CN211090078U - Light-emitting control system and light-emitting shoes - Google Patents

Abstract

The utility model relates to a light-emitting control system and a pair of light-emitting shoes, wherein, the light-emitting control system comprises a control device, a detection device, a switch, a first light-emitting circuit, a second light-emitting circuit and a power supply device; the power supply device supplies power to the light emitting control system, and the detection device is used for detecting the environmental condition; the control device is connected with the detection device, acquires the environmental condition detected by the detection device, controls the change-over switch to be switched between the first light-emitting circuit and the second light-emitting circuit based on the detected environmental condition, and switches the change-over switch to the first light-emitting circuit to emit light; the switch is switched to the second light-emitting circuit, and the second light-emitting circuit emits light. The embodiment of the utility model provides a luminous control system and luminous shoes not only can present rich and varied visual effect to can embody the environmental aspect.

Description

Light-emitting control system and light-emitting shoes

Technical Field

The utility model belongs to the technical field of electronic circuit, concretely relates to luminous control system and luminous shoes.

Background

The existing light-emitting circuit is widely applied in the field of modern decoration. The aesthetic feeling and the personality are reflected by different lighting effects presented by the light-emitting circuit. For example, many shoe manufacturers decorate a light emitting circuit on a shoe to attract the attention of consumers, and when the light emitting circuit emits light, an attractive visual effect is exhibited. However, the existing light emitting circuit can only express the decorative effect through the light singly, and cannot reflect the environmental conditions through the light.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem that the light-emitting circuit cannot reflect the environmental conditions through light, the embodiment of the utility model provides a light-emitting control system and luminous shoes.

In one aspect of the present invention, a lighting control system is provided, which includes a control device, a detection device, a switch, a first lighting circuit, a second lighting circuit, and a power supply device; the power supply device supplies power to the light emitting control system, and the detection device is used for detecting the environmental condition;

the control device is connected with the detection device, acquires the environmental condition detected by the detection device, controls the change-over switch to be switched between the first light-emitting circuit and the second light-emitting circuit based on the detected environmental condition, and switches the change-over switch to the first light-emitting circuit to emit light; the switch is switched to the second light-emitting circuit, and the second light-emitting circuit emits light.

In some embodiments, the first light-emitting circuit comprises L ED lamp beads or L ED lamp beads connected in a common cathode or anode, the L ED lamp beads or the L ED lamp beads emit light under the control of the control device, and the second light-emitting circuit comprises a warning lamp which emits light under the control of the control device.

In some embodiments, the detection device includes a current sensor and a rain conducting circuit, the current sensor is connected to the rain conducting circuit, and detects whether current flows through the rain conducting circuit.

In some embodiments, the rain conducting circuit includes a pair of conductive terminals exposed to the environment, the pair of conductive terminals includes a first conductive terminal and a second conductive terminal, the current sensor is connected in series between one end of the first conductive terminal and one end of the second conductive terminal, and a gap is left between the other end of the first conductive terminal and the other end of the second conductive terminal.

In some embodiments, the detection device comprises a humidity sensor for detecting the ambient humidity, the humidity sensor being connected to the control device, the control device controlling the switch to switch between the first light emitting circuit and the second light emitting circuit based on said detected ambient humidity.

In some embodiments, the detection device includes a water absorbing component, and the humidity sensor detects the water content or humidity of the water absorbing component.

In some embodiments, the lighting control system further comprises a light sensor for detecting the intensity of the ambient light, the light sensor being connected to the control device, and the control device adjusting the lighting mode of the first lighting circuit and/or the second lighting circuit according to the detected intensity of the ambient light.

In some embodiments, a manual switch is connected in series between the control device and the changeover switch, the manual switch being in a closed state or in an open state, and the control device controls the changeover switch to be effective in an operation of switching between the first light emitting circuit and the second light emitting circuit based on the detected environmental condition.

In some embodiments, the first lighting circuit comprises a first vibration switch and L ED light bead string, and the second lighting circuit comprises a second vibration switch and a warning light;

the control device is provided with a power supply positive terminal, a grounding terminal, an input/output port and a plurality of signal terminals;

the detection device is connected with the control device through an input/output port, the movable end of the change-over switch is connected with the positive end of the power supply of the control device, the first immovable end of the change-over switch is connected with the positive electrode of the L ED lamp string through the first vibration switch, the negative electrode of the L ED lamp string is connected with a plurality of signal ends of the control device, the second immovable end of the change-over switch is connected with one end of the warning lamp through the second vibration switch, and the other end of the warning lamp is grounded;

or the positive end of the power supply is connected with the positive electrode of the power supply, the negative electrode of the power supply is grounded with the grounding end of the control device, the detection device is connected with the control device through the input/output port, the moving end of the change-over switch is connected with the grounding end of the control device, the first fixed end of the change-over switch is connected with the negative electrode of the L ED lamp bead string through the first vibration switch, the positive electrode of the L ED lamp bead string is connected with a plurality of signal ends of the control device, the second fixed end of the change-over switch is connected with one end of the warning lamp through the second vibration switch, and the other end of the warning lamp is connected with the positive electrode of the power.

In another aspect of the present invention, a pair of luminous shoes is provided, which includes the above-mentioned luminous control system.

The utility model has the advantages that: the embodiment of the utility model provides a luminous control system and luminous shoes not only can present rich and varied visual effect to can embody the environmental aspect.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of a lighting control system according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of an embodiment of a detection device according to the present invention;

fig. 3 is a schematic structural diagram of another embodiment of a lighting control system according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a lighting control system according to still another embodiment of the present invention;

fig. 5 is a schematic structural diagram of another embodiment of a lighting control system according to an embodiment of the present invention.

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 detail with reference to the accompanying drawings. Those skilled in the art will appreciate that the present invention is not limited to the drawings and the following embodiments.

An embodiment of the present invention provides a lighting control system, as shown in fig. 1, including a control device 101, a detection device 102, a switch 103, a first lighting circuit 104, a second lighting circuit 105, and a power supply device (not shown).

The power supply device supplies power to the whole light-emitting control system. In one embodiment, the power supply device may be a battery, and preferably, the battery may be a rechargeable battery.

The detection means 102 are used to detect environmental conditions. In one embodiment, the environmental condition may be, for example, rain or ambient humidity, etc.

The control device 101 is connected with the detection device 102, acquires an environmental condition detected by the detection device 102, and controls the switch 103 to switch between the first light-emitting circuit 104 and the second light-emitting circuit 105 based on the environmental condition, when the switch 103 is switched to the first light-emitting circuit 104, the first light-emitting circuit 104 emits light or emits light under the control of the control device 101, for example, the control device 101 controls the first light-emitting circuit 104 to emit light according to a preset program, or the control device 101 controls the first light-emitting circuit 104 to emit light based on the environmental condition detected by the detection device 102 or parameters acquired by other devices (such as a light sensor which will be described later), when the switch 103 is switched to the second light-emitting circuit 105, the second light-emitting circuit 105 emits light or emits light under the control of the control device 101, for example, the control device 101 controls the second light-emitting circuit 105 to emit light according to a preset program, or the control device 101 controls the second light-emitting circuit 105 to emit light based on the environmental condition detected by the detection device 102 or other devices (such as a light sensor which will be described later), or a plurality of light bulbs which may emit light at the same time, or when the environment is detected by the switch 102, or when the switch 103 may be a plurality of bulbs may be a plurality of bulbs, such as a plurality of bulbs, or a plurality of bulbs, such as a plurality of bulbs, or a plurality of bulbs, such as a plurality of bulbs, such as a plurality.

In one embodiment, the control device 101 comprises a microcontroller.

In one embodiment, the switch 103 is an analog switch chip.

In an embodiment, when detecting rain, as shown in fig. 2, the detecting device 102 may include a current sensor 201 and a rain conducting circuit 202, wherein the current sensor 201 is connected to the rain conducting circuit 202 to detect whether current flows through the rain conducting circuit 202. The rainwater conduction circuit 202 includes a protection resistor 203, a power supply battery 204, and a pair of conductive terminals exposed in the environment, where the pair of conductive terminals includes a first conductive terminal 205 and a second conductive terminal 206, the current sensor 201, the protection resistor 203, and the power supply battery 204 are connected in series between one end of the first conductive terminal 205 and one end of the second conductive terminal 206, the order in which the current sensor 201, the protection resistor 203, and the power supply battery 204 are connected in series is not limited, and a gap (the gap shown in fig. 2 is only schematic) is left between the other end of the first conductive terminal 205 and the other end of the second conductive terminal 206. When raining, the gap is filled with rainwater, and the rainwater becomes a conductor due to impurities contained in the rainwater, so that a resistor is connected in series between the first conductive terminal and the second conductive terminal, so that the rainwater conduction circuit is conducted, and the current sensor 201 detects that current flows through the rainwater conduction circuit 202. When the current sensor 201 detects that current flows through the rain conducting circuit 202, it indicates rain or water enters between the first conducting terminal 205 and the second conducting terminal 206; if the current sensor 201 detects that no current flows in the rain conducting circuit 202, it indicates that it is not raining or that there is no water ingress between the first and second conducting terminals 205, 206. In some cases, the power of the rain water conducting circuit 202 is supplied by the power supply device, or the control device 101 converts the voltage supplied by the power supply device to supply the converted voltage, and the power supply battery 204 may be omitted. In some applications, the protection resistor 203 may not be provided if the current in the rain conducting circuit 202 can be ensured to be within the safe range of the circuit.

In one embodiment, when detecting the ambient humidity, the detecting device 102 may include a humidity sensor for detecting the humidity of the environment. The humidity sensor is connected to the control device 101, and the control device 101 controls the switch 103 to switch between the first light emitting circuit 104 and the second light emitting circuit 105 based on the detected ambient humidity. In some embodiments, the detection device 102 may further include a water absorption component, and the humidity sensor detects the water content or humidity of the water absorption component, so as to detect the ambient humidity.

The control device 101 may detect whether it is raining or not, or may detect the ambient humidity alone, and control the switching of the changeover switch 103 based on the individual detection result. For example, when rain is not detected, the control device 101 controls the changeover switch 103 to switch to the first light-emitting circuit 104, and the first light-emitting circuit 104 emits light; when rain is detected, the changeover switch 103 is switched from the first light emitting circuit 104 to the second light emitting circuit 105, and the second light emitting circuit 105 emits light. In another embodiment, the control device 101 may detect a plurality of environmental conditions at the same time, and control the switching of the switch 103 according to the plurality of environmental conditions. For example, when the detecting device 102 does not detect rain and the ambient humidity does not exceed the preset humidity value, the control device 101 controls the switch 103 to switch to the first light-emitting circuit 104, and the first light-emitting circuit 104 emits light; when the detecting device 102 does not detect rain but the ambient humidity exceeds the preset humidity value, the switch 103 is switched from the first light emitting circuit 104 to the second light emitting circuit 105, and the second light emitting circuit 105 emits light.

In some application scenarios, the light emitting mode of the first light emitting circuit 104 and/or the second light emitting circuit 105 is controlled by the control device 101, for example, a plurality of different light emitting modes are stored in the control device 101, and the first light emitting circuit 104 and/or the second light emitting circuit 105 emits light according to the light emitting mode provided by the control device 101. In one embodiment, the lighting control system further comprises a light sensor for detecting the intensity of the ambient light. The light sensor is connected to the control device 101, and the control device 101 adjusts the light emitting mode of the first light emitting circuit 104 when the first light emitting circuit 104 emits light and/or adjusts the light emitting mode of the second light emitting circuit 105 when the second light emitting circuit 105 emits light according to the detected intensity of the ambient light. The lighting pattern includes not only the flashing frequency and the flashing manner (e.g. flashing water), but also the brightness, the color, etc. to present different lighting effects. Taking the adjustment of the light emitting mode of the first light emitting circuit 104 as an example, when the light sensor detects that the intensity of the ambient light is lower than the preset intensity and the switch 103 is switched to the first light emitting circuit 104, the control device 101 controls the first light emitting circuit 104 to emit light according to the first light emitting mode; when the light sensor detects that the intensity of the ambient light is not lower than the preset intensity and the switch 103 is switched to the first light-emitting circuit 104, the control device 101 controls the first light-emitting circuit 104 to emit light according to the second light-emitting mode. Of course, those skilled in the art will recognize that the preset intensity may be divided into a plurality of light intensity intervals, and the light emitting mode corresponding to each light intensity interval is different. In another embodiment, the control device 101 may control the first light emitting circuit 104 to exhibit different light emitting modes according to the environmental condition detected by the detection device 102. For example, the control device 101 adjusts the light emission pattern (for example, light emission brightness, light emission frequency, light emission manner, light emission color, and the like) of the first light emission circuit 104 when the first light emission circuit 104 emits light in accordance with the ambient humidity detected by the humidity sensor. It will be appreciated that the two embodiments described above may be used in combination.

In one embodiment, a manual switch is connected in series between the control device 101 and the switch 103, and when the manual switch is in a closed state, the control device 101 controls the switch 103 to be effective in switching operation between the first light-emitting circuit 104 and the second light-emitting circuit 105 based on the environmental condition. It may be designed that the control device 101 controls the switching operation of the changeover switch 103 between the first light emitting circuit 104 and the second light emitting circuit 105 to be effective based on the environmental condition when the manual switch is in the on state.

In an embodiment, the control device 101 is connected to the power supply device, and the control device 101 outputs a corresponding voltage signal based on the voltage requirement of the first light emitting circuit 104 or the second light emitting circuit 105 connected to the switch 103. Therefore, in an embodiment, the control device 101 further includes a voltage conversion circuit for converting the voltage of the power supply device into an operating voltage required by the first light emitting circuit 104 or the second light emitting circuit 105.

Fig. 3 shows a schematic diagram of a main structure of a circuit implementation of the lighting control system, the lighting control system includes a control device 301, a detection device 302, a switch 303, a first lighting circuit including a first vibration switch 306 and an L ED lamp bead string 305, and a second lighting circuit including a second vibration switch 307 and a warning lamp 304.

The control device 301 comprises a power supply positive terminal VDD, a ground terminal GND, an input/output port IO and a plurality of signal terminals L, L, … … and L n, the power supply positive terminal VDD is connected with a positive terminal of a power supply, a negative terminal of the power supply and the ground terminal GND are grounded, the detection device 302 is connected with the control device 301 through the input/output port IO, a moving terminal of the switch 303 is connected with the power supply positive terminal VDD of the control device 301, a first fixed terminal a of the switch 303 is connected with a positive terminal of the L ED lamp bead string 305 through a first vibration switch 306, a negative terminal of the L ED lamp bead string 305 is connected with a plurality of signal terminals L, L, … … and L n of the control device 301, wherein in some embodiments, one signal terminal may correspond to one or a plurality of L lamp beads, a second fixed terminal b of the switch 303 is connected with one end of the control device 304 through a second vibration switch 307, the other end b of the switch 303 is connected with one terminal of the control device 301 through a second vibration switch 468, the positive terminal 468, another end of the switch 301 is connected with a of the power supply positive terminal VDD, a of the power supply, the power supply positive terminal VDD is connected with the power supply positive terminal of the power supply, the power supply positive terminal VDD is connected with the power supply, the ground terminal VDD is connected with the ground terminal of the power supply, the ground terminal of the switch 303, the power supply is connected with the ground terminal of the power supply, the power supply is connected with the ground terminal of the power supply, the ground terminal of.

In the embodiment shown in fig. 3, the first vibration switch 306 and the second vibration switch 307 may be replaced by a vibration switch (not shown) disposed between the movable terminal of the switch 303 and the positive power supply terminal VDD of the control device 301. In some cases, the shock switch may not be provided (see fig. 5).

In the embodiment shown in fig. 3, the lighting control system may further comprise a manual switch 308, as can be seen in fig. 5. The manual switch 308 may be provided between the movable terminal of the switch 303 and the positive power supply terminal VDD (or ground terminal GND) of the control device 301, or in some embodiments between the movable terminal of the switch 303 and the positive power supply terminal VDD (or ground terminal GND) of the control device 301 in series with the vibration switch.

The embodiment shown in fig. 3 can be referred to the description of the foregoing embodiment, and will not be described herein for brevity.

In one application scenario, the lighting control system may be applied to a shoe. The first and second light emitting circuits of the light emission control system are disposed on a shoe (e.g., an upper, a sole, or a lace) and the emitted light is visible to the naked eye. When the second light-emitting circuit comprises a warning lamp, the warning lamp is positioned at the front end or the rear end of the sole and/or the upper. The first conductive terminal and the second conductive terminal can be arranged in a groove formed in one side of the sole, the water absorption part can also be arranged on one side of the sole, and other parts of the light-emitting control system except the detection device can be subjected to waterproof treatment.

The embodiments of the present invention have been described above. However, the present invention is not limited to the above embodiment. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A light-emitting control system is characterized by comprising a control device, a detection device, a switch, a first light-emitting circuit, a second light-emitting circuit and a power supply device; the power supply device supplies power to the light emitting control system, and the detection device is used for detecting the environmental condition;

the control device is connected with the detection device, acquires the environmental condition detected by the detection device, controls the change-over switch to be switched between the first light-emitting circuit and the second light-emitting circuit based on the detected environmental condition, and switches the change-over switch to the first light-emitting circuit to emit light; the switch is switched to the second light-emitting circuit, and the second light-emitting circuit emits light;

the detection device comprises a current sensor and a rainwater conduction circuit, wherein the current sensor is connected with the rainwater conduction circuit to detect whether current flows through the rainwater conduction circuit.

2. The lighting control system of claim 1, wherein the first lighting circuit comprises an L ED lamp or a plurality of L ED lamp connected in common cathode or anode, the L ED lamp or the plurality of L ED lamp emits light under the control of the control device, and the second lighting circuit comprises a warning lamp which emits light under the control of the control device.

3. The lighting control system of claim 1, wherein the rain conducting circuit comprises a protection resistor, a power supply battery and a pair of conductive terminals exposed in the environment, the pair of conductive terminals comprises a first conductive terminal and a second conductive terminal, the current sensor, the protection resistor and the power supply battery are connected in series between one end of the first conductive terminal and one end of the second conductive terminal, and a gap is left between the other end of the first conductive terminal and the other end of the second conductive terminal.

4. The lighting control system of claim 1, wherein the rain conduction circuit comprises a pair of conductive terminals exposed to the environment, the pair of conductive terminals including a first conductive terminal and a second conductive terminal, the current sensor is connected in series between one end of the first conductive terminal and one end of the second conductive terminal, and a gap is left between the other end of the first conductive terminal and the other end of the second conductive terminal.

5. The lighting control system of claim 1, wherein the detecting means comprises a humidity sensor for detecting ambient humidity, the humidity sensor being connected to the control means, the control means controlling the switch to switch between the first lighting circuit and the second lighting circuit based on the detected ambient humidity.

6. The lighting control system according to claim 5, wherein the detection means comprises a water absorbing member, and the humidity sensor detects a water content or humidity of the water absorbing member.

7. The lighting control system according to claim 1, further comprising a light sensor for detecting the intensity of the ambient light, wherein the light sensor is connected to the control device, and the control device adjusts the lighting mode of the first lighting circuit and/or the second lighting circuit according to the detected intensity of the ambient light.

8. The lighting control system according to claim 1, wherein a manual switch is connected in series between the control device and the changeover switch, the manual switch being in a closed state or in an open state, and the control device controls the changeover switch to be effective in an operation of switching between the first lighting circuit and the second lighting circuit based on the detected environmental condition.

9. The lighting control system of claim 1, wherein the first lighting circuit comprises a first vibration switch and an L ED string of light beads, and the second lighting circuit comprises a second vibration switch and a warning light;

the control device is provided with a power supply positive terminal, a grounding terminal, an input/output port and a plurality of signal terminals;

the detection device is connected with the control device through an input/output port, the movable end of the change-over switch is connected with the positive end of the power supply of the control device, the first immovable end of the change-over switch is connected with the positive electrode of the L ED lamp string through the first vibration switch, the negative electrode of the L ED lamp string is connected with a plurality of signal ends of the control device, the second immovable end of the change-over switch is connected with one end of the warning lamp through the second vibration switch, and the other end of the warning lamp is grounded;

or the positive end of the power supply is connected with the positive electrode of the power supply, the negative electrode of the power supply is grounded with the grounding end of the control device, the detection device is connected with the control device through the input/output port, the moving end of the change-over switch is connected with the grounding end of the control device, the first fixed end of the change-over switch is connected with the negative electrode of the L ED lamp bead string through the first vibration switch, the positive electrode of the L ED lamp bead string is connected with a plurality of signal ends of the control device, the second fixed end of the change-over switch is connected with one end of the warning lamp through the second vibration switch, and the other end of the warning lamp is connected with the positive electrode of the power.

10. A light-emitting shoe, characterized in that it comprises a light-emission control system as claimed in any one of claims 1 to 9.

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