CN107178754B

CN107178754B - Light emitting control method of solar floating lamp and solar floating lamp

Info

Publication number: CN107178754B
Application number: CN201710293392.9A
Authority: CN
Inventors: 黄志雄; 张文孝; 许耀元
Original assignee: Intex Industries Xiamen Co Ltd
Current assignee: Intex Industries Xiamen Co Ltd
Priority date: 2017-04-28
Filing date: 2017-04-28
Publication date: 2023-03-28
Anticipated expiration: 2037-04-28
Also published as: CN107178754A

Abstract

The invention provides a light emitting control method of a solar floating lamp, which comprises the following steps: 1) Step 2 is entered if the switch is pressed 1 time; pressing for 2 times, and then entering step 4; pressing for 3 times, and then entering the step 5; 2) The floating lamp is continuously turned on for time T1; 3) Detecting whether the voltage of the storage battery is lower than a preset value, if so, turning off the floating lamp; if not, further judging whether the voltage of the solar panel is higher than a preset value, if so, charging the storage battery by the solar panel; if not, the floating lamp continues to be continuously lightened for a time T1, and then the step 3 is repeatedly executed; 4) Turning off the power supply of the battery to the floating lamp, and turning off the floating lamp; 5) Driving the floating lamp to be turned on for a time T2 by a storage battery arranged in the floating lamp, and entering a step 6 after a vibration switch arranged in the floating lamp is in an activated state; 6) Detecting whether the vibration frequency of the vibration switch reaches a preset value or not, and if so, changing the light emitting mode of the floating lamp; if not, the floating lamp keeps the current light-emitting mode.

Description

Light emitting control method of solar floating lamp and solar floating lamp

Technical Field

The invention relates to a light emitting device, in particular to a floating lamp.

Background

With the increasing standard of living, SPA pools, above ground pools, underground pools, ponds and fish ponds are increasingly present in homes and many commercial locations. In order to meet the need for lighting at night and create elegant, elegant and fantastic environmental atmospheres, SPA pools, above ground pools, underground pools, ponds and fish ponds are optionally fitted with floating lights for surface or underwater lighting.

However, in the prior art, the pool lamp usually adopts the illuminating lamp to directly irradiate the pool and the water body, the light is monotonous and lacks of change, the decorative function is very limited, and a satisfactory light effect cannot be presented.

Disclosure of Invention

The invention aims to provide a light emitting control method of a floating lamp, which can switch various light emitting modes through manual control of a user and automatically charge a built-in battery through a solar panel when the electric quantity of the built-in battery is low.

In order to solve the technical problem, the invention provides a light emitting control method of a solar floating lamp, which comprises the following steps:

1) Detecting the number of times that a switch of the floating lamp is pressed, and entering a step 2 if the switch is pressed for 1 time; pressing for 2 times, and then entering the step 4; pressing for 3 times, and then entering the step 5;

2) Driving the floating lamp to continuously light for T1 by a storage battery arranged in the floating lamp, and then entering step 3;

3) Detecting whether the voltage of the storage battery is lower than a preset value, if so, turning off the floating lamp; if not, further judging whether the voltage of the solar panel is higher than a preset value, if so, charging the storage battery by the solar panel, and turning off the floating lamp; if not, the floating lamp continues to be continuously lightened for time T1, and then the step 3 is repeatedly executed;

4) Turning off the power supply of the battery to the floating lamp, and turning off the floating lamp;

5) Driving the floating lamp to be turned on for a time T2 by a storage battery arranged in the floating lamp, and entering a step 6 after a vibration switch arranged in the floating lamp is in an activated state;

6) Detecting whether the voltage of the storage battery is lower than a preset value or not, and if so, turning off the floating lamp; if not, further judging whether the voltage of the solar panel is higher than a preset value, if so, charging the storage battery by the solar panel, and turning off the floating lamp; if not, the floating lamp is continuously lightened, and meanwhile, whether the vibration frequency of the vibration switch reaches a preset value or not is detected, and if so, the floating lamp changes a light emitting mode; if not, the floating lamp keeps the current light outlet mode.

In a preferred embodiment: in

steps

2 and 3, the floating lamp emits white light.

In a preferred embodiment: in step 6, the floating lamp changes the light emitting mode from white light emitting to color light emitting, or from color light emitting to white light emitting, or from color light of one color to color light of another color.

In a preferred embodiment: in step 6, when the vibration frequency of the vibration switch reaches a preset value, the floating lamp keeps the current light emitting mode for a time T3, and then the light emitting mode is changed.

The invention also provides a solar floating lamp applying the light-emitting control method, which comprises the following steps: the LED lamp comprises an upper cover, a lampshade, a solar panel, a storage battery, a switch assembly, a vibration switch, an LED light source and a driving circuit; the storage battery supplies power to the driving circuit, and the driving circuit drives the LED light source to light; the solar panel charges the storage battery;

the lampshade is a container with an opening end, and the upper cover covers the opening end and is connected with the lampshade in a sealing way; the surface of the upper cover is provided with a groove for mounting the solar panel and a through hole for placing the switch component; the switch assembly is electrically connected with a driving circuit arranged in the lampshade through the through hole;

the vibration switch is arranged in the lampshade and electrically connected with the driving circuit, and when the floating lamp is impacted by water waves, the vibration switch vibrates therewith.

In a preferred embodiment: the upper cover is connected with the lampshade through threads, and a circle of locking sleeve is sleeved on the periphery of the joint of the upper cover and the lampshade.

In a preferred embodiment: the threaded connection part of the upper cover and the lampshade is also provided with a circle of sealing gasket.

In a preferred embodiment: the storage battery is a lithium battery.

In a preferred embodiment: the switch assembly comprises a key, a switch and a pressing sheet; the key is exposed on the upper surface of the through hole, and when the key is pressed, the key drives the switch to be linked, so that the key extrudes the pressing sheet to form a trigger signal for closing the switch to the driving circuit.

In a preferred embodiment: the lampshade conducts diffuse reflection on the light emitted by the LED light source and then transmits the light outwards.

Compared with the prior art, the technical scheme of the invention has the following beneficial effects:

according to the solar floating lamp provided by the invention, a user presses the switch and enters different light emitting modes according to different pressing times, so that the light emitting effect of the floating lamp is various and is easy to adjust. In addition, use solar panel to charge to the battery, can guarantee that the battery in time obtains charging in the time of low electric quantity to make the floating lamp can use for a long time.

Drawings

FIG. 1 is a perspective view of a floating lamp in accordance with a preferred embodiment of the present invention;

FIG. 2 is an exploded view of the floating lamp structure in the preferred embodiment of the present invention;

FIG. 3 is a structural sectional view of an upper cover in the preferred embodiment of the present invention;

FIG. 4 is a sectional view of the structure of the lamp housing in the preferred embodiment of the invention;

fig. 5 is a flow chart of the control of the light output of the floating lamp in the preferred embodiment of the present invention.

Detailed Description

The invention is further described with reference to the following figures and detailed description.

Referring to fig. 1-4, a solar floating lamp includes: the LED lamp comprises an upper cover 1, a lampshade 2, a solar panel 3, a storage battery 4, a switch component 5, a vibration switch 6, an LED light source 7 and a driving circuit 8; the storage battery 4 is a lithium battery.

The storage battery supplies power to the driving circuit 8 4, the driving circuit 8 drives the LED light source 7 to be lightened, and the lampshade 2 conducts diffuse reflection on light rays emitted by the LED light source 7 and then transmits the light rays outwards.

The solar panel 3 charges the storage battery 4; thus, the solar panel 3 can be ensured to automatically charge the storage battery 4, so that the floating lamp can be in a working state for a long time.

The lampshade 2 is a container with an open end, and the upper cover 1 covers the open end and is connected with the lampshade 2 in a sealing way; the surface of the upper cover 1 is provided with a groove 11 for mounting the solar panel 3 and a through hole 12 for placing the switch component 5; the switch component 5 is electrically connected with a driving circuit 8 arranged in the lampshade 2 through the through hole 12; by operating the switch assembly 5, a user can form an input signal to the driving circuit 8, so that the driving circuit 8 drives the LED light source 7 to form different light emitting effects according to different input signals.

Because the floating lamp is used on water and the inside works in a charged mode, if water leakage occurs, the water in the whole pool is charged, and the floating lamp is very dangerous. Therefore, the floating lamp must have good sealing and waterproof properties. In order to solve the problem, the upper cover 1 is connected with the lampshade 2 through threads, and a circle of locking sleeve 13 is sleeved on the periphery of the joint of the upper cover 1 and the lampshade 2. Therefore, the gap at the periphery of the threaded connection part is sealed, and a good sealing effect is achieved.

In order to further increase the sealing performance, the open end of the lampshade 2 extends outwards horizontally to form a circle of skirt. The upper surface of shirt rim sets up round recess, and a sealed pad 21 sets up in this recess, and when upper cover 1 and lamp shade 2 threaded connection, it is sealed to support through this sealed pad 21 between upper cover and the lamp shade, has further increased sealed effect.

The vibration switch 6 is arranged in the lampshade 2 and is electrically connected with the driving circuit 8, and when the floating lamp is impacted by water waves, the vibration switch 6 vibrates therewith.

The switch assembly 5 comprises a key 51, a switch 52 and a pressing sheet 53; the key 51 is exposed on the upper surface of the through hole 11, and when the key 51 is pressed, the key 51 drives the switch 52 to be linked, so that the pressing sheet 53 is extruded, and a trigger signal for switching on and off is formed to the driving circuit 8.

With further reference to fig. 5, the light-emitting control method of the solar floating lamp includes the following steps:

1) Detecting the number of times that the switch component 5 of the floating lamp is pressed, and entering the step 2 if the switch component is pressed for 1 time; pressing for 2 times, and then entering the step 4; pressing for 3 times, and then entering the step 5;

2) Driving the floating lamp to continuously light for time T1 by a storage battery 4 arranged in the floating lamp, and then entering step 3; the lighting time T1 and the lighting color of the floating lamp can be set according to needs, the lighting color of the floating lamp is white in the embodiment, and the duration time is 10s.

3) Detecting whether the voltage of the storage battery 4 is lower than a preset value, if so, turning off the floating lamp; if not, further judging whether the voltage of the solar panel 3 is higher than a preset value, if so, charging the storage battery 4 by the solar panel 3, and turning off the floating lamp; if the voltage is less than 0.5V, the floating lamp continues to be continuously lightened for T1, and then the step 3 is repeatedly executed; in this embodiment, the preset voltage of the battery 4 is 3V.

5) Driving the floating lamp to be on for a time T2 by a storage battery arranged in the floating lamp, and entering a step 6 after a vibration switch 6 arranged in the floating lamp is in an activated state; in this embodiment, the lighting color of the floating lamp is colored, and the duration time is 10s.

6) Detecting whether the voltage of the storage battery 4 is lower than 3V, if so, turning off the floating lamp; if not, further judging whether the voltage of the solar panel 3 is higher than a preset value, if so, charging the storage battery 4 by the solar panel 3, and turning off the floating lamp; if the voltage is less than 0.5V, the floating lamp is continuously lightened, and whether the vibration frequency of the vibration switch 6 reaches 5 times is detected. If yes, the floating lamp changes the light emitting mode; if not, the floating lamp keeps the current light outlet mode. The floating lamp changes the light emitting mode, namely the floating lamp changes from emitting white light to emitting color light, or changes from emitting color light to emitting white light, or changes from color light of one color to color light of another color.

In step 6, when the vibration switch 6 vibrates for 5 times, the floating lamp maintains the current light emitting mode for time T3, and then changes the light emitting mode. T3 is 30s.

Various parameter designs in this embodiment are only designed to better illustrate the working process of this embodiment, and do not limit the protection scope of the present invention, and those skilled in the art may arbitrarily increase or decrease the parameters according to actual needs, which belongs to a simple replacement of the above embodiment and will not be described again.

The invention is not limited to the foregoing embodiments. The above examples should not be construed as limiting the scope of the invention. Modifications and alterations will occur to others upon reading and understanding the preceding detailed description. The specific protection scope shall be subject to the claims.

Claims

1. A light emitting control method of a solar floating lamp is characterized by comprising the following steps:

2) Driving the floating lamp to continuously light for time T1 by a storage battery arranged in the floating lamp, and then entering the step 3;

3) Detecting whether the voltage of the storage battery is lower than a preset value or not, and if so, turning off the floating lamp; if not, further judging whether the voltage of the solar panel is higher than a preset value, if so, charging the storage battery by the solar panel, and turning off the floating lamp; if not, the floating lamp continues to be continuously lightened for a time T1, and then the step 3 is repeatedly executed;

4) The power supply of the battery to the floating lamp is turned off, and the floating lamp is turned off;

2. The light-emitting control method of the solar floating lamp according to claim 1, characterized in that: in steps 2 and 3, the floating lamp emits white light.

3. The light-emitting control method of the solar floating lamp according to claim 1, characterized in that: in step 6, the floating lamp changes the light emitting mode from white light emitting to color light emitting, or from color light emitting to white light emitting, or from color light of one color to color light of another color.

4. The light-emitting control method of the solar floating lamp according to claim 1, characterized in that: in step 6, when the vibration frequency of the vibration switch reaches a preset value, the floating lamp keeps the current light emitting mode for a time T3, and then the light emitting mode is changed.

5. A solar floating lamp applying the light control method of any one of claims 1 to 4, characterized by comprising: the LED lamp comprises an upper cover, a lampshade, a solar panel, a storage battery, a switch assembly, a vibration switch, an LED light source and a driving circuit; the storage battery supplies power to the driving circuit, and the driving circuit drives the LED light source to light; the solar panel charges the storage battery;

the vibration switch is arranged in the lampshade and is electrically connected with the driving circuit, and when the floating lamp is impacted by water waves, the vibration switch vibrates along with the water waves.

6. The solar floating lamp according to claim 5, wherein: the upper cover is connected with the lampshade through threads, and a circle of locking sleeve is sleeved on the periphery of the joint of the upper cover and the lampshade.

7. The solar floating lamp according to claim 6, wherein: the upper cover and the lampshade are further provided with a circle of sealing gasket at the threaded connection part.

8. The solar floating lamp according to claim 7, wherein: the storage battery is a lithium battery.

9. The solar floating lamp according to claim 5, wherein: the switch assembly comprises a key, a switch and a pressing sheet; the key is exposed on the upper surface of the through hole, and when the key is pressed, the key drives the switch to be linked, so that the key extrudes the pressing sheet to form a trigger signal for closing the switch to the driving circuit.

10. The solar floating lamp according to claim 5, wherein: the lampshade conducts diffuse reflection on the light emitted by the LED light source and then transmits the light outwards.