CN210721116U - Infrared socket control structure - Google Patents

Abstract

The utility model discloses an infrared socket control structure, which comprises a socket, a first power supply device, a wireless transceiver, a first main control chip, an electromagnetic relay, a first electronic switch, an infrared emitter, an infrared sensor, a second power supply device, a second main control chip and a second electronic switch, wherein the first power supply device, the wireless transceiver and the first main control chip are sequentially connected in series to form a loop, the electromagnetic relay is connected in series with the first electronic switch, then connect in parallel between first main control chip and first power supply with wireless transceiver, infrared emitter is used for launching the infrared light, and electromagnetic relay is used for changing infrared sensor to the receiving state of infrared light, and second power supply, second main control chip and infrared sensor establish ties in proper order and form the return circuit, and second main control chip is connected with the second electronic switch electricity, and the second electronic switch control socket and the on-off state between the socket power.

Description

Infrared socket control structure

[ technical field ] A method for producing a semiconductor device

The utility model relates to an infrared socket control structure belongs to the socket field.

[ background of the invention ]

The use positions of the sockets are various, and some sockets are arranged at higher positions, so that the on-off of the sockets is difficult to control. However, if some remote control modes are adopted, due to the influence of obstacles around the socket and the like, signals are easily blocked, and the situation that the on-off control of the socket is not flexible occurs.

[ Utility model ] content

The utility model aims to solve the technical problem that overcome prior art not enough and provide an infrared socket control structure convenient to control.

Solve the technical problem, the utility model discloses a following technical scheme:

the utility model provides an infrared socket control structure, which comprises a socket, first power supply ware, wireless transceiver, first main control chip, electromagnetic relay, first electronic switch, infrared transmitter, infrared sensor, the second power supply ware, second main control chip and second electronic switch, first power supply ware, wireless transceiver and first main control chip establish ties in proper order and form the return circuit, electromagnetic relay establishes ties with first electronic switch, then parallelly connected between first main control chip and first power supply ware with wireless transceiver, infrared transmitter is used for the transmission infrared light, electromagnetic relay is used for changing infrared sensor to the receipt state of infrared light, the second power supply ware, second main control chip and infrared sensor establish ties in proper order and form the return circuit, second main control chip is connected with second electronic switch electricity, the on-off state between second electronic switch control socket and the socket power.

The utility model has the advantages that:

the first power supply device, the wireless transceiver and the first main control chip are sequentially connected in series to form a loop, and the first power supply device supplies power to the wireless transceiver and the first main control chip. The socket is located higher position such as wardrobe top center, and wireless transceiver is then located the position of wardrobe top edge to wireless transceiver carries out wireless connection with wireless terminal such as cell-phone, and carries out signal transmission with the mode of rectilinear propagation as far as possible, reduces the barrier such as wardrobe to the signal transmission influence between wireless transceiver and the cell-phone. After the wireless transceiver receives a mobile phone signal, the signal is transmitted to the first main control chip, and the first main control chip controls the first electronic switch to be closed, so that the first power supply device supplies power to the electromagnetic relay. When the wireless transceiver receives the mobile phone signal again and transmits the mobile phone signal to the first main control chip, the first main control chip controls the first electronic switch to be switched on, so that the electromagnetic relay is powered off. The power on and off of the electromagnetic relay is controlled through a mobile terminal such as a mobile phone, so that the movable end of the electromagnetic relay moves, and the infrared receiving state of the infrared sensor is changed. The second power supply, the second main control chip and the infrared sensor are sequentially connected in series to form a loop, and the second power supply simultaneously supplies power to the second main control chip and the infrared sensor so as to keep the working states of the second main control chip and the infrared sensor and ensure that the infrared sensor is ready to receive infrared light all the time. Once the infrared sensor receives the infrared light, corresponding information is transmitted to the second main control chip. The second electronic switch controls the on-off state between the socket and the socket power supply, and the second electronic switch is a main switch of the socket. The second main control chip is electrically connected with the second electronic switch, the second main control chip controls the second electronic switch to be closed when receiving signals of the infrared sensor, and at the moment, the socket power supply can supply power to electrical appliances plugged on the socket. And otherwise, when the second main control chip stops receiving the signal of the infrared sensor, the second electronic switch is turned on, and the socket power supply stops supplying power to the electrical appliance.

The second electronic switch 10 controls the on/off state between the socket 11 and the socket power supply, and the second electronic switch 10 is a main switch of the socket 11. The socket power supply enables the socket 11 to supply power to some high-power electrical appliances, and the generated power of the first power supply 1, the second power supply 8 and the third power supply 12 is smaller in the embodiment.

The infrared emitter 6 is used for emitting infrared light, and the infrared sensor 7 is used for receiving the infrared light emitted by the infrared emitter 6. The movement of the movable end of the electromagnetic relay 4 controls whether the infrared sensor 7 can receive the infrared light emitted by the infrared emitter 6.

The electromagnetic relay 4 is used for changing the receiving state of the infrared sensor 7 to the infrared light.

The utility model discloses still include the third power supply ware, infrared emitter, third power supply ware and electromagnetic relay's movable end establishes ties in proper order and forms the return circuit to through electromagnetic relay control infrared emitter's on-state, infrared emitter's transmission mouth is towards infrared sensor.

The utility model discloses still include third power supply ware and scattering piece, infrared emitter and third power supply ware electricity are connected, and the scattering piece is installed at electromagnetic relay's the end that moves, moves the end activity and sets up in infrared emitter department in order to drive the scattering piece activity, and infrared emitter's transmission mouth staggers with infrared sensor.

Infrared sensor is located the outer wall of socket, second power supply ware and second main control chip are located the socket.

The utility model discloses still include the casing and clamp the PCB board in the casing, first power supply ware, wireless transceiver, first main control chip, electromagnetic relay, first electronic switch, infrared transmitter and third power supply ware are all installed on the PCB board.

The utility model discloses still include first circular telegram switch, first power supply ware, wireless transceiver, first main control chip and first circular telegram switch establish ties in proper order, and first circular telegram switch is ship type switch, and first circular telegram switch rotates and sets up on the casing, and a part of first circular telegram switch exposes in the casing.

The utility model discloses still including the second on-off switch of establishing ties between infrared emitter and third power supply ware, second on-off switch is ship type switch, and second on-off switch rotates and sets up on the casing, and a part of second on-off switch exposes in the casing.

The collecting lens is disassembled from the transmitting port of the infrared transmitter.

Other features and advantages of the present invention will be disclosed in more detail in the following detailed description and the accompanying drawings.

[ description of the drawings ]

The invention will be further explained with reference to the drawings:

fig. 1 is a schematic circuit diagram of an infrared socket control structure according to embodiment 1 of the present invention;

fig. 2 is a schematic diagram of a circuit structure of an infrared socket control structure according to embodiment 2 of the present invention.

[ detailed description ] embodiments

The technical solutions of the embodiments of the present invention are explained and explained below with reference to the embodiments of the present invention and the accompanying drawings, but the following embodiments are only preferred embodiments of the present invention, and not all embodiments. Based on the embodiments in the embodiment, other embodiments obtained by those skilled in the art without any creative work belong to the protection scope of the present invention.

In the following description, the appearances of the indicating orientation or positional relationship, such as the terms "inner", "outer", "upper", "lower", "left", "right", etc., are only for convenience in describing the embodiments and for simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and are not to be construed as limiting the invention.

Example 1:

referring to fig. 1, the present embodiment provides an infrared socket control structure, which includes a first power supply 1, a wireless transceiver 2, a first main control chip 3, an electromagnetic relay 4, a first electronic switch 5, an infrared emitter 6, an infrared sensor 7, a second power supply 8, a second main control chip 9, a second electronic switch 10, and a socket 11.

The first power supplier 1, the wireless transceiver 2 and the first main control chip 3 are connected in series in sequence to form a loop, and the first power supplier 1 supplies power to the wireless transceiver 2 and the first main control chip 3.

The socket 11 is located at a higher position such as the center of the top of the wardrobe, and the wireless transceiver 2 is located at the edge of the top of the wardrobe, so that the wireless transceiver 2 is in wireless connection with wireless terminals such as a mobile phone, signal transmission is carried out in a linear propagation mode as far as possible, and the influence of obstacles such as the wardrobe on the signal transmission between the wireless transceiver 2 and the mobile phone is reduced.

The electric relay 4 is connected in series with the first electronic switch 5, and then the electric relay 4 and the first electronic switch 5 are connected in parallel with the wireless transceiver 2 as a whole between the first main control chip 3 and the first power supply 1.

After the wireless transceiver 2 receives a mobile phone signal, the signal is transmitted to the first main control chip 3, and the first main control chip 3 controls the first electronic switch 5 to be closed, so that the first power supply 1 supplies power to the electromagnetic relay 4. When the wireless transceiver 2 receives the mobile phone signal again and transmits the mobile phone signal to the first main control chip 3, the first main control chip 3 controls the first electronic switch 5 to be turned on, so that the electromagnetic relay 4 is powered off. The power on and off of the electromagnetic relay 4 is controlled through a mobile terminal such as a mobile phone, so that the movable end of the electromagnetic relay 4 moves.

The infrared emitter 6 is used for emitting infrared light, and the infrared sensor 7 is used for receiving the infrared light emitted by the infrared emitter 6. The movement of the movable end of the electromagnetic relay 4 controls whether the infrared sensor 7 can receive the infrared light emitted by the infrared emitter 6.

The electromagnetic relay 4 is used for changing the receiving state of the infrared sensor 7 to the infrared light.

The infrared ray socket control structure in this embodiment further includes a third power supply 12. The infrared emitter 6, the third power supply 12 and the movable end of the electromagnetic relay 4 are sequentially connected in series to form a loop. Be provided with closed contact and open contact in the return circuit that infrared emitter 6, third power supply 12 and electromagnetic relay 4 formed, make closed contact when electromagnetic relay 4 moves the end for infrared emitter 6, third power supply 12 and electromagnetic relay 4 move the return circuit that the end formed and switch on, and third power supply 12 can supply power to infrared emitter 6, so that infrared emitter 6 sends the infrared light. On the contrary, when the moving end of the electromagnetic relay 4 is opened to the open contact, the loop formed by the infrared emitter 6, the third power supply 12 and the moving end of the electromagnetic relay 4 cannot conduct electricity, and the corresponding infrared emitter 6 cannot emit infrared light.

The emission opening of the infrared emitter 6 faces the infrared sensor 7, and therefore can be detected by the infrared sensor 7 in the case where the infrared emitter 6 emits infrared light. That is, the present embodiment controls whether the infrared sensor 7 can detect infrared light by controlling the energization of the infrared emitter 6 through the electromagnetic relay 4.

The infrared sensor 7 may be located on an outer wall of the socket 11 so as to receive infrared light emitted from the infrared emitter 6, because infrared light has a weak penetrating power. Meanwhile, the outer wall of the socket 11 can also position the infrared sensor 7, and the alignment state between the infrared emitter 6 and the infrared sensor 7 is ensured as much as possible.

Preferably, a collecting mirror is mounted on and detached from the emission port of the infrared emitter 6, and the collecting mirror focuses infrared light, so that the infrared sensor 7 can effectively sense the insufficient luminous power of the infrared emitter 6.

The second power supply 8, the second main control chip 9 and the infrared sensor 7 are sequentially connected in series to form a loop, and the second power supply 8 simultaneously supplies power to the second main control chip 9 and the infrared sensor 7 so as to keep the working states of the second main control chip 9 and the infrared sensor 7 and ensure that the infrared sensor 7 is ready to receive infrared light all the time. Once the infrared sensor 7 receives the infrared light, corresponding information is transmitted to the second main control chip 9.

The second electronic switch 10 controls the on/off state between the socket 11 and the socket power supply, and the second electronic switch 10 is a main switch of the socket 11. The socket power supply enables the socket 11 to supply power to some high-power electrical appliances, and the generated power of the first power supply 1, the second power supply 8 and the third power supply 12 is smaller in the embodiment.

The second main control chip 9 is electrically connected with the second electronic switch 10, the second main control chip 9 controls the second electronic switch 10 to be closed when receiving the signal of the infrared sensor 7, and at the moment, the socket power supply can supply power to an electric appliance plugged on the socket 11. On the contrary, when the second main control chip 9 stops receiving the signal of the infrared sensor 7, the second electronic switch 10 is turned on, and the socket power supply stops supplying power to the electrical appliance.

In view of saving space and protecting the second electronic switch 10, the second power supply 8 and the second main control chip 9, the second electronic switch 10, the second power supply 8 and the second main control chip 9 are all located in the socket 11. Fig. 1 shows the circuit structure for simplicity and clarity, so the infrared sensor 7, the second power supply 8 and the second main control chip 9 are shown outside the socket 11.

The infrared socket control structure in this embodiment still includes the casing and clamps the PCB board in the casing, and first power supply 1, wireless transceiver 2, first main control chip 3, electromagnetic relay 4, first electronic switch 5, infrared emitter 6 and third power supply 12 are all installed on the PCB board, and then use first power supply 1, wireless transceiver 2, first main control chip 3, electromagnetic relay 4, first electronic switch 5, infrared emitter 6 and third power supply 12 as a whole. The infrared sensor 7, the second power supply 8, the second main control chip 9, the second electronic switch 10 and the socket 11 are used as a whole, so that the use difficulty of a user is effectively reduced.

The shell is also positioned at the top of the wardrobe, and the emitting opening of the infrared emitter 6 is exposed out of the shell so as to ensure that infrared light emitted by the infrared emitter 6 can reach the infrared sensor 7.

Example 2:

referring to fig. 2, the present embodiment provides an infrared socket control structure, which includes a first power supply 1, a wireless transceiver 2, a first main control chip 3, an electromagnetic relay 4, a first electronic switch 5, an infrared emitter 6, an infrared sensor 7, a second power supply 8, a second main control chip 9, a second electronic switch 10, and a socket 11.

The connection mode among the first power supply 1, the wireless transceiver 2, the first main control chip 3, the electromagnetic relay 4 and the first electronic switch 5 is the same as that in embodiment 1, and the connection mode among the infrared sensor 7, the second power supply 8, the second main control chip 9, the second electronic switch 10 and the socket 11 is the same as that in embodiment 1, so that no further description is provided in this embodiment.

The present embodiment is mainly different from embodiment 1 in that the electromagnetic relay 4 changes the manner of receiving the infrared light by the infrared sensor 7.

The infrared socket control structure in this embodiment further includes a third power supply 12 and a diffusion sheet 13.

The infrared emitter 6 and the third power supply 12 are electrically connected, as in the present embodiment, the infrared emitter 6 and the third power supply 12 are connected in series to form a loop, and the third power supply 12 supplies power to the infrared emitter 6 so that the infrared emitter 6 emits infrared light. The emitting port of the infrared emitter 6 is staggered with the infrared sensor 7, so that infrared light emitted by the infrared emitter 6 cannot directly irradiate the infrared sensor 7.

The scattering sheet 13 is fixedly arranged at the movable end of the electromagnetic relay 4, the movable end moves to drive the scattering sheet 13 to move, and the movable range of the scattering sheet 13 is close to the infrared emitter 6. The diffusion sheet 13 is deviated from the emission opening of the infrared emitter 6, and the infrared light does not pass through the diffusion sheet 13, so that the infrared light does not reach the infrared sensor 7. When the scattering sheet 13 reaches the position of the emission opening of the infrared emitter 6, the infrared light is scattered by the scattering sheet 13, reaches the infrared sensor 7, and is further sensed by the infrared sensor 7. At this time, even if the position of the socket 11 is deviated, the infrared sensor 7 can sense the infrared light emitted from the infrared emitter 6.

Example 3:

the difference between this embodiment and embodiment 1 is that the infrared socket control structure further includes a first power switch, and the first power supply, the wireless transceiver, the first main control chip and the first power switch are sequentially connected in series. And the first power supply is controlled by the first power switch to supply power to the wireless transceiver and the first main control chip.

The first power switch is a ship-shaped switch, the first power switch is rotatably arranged on the shell, and one part of the first power switch is exposed out of the shell, so that a user can conveniently control the on-off of a loop formed by the first power supply, the wireless transceiver and the first main control chip.

The first power-on switch should be closed under normal use of the infrared receptacle control structure.

Example 4:

this embodiment is different from embodiment 1 in that the infrared outlet control structure further includes a second energizing switch connected in series between the infrared transmitter and the third power supply. Under the non-user state of infrared ray socket control structure, the second on-off switch is opened, ensures that infrared emitter does not circular telegram, can not send infrared light then, avoids unexpected condition such as shining people's eye.

The second on-off switch is ship type switch, and the second on-off switch rotates and sets up on the casing, and a part of second on-off switch exposes in the casing, and the user of being convenient for controls.

The second switch should be closed under normal use of the infrared socket control structure.

The above description is only for the specific embodiments of the present invention, but the protection scope of the present invention is not limited thereto, and those skilled in the art should understand that the present invention includes but is not limited to the contents described in the above specific embodiments. Any modification which does not depart from the functional and structural principles of the present invention is intended to be included within the scope of the claims.

Claims (8)

1. An infrared socket control structure is characterized by comprising a socket (11), a first power supply device (1), a wireless transceiver (2), a first main control chip (3), an electromagnetic relay (4), a first electronic switch (5), an infrared transmitter (6), an infrared sensor (7), a second power supply device (8), a second main control chip (9) and a second electronic switch (10), wherein the first power supply device (1), the wireless transceiver (2) and the first main control chip (3) are sequentially connected in series to form a loop, the electromagnetic relay (4) is connected in series with the first electronic switch (5) and then connected in parallel with the wireless transceiver (2) between the first main control chip (3) and the first power supply device (1), the infrared transmitter (6) is used for transmitting infrared light, and the electromagnetic relay (4) is used for changing the receiving state of the infrared sensor (7) for the infrared light, the second power supply (8), the second main control chip (9) and the infrared sensor (7) are sequentially connected in series to form a loop, the second main control chip (9) is electrically connected with the second electronic switch (10), and the second electronic switch (10) controls the on-off state between the socket (11) and a socket power supply.

2. The infrared socket control structure as claimed in claim 1, further comprising a third power supply (12), wherein the infrared emitter (6), the third power supply (12) and the moving end of the electromagnetic relay (4) are sequentially connected in series to form a loop, so as to control the power-on state of the infrared emitter (6) through the electromagnetic relay (4), and the emitting port of the infrared emitter (6) faces the infrared sensor (7).

3. The infrared socket control structure according to claim 1, further comprising a third power supply (12) and a scattering sheet (13), wherein the infrared emitter (6) and the third power supply (12) are electrically connected, the scattering sheet (13) is installed at a movable end of the electromagnetic relay (4), the movable end is movable to drive the scattering sheet (13) to be movably arranged at the infrared emitter (6), and an emission port of the infrared emitter (6) is staggered with the infrared sensor (7).

4. An infrared socket control structure as claimed in claim 2 or 3, characterized in that the infrared sensor (7) is located on an outer wall of the socket (11), and the second power supply (8) and the second main control chip (9) are located inside the socket (11).

5. The infrared socket control structure as claimed in claim 2 or 3, further comprising a housing and a PCB board clamped in the housing, wherein the first power supply (1), the wireless transceiver (2), the first main control chip (3), the electromagnetic relay (4), the first electronic switch (5), the infrared emitter (6) and the third power supply (12) are all mounted on the PCB board.

6. The infrared socket control structure as claimed in claim 5, further comprising a first power switch, wherein the first power supply (1), the wireless transceiver (2), the first main control chip (3) and the first power switch are connected in series, the first power switch is a ship-shaped switch, the first power switch is rotatably disposed on the housing, and a portion of the first power switch is exposed out of the housing.

7. The infrared socket control structure as claimed in claim 5, further comprising a second on-off switch connected in series between the infrared emitter (6) and the third power supply (12), wherein the second on-off switch is a boat-type switch, the second on-off switch is rotatably disposed on the housing, and a portion of the second on-off switch is exposed out of the housing.

8. The infrared ray socket control structure as claimed in claim 2, wherein the emission port of the infrared emitter (6) is disassembled with a condenser lens.

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