KR101079490B1 - Led under water nozzle assembly - Google Patents

Abstract

The present invention is connected to the pump nozzle body having a nozzle for supplying water to be sprayed at high pressure and the LED underwater nozzle configured by combining a plurality of LEDs arranged in a radial arrangement for emitting light to the nozzle body To;

After installing a power generation device capable of generating power by using high pressure water supplied from the pump to the nozzle, the electricity generated by the power supply device is supplied to the light composed of the pump and the LED, and then the power is required for initial operation. Its self-operation allows the landscape to be beautiful while saving electrical energy.

LED underwater nozzle, self-power generation

Description

LED underwater nozzle with self-generation function {LED UNDER WATER NOZZLE ASSEMBLY}

The present invention relates to an LED underwater nozzle having a self-generating function, and more particularly, an LED having a self-generating function to produce a power source for operation through a power generation function by improving an underwater nozzle that illuminates while spraying water. The provision of an underwater nozzle.

Generally, fountains are installed for aesthetics in parks, rivers, reservoirs, etc. to spray water to provide cool and refreshing scenery as well as to provide excellent scenery, and various shapes, shapes, and heights by varying the pressure of sprayed water and the shape of nozzles. To spray water to have.

By improving the general fountain, lighting is installed around the fountain to spray water to provide visual beauty at daytime as well as at night, or in the direction of the fountain. It is a situation that is installed and used a lot to increase the beauty by spraying the water sprayed in various colors at night.

Looking at the configuration of the LED underwater nozzle to which the prior art as described above is applied as shown in FIG.

The LED underwater nozzle (1) has a nozzle body (3) having a nozzle (2) to be sprayed at a high pressure by receiving water to be sprayed in connection with a pump or the like, the outside of the nozzle body (3) to the light inside It combines a plurality of LED (4, 5) for emitting light body 6 in a radial arrangement.

The transparent body 7 is formed on the upper part of the lighting body 6 by closing the cap 9 with an airtight material 8 interposed therebetween.

It is obvious that the LED underwater nozzle to which the prior art as described above is applied is able to obtain a visual effect by spraying water through the nozzle and simultaneously illuminating the LED to emit light together. will be.

However, there is a disadvantage in that a lot of power is consumed because a power supply for operating a high-pressure pump and lighting an LED light is consumed, and in view of the difficult economic conditions with the recent surge in oil prices and the rise of various raw material prices. There is a problem in that a lot of energy sources are consumed for the sake and scenery.

In order to reduce the waste of electric energy under such difficult economic conditions, the trend of reducing the operating time of LED underwater nozzles has been gradually reduced. The landscape and aesthetics are gradually disappearing.

In particular, when the LED underwater nozzle installed in the artificial lake formed in the river, lake or park in the city for a long time without operation does not work, it causes the landscape to be rather harmed.

In addition, when the LED underwater nozzle installed at a high cost and time to prevent the use without saving in order to save the electric energy, there are various problems such as wasting the cost of the installation as it is.

Accordingly, the present invention is invented to solve the above problems, the nozzle body having a nozzle connected to the pump and sprayed at a high pressure by receiving water to be sprayed, and a plurality of LEDs for emitting light to the nozzle body radially In the LED underwater nozzle is configured by combining the lights arranged as;

After installing a power generation device capable of generating power by using high pressure water supplied from the pump to the nozzle, the electricity generated by the power supply device is supplied to the light composed of the pump and the LED, and then the power is required for initial operation. By enabling self-operation, it is possible to achieve the purpose of scenic beauty while saving electric energy.

The present invention provides the LED underwater nozzle with a self-generation function to operate by applying a general power during the initial operation, the underwater nozzle is installed by performing the operation of the pump and the LED lights through the self-generation after the underwater nozzle is installed It is an invention having various effects, such as saving a lot of energy sources while improving the surrounding landscape without having to leave it.

Hereinafter, with reference to the accompanying drawings will be described a preferred configuration and operation of the present invention for achieving the above object.

1 is a conceptual diagram showing an LED underwater nozzle having a self-power generation function to which the technique of the present invention is applied, Figure 2 is a schematic diagram showing an example of the LED underwater nozzle having a self-power generation function to which the technique of the present invention is applied do.

Conventional LED underwater nozzle (100) is provided with a nozzle body (103) having a nozzle (102) connected to the pump 101 is supplied with water to be sprayed and sprayed at a high pressure, the nozzle body (103) It consists of combining a plurality of LEDs 104, 105 for emitting light 106 arranged radially.

In the present invention, by using the high pressure water supplied from the pump 101 to the nozzle 102 is installed a power generator 110 that can perform power generation, and pumps the electricity produced by the power generator 110 ( It is characterized in that the self-operation is possible after supplying power to the lighting 106 consisting of the 101 and the LEDs (104, 105) for initial operation.

The generator 110 is installed in the tubular body 111 for supplying water from the pump 101 to the nozzle 102 to obtain a rotational force to obtain a rotational force of the turbine 112 After increasing the speed through the transmission 113 receives the rotational power to rotate the conventional generator 114 to perform power generation.

Power transmission to the turbine 112 and the transmission 113 will be able to combine a variety of gears, such as worm gears, helical gears, to be transmitted to the transmission 113 to obtain a sufficient power generation speed to obtain a high ratio of rotation. Good to do.

The generator 110 has an automatic level unit 115 to supply the electricity produced by the generator 114 to the next step only when the level is above the usable level.

And a rectifier 118 having a DC converter 116 and an AC converter 117 for converting the electricity applied through the automatic level unit 115 into a DC power source 24V and an AC power source 220V. The pump 101 and the lighting 106 can be supplied to convert the power used.

The DC power applied through the rectifier 118 is to be charged to the storage battery 120 through the charge and discharge controller 119, and then supplied to the power to turn on the LED (104, 105).

The AC power applied through the rectifier 118 is applied to the pump 101 through the switch 121, and when the electricity produced is insufficient, the general power (electric power) is applied to operate the pump 101. Configure it to be.

Since the technical configurations of the turbine 112, the transmission 113, and the generator 114 described in the technology of the present invention are already known and used in various ways, descriptions of specific technical contents will be omitted.

Looking at the state of use of the LED underwater nozzle (100) having a self-generation function is applied as described above as follows.

In the initial operation of the LED underwater nozzle 100, a general power supply (KEPCO) is applied to operate the pump 101 to inject water at a high pressure through the nozzle 102, and is also supplied to the lighting 106 to the LED (104,105) lights up to emit light.

When the high pressure water is supplied through the tube body 111 by the operation of the pump 101 in this way, the turbine 112 installed in the tube body 111 rotates, and the rotation force is transmitted to the transmission 113 to receive the high speed. After the conversion by rotating the generator 114 it is possible to produce electricity through power generation.

As described above, the electricity produced by the rotation of the turbine 112 is applied to the rectifier 118 only when the level available by the automatic level unit 115 is maintained, and the electricity applied to the rectifier 118 is DC and AC. The converters 116 and 117 are converted into DC and AC power and applied.

Then, the DC power is stored in the storage battery 120 through the charge and discharge controller 119 and is supplied to the lighting 106 to light the LEDs 104 and 105, AC power is applied to the switch 121 When enough power is applied to drive the pump 101, the general power source is cut off to operate the pump 101 by using the generated electricity.

Of course, if the electricity produced by the self-power generation is not enough to operate the pump 101, it will be natural that there is no problem in operating the pump 101 by switching to the general power (electric power) by the switch 121. .

In the present invention, by applying only the initial power required for the operation of the pump to perform a self-generation using a turbine that generates a rotational force by the water sprayed at a high pressure by applying the power required for the pump and lighting operation waste of electrical energy LED underwater nozzle to reduce the landscape while reducing the advantage to achieve the original purpose is sufficient.

1 is a conceptual view showing an LED underwater nozzle having a self-power generation function to which the technique of the present invention is applied.

Figure 2 is a configuration diagram of one example showing the LED underwater nozzle having a self-generation function to which the technique of the present invention is applied.

Figure 3 is a block diagram showing a general LED underwater nozzle to which the prior art is applied.

* Description of the symbols used in the main parts of the drawings *

100; LED underwater nozzle

106; light

110; Generator

114; generator

115; Auto level unit

118; rectifier

121; Changer

Claims (2)

A nozzle body 103 connected to the pump 101 and having a nozzle 102 supplied with sprayed water to spray at a high pressure; A combination of illuminations (106) arranged radially with a plurality of LEDs (104,105) for emitting light to said nozzle body (103); A turbine 112 installed in the pipe body 111 for supplying water from the pump 101 to the nozzle 102 to obtain rotational force; A transmission (113) for receiving and increasing the rotational force of the turbine (112); Installing a power generation device (110) consisting of a generator (114) for generating power by receiving rotational force of the transmission (113); LED underwater having a self-generation function to supply the electricity produced in the power generator 110 to the lighting 106 consisting of the pump 101 and the LEDs 104, 105 to enable self-operation after the power is required for initial operation In a nozzle; An automatic level unit 115 for supplying the electricity produced by the generator 114 to the next level only when it is above a usable level; A rectifier 118 having a DC converter 116 and an AC converter 117 for converting electricity applied through the automatic level unit 115 into a DC power source and an AC power source; A charge / discharge controller 119 for supplying power to the LEDs 104 and 105 after charging the DC power applied through the rectifier 118 to the storage battery 120; When the AC power applied through the rectifier 118 to the pump 101 is insufficient when the electricity produced by the general power is further applied to switch the tool 121 to be able to operate the pump 101 LED underwater nozzle having a self-generation function characterized in that. delete

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