The present invention relates to the art of photo-electrical technics, and more particularly, to a micro-current LED light source or a module of the same, especially to an inner red-dot gun sighting device powered by solar cell and provided with micro-current led light source.
Most of the existing inner red-dot sighting devices use cells, such as lithium to provide power needed by the inner red-dot module (using LED as the light source) when working. The cells have limited lifetimes and should be replaced, increasing the cost. Further, during using, since the light in the outside environment changes, the current or voltage supplied by the cell should be adjusted, so as to achieve adjusting the luminance of the light emitted from the inner red-dot module. For example, when the environment luminance increases, the luminance of the light emitted from the inner red-dot module should be increased. Conversely, the luminance of the light emitted from the inner red-dot module should be decreased. Such inner red-dot sighting device relies on the power supplied by the cell day and night, increasing replacement cost for the cells. Besides the above-mentioned inner red-dot sighting device, most of the current lighting devices or auxiliary sighting devices use LED as the light source, and most of them are powered by cells which should be replaced frequently, increasing the using cost.
An object of the present invention is to provide an inner red-dot gun sighting device powered by solar cell and provided with micro-current led light source, which can decrease the using of a cell by means of the LED light source powered by the solar cell, so as to decrease the using cost.
To obtain the above-mentioned object, the present invention provides an inner red-dot gun sighting device powered by a solar cell and provided with a micro-current LED light source, comprising a housing, a micro-current LED light source provided in the housing or on the housing, a cell storage provided on the housing for seating a cell, a luminance adjusting switch, and a controlling circuit board provided in the housing; the cell storage, the luminance adjusting switch, the controlling circuit board and the micro-current LED light source constituting a series connection circuit. The sighting device is characterized in: a solar cell is provided on the housing; the solar cell supplies power for the micro-current LED light source by connecting with the micro-current LED light source through a conducting wire; the sighting device further comprises a dual-power supply automatic switching module provided in the housing, for conducting an electrical connection between the solar cell and the micro-current LED light source when the luminance adjusting switch is in a turn-off state, such that the solar cell supplies power for the micro-current LED light source; or conducting the series connection circuit constituted by the cell, the luminance adjusting switch, the controlling circuit board and the inner micro-current LED light source when the solar cell cannot provide sufficient voltage or current, achieving a power supply for the micro-current LED light source by the cell, and a luminance control for the output light from the micro-current LED light source by the luminance adjusting switch.
A trigger switch is further provided on the above-mentioned housing; after receiving a input signal from the trigger switch, the dual-power supply automatic switching module breaks the electrical connection between the solar cell and the micro-current LED light source as well as conducts the series connection circuit constituted by the cell, the luminance adjusting switch, the controlling circuit board and the micro-current LED light source synchronously; the trigger switch is in series connection between the cell and the dual-power supply automatic switching module.
The above-mentioned luminance adjusting switch is a buttoned switch comprising “+” and “−” buttons; on the controlling circuit board there is comprised a processing chip MCU and a stage controlling circuit;
The solar cell is connected to the micro-current LED light source in series via the processing chip MCU; the cell is connected to the micro-current LED light source in series via the processing chip MCU and the stage controlling circuit; the “+” and “−” buttons are connected with the processing chip MCU, respectively;
The processing chip MCU breaks the electrical connection between the solar cell and the micro-current LED light source according to a preliminary input signal from any one of the “+” and “−” buttons, and controls the stage controlling circuit according to a secondary or repeated input signal from any one of the “+” and “−” buttons, so as to achieve an adjustment to the a voltage or current supplied for the micro-current LED light source, changing the luminance of the light emitted from the micro-current LED light source; and breaks the electrical connection between the cell and the stage controlling circuit as well as recovers the electrical connection between the solar cell and the micro-current LED light source synchronously according to the signals inputted simultaneously from the “+” and buttons or no signals inputted in a period of time.
The above-mentioned inner red-dot gun sighting device powered by a solar cell and provided with a micro-current LED light source, further comprises an arched lens support on a front end of the housing for mounting a lens, and a controlling circuit board in the housing; the cell storage, the luminance adjusting switch, the controlling circuit board and the micro-current LED light source constituted a series connection circuit; the micro-current LED light source is mounted at a rear end of the housing; the cell storage is imbed-mounted at a top surface of the housing, and disposed between the cell storage and the micro-current LED light source; the “+” and “−” buttons are provided at rear ends of a left surface and a right surface of the housing, respectively.
The above-mentioned micro-current LED light source is mounted on a slide which is disposed in a rear end of the housing and is laterally movable in a left and right direction along the housing; the slide has a “” shaped cross-section; on a top portion of its front end surface there is provided with a micro-current LED light source seating groove, and the top portion is provided with a limiting sliding groove cooperating with a limiting slide extending downwards from an inner surface of the top surface of the housing.
A lower cover located under the slide is provided on the bottom surface of the above-mentioned housing, and four three fixing screw holes and at least one draining hole are provided on the lower cover.
A left trapped rail and a right trapped rail that extend axially are provided on the bottom surface of the housing; a dovetail block (19) is provided on the left trapped rail, and is threadingly coupled with a locking screw penetrated from the right trapped rail; the housing is coupled with a barrel coupling sleeve through the left trapped rail and the right trapped rail; the barrel coupling sleeve is constituted by a supporting tube with an axial duct provided therein, and a case nested thereoutside; the supporting tube comprises a quadrangular prism and a circular end surface provided at a front end of the quadrangular prism; a axially extending limiting beam is provided on each bottom end of a left and a right surfaces of the quadrangular prism; a sliding groove extending axially and protruding downwards beyond the bottom surface is provided at a bottom surface of the quadrangular prism; a fixing trapped rail axially extending backwards from the circular end surface and clamped by the left trapped rail and the right trapped rail is provided at the front end of a top surface of the quadrangular prism; a first screw hole penetrating the axial duct is provided behind the fixing trapped rail; an axially extending hole groove for insertion of the left trapped rail and the right trapped rail is provided at a front end of a top surface of the case; an axially extending elongated groove is at the top surface of the case behind the hole groove; and a second screw hole is provided on the elongated groove; a downward protruding chamber for accommodating the sliding groove is provided at the front end of the bottom surface of the case; the downward protruding chamber is coupled with the sliding groove by a screw.
The above-mentioned axial duct has an inner diameter decreasing gradually from a front end to a rear end of the supporting tube; the rear end of the case has a truncated cone shape which becomes thinner gradually from front to rear.
A horizontal adjusting screw is mounted on the above-mentioned housing on its right surface at a place corresponding to the slide; an adjusting coil spring is mounted between the left surface of the housing and the slide; the adjusting coil spring is nested on the limiting column. an opening stop-collar that snapped and nested on the horizontal adjusting screw is provided in the housing, so as to prevent the horizontal adjusting screw from rotating due to the squeezing of the adjusting coil spring.
In a rear end surface of the above-mentioned housing there are provided a boost pin that presses against a rear end surface of the slide, a boost coil spring nested on the boost pin, and a fixing screw threadingly coupled with the housing and presses against a rear end of the boost coil spring; the boost coil spring and fixing screw can achieve a front-rear limiting for the slide by means of the boost pin. An up and down adjusting screw is provided perpendicularly at a rear end of the housing, which is threadingly coupled with the adjusting disc provided in the rear end of the housing and imbed-coupled with the rear end surface of the slide.
The above-mentioned solar cell is imbed-mounted at a top surface of the housing, and a protection glass is provided at a top surface of the solar cell. The solar cell is any one of a monocrystalline silicon, a polycrystalline silicon, a silicon photodiode or a low-light amorphous silicon solar cell. The luminance adjusting switch is a buttoned switch comprising “+” and “−” buttons, and are provided at both sides of the front end of the housing, respectively.
The advantages of the present invention lie in: by using the solar cell to supply power for the micro-current LED light source, it is possible for the inner red-dot gun sighting device itself to automatically adjust the luminance of the output light from the micro-current LED light source as the environment luminance changes, without relying on any controlling circuit. The normal working power of the sighting device can be ensured in the case of no cell, which can reduce the use to the cell, prolong the lifetime of the cell, and decrease the using cost. Taking the cell power system of the inner red-dot sighting device or other LED light source themselves, the normal use of the inner red-dot sighting device or other LED light source during at night can be ensured.
Hereinafter, further description will be made in combination with the drawings and embodiment, which is not intend to limit the scope of the present invention.
1, housing; 2, solar cell; 3, trigger switch; 4, 5, “+”, “−” button; 6, micro-current LED light source; 7, cell storage; 8, trapped rail; 9, lens; 10, arched lens support; 11, luminance adjusting switch; 12, slide; 13, micro-current LED light source seating groove; 14, limiting slide; 15, limiting slide groove; 16, lower cover; 17, fixing screw hole; 18, draining hole; 19, dovetail block; 20, locking screw; 21, supporting tube; 22, case; 23, quadrangular prism; 24, circular end surface; 25, 26, limiting beam; 27, sliding groove; 28, fixing trapped rail; 29, first screw hole; 30, hole groove; 31, elongated groove; 32, second screw hole; 33, downward protruding chamber; 34, horizontal adjusting screw; 35, adjusting coil spring; 36, limiting column; 37, opening stop-collar; 38, boost pin; 39, boost coil spring; 40, fixing screw; 41, up and down adjusting screw; 42, adjusting disc; 43, axial duct; 44, protruding collar; 45, circuit board; 46, protection glass; 47, cell cover; 48, cell; 49, cell washer; 50, front cover; 51, LED protection glass; 52, screw.
Embodiment 1, an inner red-dot sighting device powered by a solar cell, wherein an inner red-dot module without a luminance adjusting switch is mounted on a LED mounting support inside a housing: as shown by
By adding the solar cell and the dual-power supply automatic switching module (switch), power supply for the inner red-dot module (using the micro-current LED as the light source) can be achieved by the solar cell in a sunny (daytime) environment, and the working power of the sighting device can be ensured without the cell. The cell is unnecessarily to be installed at the same time. The only requirement is to switch to the cell power supply by the dual-power supply automatic switching module when there is not enough sunshine or no sunshine (nighttime).
When it is getting dark, by a trigger switch 3 provided on the housing 1 as shown by
The solar cell 2 provided in the present embodiment is shown in
In this way, when the solar-powered inner red-dot sighting device according to the present embodiment is used in the daytime or sunny environment, in the premise of no input signal from the trigger switch 3, the dual-power supply automatic switching module conducts the electrical connection between the solar cell 2 and the inner red-dot module (using the micro-current LED as the light source), such that inner red-dot module (using the micro-current LED as the light source) is powered by the solar cell 2, and the luminance of the light emitted from the micro-current LED light source will adaptively changes according to the power generated by the solar cell 2. For example, when the environment luminance increases, the luminance of the light emitted from the inner red-dot module (using the micro-current LED as the light source) will increase. In the contrary, when the environment luminance becomes dark and weak, and the solar cell 2 cannot provide sufficient voltage or current, the dual-power supply automatic switching module will break the connection between the solar cell 2 and the inner red-dot module (using the micro-current LED as the light source), and switch to the cell power supply. Of course, in the premise that when the solar cell provides a relatively small voltage or current, but not so small to cause the switch of the dual-power supply automatic switching module, and at this time the output laser from micro-current LED light source is dark, a input signal may be manually give to the dual-power supply automatic switching module by the trigger switch 3, to break the connection between the solar cell 2 and the inner red-dot module (using the micro-current LED as the light source), and conduct the connection circuit for the cell and the inner red-dot module (using the micro-current LED as the light source). The solar cell 2 mentioned in the present embodiment may be any one of a monocrystalline silicon, a polycrystalline silicon, a silicon photodiode or a low-light amorphous silicon solar cell.
Embodiment 2: When a cell storage is provided at the bottom of the inner red-dot sighting device as shown by
Further, an electronic circuit diagram of the solar powered inner red-dot sighting device according to the present embodiment is shown in
Of course, as can be seen from
When the solar powered inner red-dot sighting device according to the present embodiment is used at night, if any one of the “+” and “−” buttons 4, 5 is pressed, an input signal will be given to the processing chip MCU, and the electrical connection between the solar cell 2 and the inner red-dot sighting device can be break. At the same time, the power circuit of the stage controlling circuit can be conducted, cell and the inner red-dot module (using the micro-current LED as the light source) will be powered by the cell. When the input signal of any one of the “+” and “−” buttons 4, 5 is inputted again or repeatedly, the value of the voltage or current supplied for the inner red-dot module (using the micro-current LED as the light source) can be adjusted, and luminance of the light output from the inner red-dot module (using the micro-current LED as the light source) can be adjusted to increase or decrease. To recover the solar cell power, it is only required that the input signals of the “+” and “−” buttons 4, 5 are inputted simultaneously, or there is no input signals in a period of time. The processing chip MCU breaks the electrical connection between the cell and the stage controlling circuit as well as recover the electrical connection between the solar cell and the inner red-dot module synchronously (using the micro-current LED as the light source).
In the above embodiments, the solar cell 2 is mounted at a top surface of the housing 1, which is intend to ensure a largest light receiving area for the solar cell 2, and to use its full performance. Of course, according to the actual structure and requirement of the inner red-dot sighting device, the solar cell 2 may also be provided at an end surface of the front end of the housing 1 of the inner red-dot sighting device, as shown in
A solar inner red-dot gun sighting device with a crosshair is shown in
As seen in
To ensure the stability of the adjustment of the lateral and horizontal position for the slide 12, as shown in
Also, as seen in
As shown in
After the case 22 is nested on the supporting tube 21, a screw coupling is adapted by the first screw hole 29 and the second screw hole 32. The solar inner red-dot gun sighting device with the crosshair, after being inserted into the hole groove 30 by the left trapped rail and the right trapped rail provided on the bottom surface of its housing 1, achieves a clamp coupling between the left trapped rail and the right trapped rail and the fixing trapped rail 28 by means of the dovetail block 19 and the locking screw 20, then the supporting tube 21, as well as the entire solar inner red-dot gun sighting device with the crosshair is nested on the gun barrel, and is finally limited by the connection screw passing through the first screw hole 29 and the second screw hole 32, which has a convenient assembling and disassembling. As shown in
The rear end of the case 22 has a truncated cone shape which becomes thinner gradually from front to rear, which can reduce the obstruct of the case 22 to the human sight. Also, as seen in
In view of the above, it can be easily seen that, by using the solar cell 2 to supply power for the micro-current LED light source 6, it is possible for the inner red-dot gun sighting device itself to automatically adjust the luminance of the output light from the micro-current LED light source as the environment luminance changes, without relying on any controlling circuit. That is, the normal working power of the sighting device can be ensured in the case of no cell, which can reduce the use to the cell, prolong the lifetime of the cell, and decrease the using cost. Further, by means of the left trapped rail and the right trapped rail mounted at the bottom of the gun sighting device and the barrel coupling sleeve to be coupled with the barrel, the gun sighting device can be used very conveniently.
Number | Date | Country | Kind |
---|---|---|---|
2014 2 0092959 U | Mar 2014 | CN | national |
2014 1 0071368 | Mar 2014 | CN | national |
2014 2 0124704 U | Mar 2014 | CN | national |
2014 2 0124716 U | Mar 2014 | CN | national |
2014 2 0198235 U | Apr 2014 | CN | national |
2014 2 0198358 U | Apr 2014 | CN | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/CN2014/078360 | 5/25/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2015/131452 | 9/11/2015 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5189555 | Jorlov | Feb 1993 | A |
6519889 | Schlierbach | Feb 2003 | B1 |
8671611 | Ostergren | Mar 2014 | B2 |
8925238 | Anderson | Jan 2015 | B2 |
9163902 | Cheng | Oct 2015 | B1 |
20020191401 | He | Dec 2002 | A1 |
20030012015 | Schiller | Jan 2003 | A1 |
20070214701 | Grauslys et al. | Sep 2007 | A1 |
20070267058 | Naum | Nov 2007 | A1 |
20090288324 | Peterson | Nov 2009 | A1 |
20100083554 | Elpedes | Apr 2010 | A1 |
20110154713 | Jung | Jun 2011 | A1 |
20120042560 | Jackson | Feb 2012 | A1 |
20120055063 | Lindau | Mar 2012 | A1 |
20120151816 | Kleck | Jun 2012 | A1 |
20120327247 | Mironichev | Dec 2012 | A1 |
20130061510 | Ostergren | Mar 2013 | A1 |
20130098344 | Morris, II | Apr 2013 | A1 |
20130112879 | Meyers | May 2013 | A1 |
20130152447 | Ostergren | Jun 2013 | A1 |
20130194435 | Lupher | Aug 2013 | A1 |
20130333266 | Gose | Dec 2013 | A1 |
20140237884 | Koesler | Aug 2014 | A1 |
20160102943 | Teetzel | Apr 2016 | A1 |
20160356573 | Berlips | Dec 2016 | A1 |
20170038177 | Sun | Feb 2017 | A1 |
Number | Date | Country |
---|---|---|
2463779 | Dec 2001 | CN |
2809578 | Aug 2006 | CN |
102032840 | Apr 2014 | CN |
103954173 | Jul 2014 | CN |
0545527 | Jun 1993 | EP |
94018842 | May 1997 | RU |
I258561 | Jul 2006 | TW |
Entry |
---|
International Search Report for PCT/CN2014/078360, dated Nov. 21, 2014. |
Number | Date | Country | |
---|---|---|---|
20170038177 A1 | Feb 2017 | US |