 1, wherein a timer is provided on said sensor, said timer being connected to said controller.

6. The low power consumption ventilator assembly for shower cubicle according to claim 1, characterized in that said sensor is an infrared sensor.

7. The low power consumption ventilator assembly for shower room as claimed in claim 1, further comprising a ventilation tube, an outlet end of which is provided with a wind energy collecting device.

8. The low-power consumption ventilator assembly for the shower room according to claim 7, wherein the wind energy collecting device comprises a wind driven generator, a storage capacitor and a transformer, the wind driven generator is connected with the storage capacitor, and the storage capacitor is connected with the ventilator body through the transformer.

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