KR20200119696A - Underwater Camera Device - Google Patents

Abstract

A disclosed invention relates to an underwater camera device including: a frame formed in a bar shape, wherein a mounting hole is formed through the frame and a lighting coupling portion is formed at both ends of the frame; an underwater camera detachably coupled to the mounting hole of the frame; and an underwater lighting unit detachably coupled to the lighting coupling portion of the frame. The present invention provides the underwater camera device which can conveniently be used by a user by detachably combining the underwater camera and the plurality of underwater lighting units in one frame.

Description

Underwater Camera Device

The disclosed content relates to a lighting device used for underwater video recording, and more particularly, to an underwater photography device that can be conveniently used by a user by detachably combining a camera and a plurality of illuminators in one frame. About.

Unless otherwise indicated herein, the content described in this section is not prior art to the claims of this application, and inclusion in this section is not admitted to be prior art.

In general, underwater camera devices for photographing underwater ecology, underwater activities or underwater facilities are widely used for water sports such as scuba diving and snorkel diving, or for marine exploration, marine ecological survey, or maintenance of underwater facilities.

At this time, the underwater camera device is required to have good watertightness so that water does not penetrate into the camera device under water pressure.

In general, in the water, various underwater devices required for diving due to the nature of the environment have been developed accordingly.

For example, a waterproof-based lighting device has been developed for night diving, underwater search for cloudy water, and underwater photography, and conventional underwater lighting devices use light-emitting elements first, which complements the disadvantages of existing halogen lamps. It was developed to do.

In other words, conventional halogen lamps have insufficient color temperature in water, and their use time is largely restricted due to high power consumption, thereby consuming a large-capacity battery.

On the other hand, the use of a light-emitting device (LED) has advantageous characteristics in terms of luminance and power consumption compared to conventional halogen lamps due to the property that the light-emitting device itself converts electrical energy into light.

Here, in terms of the characteristics of underwater lighting, a high-intensity light-emitting device is required, and since one light-emitting device is not sufficient for underwater lighting, a plurality of light-emitting devices are horizontally arranged in parallel.

In particular, a collimator lens is used to secure the straightness of the light, and each light emitting element has a collimating lens, in particular, a collimate lens is used to secure the straightness of the light. The device is individually equipped with an aiming lens.

In addition, the case is equipped with a waterproof O-ring in each part separated to ensure the waterproofing of the lighting device. In particular, a separate mounting ring is installed in the opening of the case forming the irradiation part, and a double waterproof O-ring and a lighting window are mounted.

In addition, a magnetic switch (not shown) is mounted due to the characteristic of water resistance, and the magnetic switch is a non-contact switch that uses a magnet to control a short circuit of the power line inside the case from the outside of the case.

In addition, the case is made of a heat dissipating material, for example, an aluminum alloy, which is for dissipating heat from the light emitting device substrate.

That is, since the light-emitting device for use as underwater lighting must have high brightness, for example, three light-emitting devices of 3 watts are arranged in a light-emitting device lamp performed in a performance, and heat is generated toward the back of the substrate of the light-emitting device for lighting. It is excessive, and an aluminum heat sink is mounted on the back of the substrate to cool it.

In addition, the aluminum heat sink is in contact with the case and radiates heat to the outside through the case to perform cooling toward the light emitting device.

However, such an underwater lighting device is unsuitable for photographing, and there is a problem in that there is a concern about damage to an internal device, a deterioration in battery performance is expected, and a decrease in productivity.

To explain this in more detail, first, an underwater lighting device using a conventional light emitting device is not suitable for photographing due to the horizontal arrangement of the light emitting device.

That is, as described above, a collimating lens is used for underwater irradiation, and each light emitting element has a straightness of about 20° each of the light emitting elements by the collimating lens.

Accordingly, a remnant of a plurality of light sources remains on the irradiated subject, and the overlapped shadow during underwater photography deteriorates the quality of photography.

In addition, a case of requiring high luminance occurs, and when six horizontally arranged cases are predicted, the arrangement area is excessively increased by each collimating lens.

In other words, the collimating lens has a funnel-shaped side shape of the lower-negative beam due to the optical characteristics, and the interference is avoided by the arrangement area above it, and when about 6 light-emitting elements are arranged, the arrangement area is avoided from increasing. Since it cannot be done, the high brightness requires a volume that makes it inconvenient to use, and accordingly, the size of the case and the weight of the case are increased.

Next, due to insufficient heating means, damage to internal devices and deterioration of battery performance are expected.

That is, in an underwater lighting device, an extended heat sink is attached to a heat sink of a substrate for heat dissipation of a light emitting device for lighting, and the aluminum extended heat sink is in contact with an aluminum case, and heat radiation through this is close to indirect heat radiation.

Therefore, when the extended heat sink is heated, the inside of the case is first heated, and the temperature increase of the case particularly degrades the performance of the battery.

In general, it is known that the performance of the battery decreases sharply at around 80℃, and it is a temperature that can be sufficiently heated when the inside of the case is not properly heat dissipated. In particular, if it exceeds 140℃, the battery as well as the light emitting device is damaged I am also concerned.

This was experimentally confirmed that especially, when the high luminance required in the characteristics of underwater photography, for example, 5 watts of light-emitting elements were arranged in an array of six, the inside of the case and the light-emitting elements were damaged.

Of course, it is possible to prevent heating toward the battery side by separately installing a heat shield wall close to the expansion heat sink, but it does not fundamentally improve the deterioration of heat dissipation.

Next, the aluminum case for heat dissipation increases its weight and decreases productivity.

That is, in the prior art, it is essential to make the case of aluminum for heat dissipation, and this aluminum case is generally manufactured by die casting and is also expensive.

In particular, since individual processing of the screw wires for fastening the separate parts must be performed on each part of the separation, this is also a major factor in the decrease in productivity.

In addition, in the conventional underwater lighting device, there is a concern that the appearance of the case is deteriorated by separately processing a screw groove to fasten it with a holder such as an arm, and a separate mounting ring for improving this has a problem that causes the addition of parts. .

In addition, in the conventional shooting of the underwater floor, a diver directly carries an underwater camera and a lighting device and illuminates the floor with a lighting device while photographing an area illuminated by the camera.

Underwater photographing using such a conventional method has several problems.

First of all, since the entire area to be investigated must be photographed, there are many areas that overlap each other, and there is a possibility that some areas that are not photographed may occur.

In addition, when a diver moves forward in one direction and shoots with the sense of the diver, the film is taken with the sense of the diver, so overlapping occurs in the front and rear, and does not coincide in the left and right.

Thus, when the pictures are connected to each other to make a whole picture, it is inefficient and inefficient because the overlapped parts of the front and rear and the parts that do not coincide with each other must be cut out.

In addition, since the diver takes a picture with a camera in the water where movement is not free, the distance between the camera and the floor (ie, accumulation of pictures) is not constant for each picture. This necessitates an additional process in which the distance between the camera and the floor (ie, accumulation of photos) must be arbitrarily matched by enlarging or reducing the photos when connecting the photos to each other.

In order to solve this problem, Korean Patent Application Publication No. 10-2005-0099136 discloses an underwater lighting device.

Looking at this, a case having an irradiation unit consisting of a light source composed of a light emitting element arranged horizontally and a collimating lens individually mounted to the light emitting element, an opening in which a mounting ring, an illumination window and a waterproof O-ring are installed so that the irradiation unit is formed, and the light emission In an underwater lighting device equipped with a ring-type operation device to operate a magnetic switch, consisting of a heat dissipation means for dissipating heat through the case by contacting the heat sink of the light emitting element and the case so that the heat of the element is radiated to the outside,

An irradiation unit comprising a light source composed of light-emitting elements horizontally disposed adjacent to each other and a collimating lens for integrating and irradiating the horizontally disposed light-emitting elements into a single light source; A case having a case and a waterproof O-ring installed between the collimating lens and the opening of the case: An extended heat sink that contacts the heat sink of the light emitting device substrate and is provided in double to provide a heat radiation space and heat radiation by water injected into the heat radiation space. Section: Through-holes formed in the case for circulation of water to the heat dissipation space, and a waterproof O-ring installed on the expansion heat sink to block waterproof inside the case: the aiming lens and waterproof O-rings and light emitting elements mounted from the rear of the case And a heat shield mounting plate that is fastened to the case so as to fix the extended heat sink in response to water pressure and block heat transfer to the battery side.

Another prior document, Republic of Korea Patent Publication No. 10-0967683, relates to an underwater photographing system for photographing the underwater floor, and more specifically, using a frame and a rope, always at a constant distance (that is, the accumulation is the same. ) An underwater photographing system is disclosed that minimizes the underwater bottom surface and unnecessary overlapping photographs, facilitates interconnection of photographed photographs, and makes it easy to grasp the reproductive status of underwater seaweed at a glance,

In Korean Utility Model Publication No. 20-0398282, the design relates to the lighting structure of the exterior lighting of a camera box for underwater photography. The purpose of this is to store the camera confidentially for underwater photography, and the camera itself is used when shooting by operating the camera underwater. It provides a lighting structure for the external lighting of the underwater camera box for safe and continuous underwater photography by reliably preventing the risk of leakage in the camera box and frost in the shooting scene while the flash is lit and the external lighting is lit together at the same time. , The configuration is in a conventional underwater camera box consisting of a main body and an opening and closing plate, and a transparent material that has a screw part on the outer circumferential surface of the upper part and the middle part, and the intermediate screw part is detachably and airtightly assembled in the upper assembly hole of the camera box body Household and; It is an optical cable that has screw fittings at both ends and transmits light transmitted from one end to the other end. One end screw fitting is screwed detachably with the upper thread of the optical collecting port, and the other end is It is composed of an optical transmission cable that is screwed detachably with the optical sensor unit to transmit the light collected and transmitted from the optical collecting port to the optical sensor unit of the external lighting.

However, these inventions only disclose a housing capable of accommodating a camera and a lighting device that emits light, so there is still a problem in that the lighting device must be attached to a camera or used by another user holding the lighting device. .

1. Korean Patent Application Publication No. 10-2005-0099136 2. Korean Patent Publication No. 10-0967683 3. Republic of Korea Utility Model Publication No. 20-0398282

In order to solve the above problems, an object of the present disclosure is to provide an underwater photographing apparatus that can be conveniently used by a user by detachably combining an underwater camera and a plurality of underwater lights in one frame.

The disclosed contents include a frame having a bar shape, but with a mounting hole formed therethrough, and an illumination coupling portion formed at both ends, an underwater camera detachably coupled to the mounting hole of the frame, and the lighting coupling portion of the frame. It includes an underwater illuminator that is combined in a way.

According to a preferred feature of the disclosed content, the frame is formed as a flat plate extending by a predetermined length with the same width, and the mounting hole is formed in a slit shape penetrating along the length direction of the frame.

According to a preferred feature of the disclosed content, the lighting coupling portion is formed to be bent upwardly outward at both ends of the frame, and a first support capable of being gripped by an operator underwater and a second bent upwardly inwardly from the upper end of the first support. It characterized in that it comprises a support and a seat extending outwardly from the second support and formed to maintain a horizontal state with the frame.

According to a preferred feature of the disclosed content, the seating portion is characterized in that a plurality of fitting holes are formed to be spaced apart by a predetermined distance.

According to a preferred feature of the disclosed content, a plurality of coupling holes corresponding to the fitting holes are formed in the lower portion of the underwater illuminator.

According to a preferred feature of the disclosed subject matter, the underwater illuminator includes a front coupling portion to which a first transmission portion is coupled to a front, a space is formed therein, and a housing including a first rear coupling portion to which a third thread is formed on a rear inner peripheral surface, and the It is inserted into the rear of the housing and coupled, and includes a first power terminal part in contact with the + or-pole of the battery on one side, and on the other side, a first power plate on which an electric circuit is formed and a front side of the first power plate and A first light-emitting portion having a plurality of first light-emitting elements electrically connected to the first power plate, and a fourth screw wire screwed to the third screw wire are formed on an outer circumferential surface of one end, and a plurality of batteries are provided inside. A space for accommodating is formed, and a first battery housing including a second power terminal part contacting the + or-pole of the battery is formed on the outer side of the housing and is electrically connected to the first power plate. It characterized in that it comprises a first switch for controlling the operation of the first light emitting device.

According to a preferred feature of the disclosed content, the first switch unit has a multi-stage structure capable of adjusting the brightness of the first light-emitting device step by step, and different wavelengths on the outside of the housing according to the brightness of the first light-emitting device It is characterized in that a plurality of first notification light emitting units that emit light of are formed.

According to a preferred feature of the disclosed subject matter, the underwater illuminator includes a front housing in which a space is formed inside and a second light-transmitting portion is inserted and fixed to one surface, and a first rear coupling portion having a fifth screw line formed on the inner peripheral surface of the rear, and the front A rear housing inserted into the space of the housing and coupled to the rear housing and a third power terminal formed in front of the rear housing and in contact with the + or-pole of the battery on one side, and a second power plate on which an electric circuit is formed on the other side. A second light-emitting portion formed in front of the second power plate and having a plurality of second light-emitting elements electrically connected to the second power plate on one surface, and a sixth screw wire screwed with a fifth screw wire on an outer circumferential surface of one end Is formed, a space for accommodating a plurality of batteries is formed inside, and a second battery housing including a fourth power terminal part contacting the + or-pole of the battery and the outer side of the front housing A second switch part is formed that is electrically connected to the second power plate and controls the operation of the second light emitting device.

According to a preferred feature of the disclosed content, the second switch unit has a multi-stage structure capable of adjusting the brightness of the second light-emitting device step by step, and different from each other according to the brightness of the second light-emitting device outside the front housing. It is characterized in that a plurality of second light emitting units for emitting light of a wavelength are further formed.

As described above, the underwater video shooting portable lighting device can be used in combination with an underwater camera and a plurality of underwater lights in one frame, so that the user can freely and easily perform shooting work in underwater shooting. It provides the advantage of recording clear images.

1 is a perspective view of a combined underwater illuminator according to an embodiment of the disclosed content.
2 is a perspective view of a frame according to an embodiment of the disclosed subject matter.
3 is an exploded perspective view of a cylindrical underwater illuminator according to an embodiment of the disclosed content.
4 is a perspective view of a cylindrical underwater illuminator according to an embodiment of the disclosed content.
5 is an exploded perspective view of a rectangular underwater illuminator according to an embodiment of the disclosed content.
6 is a perspective view of a rectangular underwater illuminator according to an embodiment of the disclosed content.

Advantages and features of the present invention, and a method of achieving them will become apparent with reference to embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in a variety of different forms, only the present embodiments are intended to complete the disclosure of the present invention, and the general knowledge in the technical field to which the present invention belongs. It is provided to completely inform the scope of the invention to those who have it, and the invention is only defined by the scope of the claims. The same reference numerals refer to the same elements throughout the specification.

In describing embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in an embodiment of the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout this specification.

As shown in FIGS. 1 and 2, the frame 100 is formed as a flat plate having a bar shape but extending by a predetermined length with the same width.

The frame 100 may be formed in various shapes such as various rectangular circles.

However, in the frame 100, as shown in FIG. 2, the mounting hole 101 is formed through a certain length, and the lower surface of the underwater camera 10 is coupled to and fixed to the mounting hole 101. It is preferable that the upper surface of (100) is formed to have a flat surface.

The width of the frame 100 may be formed to have various values.

The width of the frame 100 is that the underwater camera 10 is eventually seated and functions as a supporting surface to support its weight. As the width increases, the coupling fixing force of the underwater camera 10 is strengthened.

However, it is economical in terms of manufacturing cost that the lighting coupling unit 200 to be described later is manufactured integrally with the frame 100, and the first support 210 of the lighting coupling unit 200 functions as a handle that can be destroyed by an operator. Bar, the width of the frame 100 is preferably formed to have the same value as the width of the first support 210.

As shown in FIG. 2, the mounting hole 101 is formed in the form of a slit 103 penetrating along the length direction of the frame 100.

As described above, in the mounting hole 101, various types of underwater cameras 10 are fixed by a screw-type coupling member 20, and may be formed into various types of slits 103 such as rectangles, circles, and ovals. have.

However, the underwater camera 10 is not fixed to one point of the mounting hole 101, but is coupled to be movable left and right. Considering that the outer surface of the body of the screw-type coupling member 20 is formed in a cylindrical shape The shape of the slit 103 is preferably formed in an oval shape in which both ends are rounded.

Accordingly, the moving range of the underwater camera 10 in the frame 100 can be extended to both ends of the slit 103.

The width and length of the slit 103 may be variously formed.

The length of the slit 103 is the range of movement of the underwater camera 10, and the width of the screw-type coupling member 20 must be hung under the slit 103 so that the underwater camera 10 is fixed on the frame 100. That is, it is preferable that the operator is formed according to the size and type of the underwater camera 10 to be used.

In addition, the slits 103 may be formed in multiples.

However, in the case of being formed of multiple slits 103, a screw hole (not shown) corresponding to the number of slits 103 must be provided on the lower surface of the underwater camera 10, and a plurality of coupling members 20 are required, There is an advantage in that the bonding force is strengthened by an increase in the bonding point, but there is also a disadvantage in that the cost increases, and the user should consider this point and determine the number of slits 103 according to the work purpose and environment.

Various types of underwater cameras 10 may be used.

For example, a smart phone or a DSLR camera may be accommodated in a smart phone waterproof housing or a DSLR camera waterproof housing and used integrally.

Since the type or structure of the underwater camera 10 is a known technique, a detailed description will be omitted.

The material of the frame 100 can be formed of various materials such as stainless steel (SUS), titanium, aluminum, etc., but considering the convenience of use and corrosion in water, it is made of steel, but a waterproof material such as waterproof paint is used on the surface. It is preferable to apply and use or to be made of an alloy containing copper or lead in the metal.

As shown in FIG. 2, lighting coupling portions 200 are formed at both ends of the frame 100.

Various types of underwater illuminators 300 are detachably coupled to the lighting coupling unit 200.

To this end, as shown in FIG. 2, the lighting coupling part 200 includes a first support 210, a second support 230, and a seating part 240.

As shown in FIG. 2, the first support 210 is formed by being bent upwardly outward at both ends of the frame 100.

The shape of the first support 210 may be formed in various shapes such as a rectangular bar shape having a long vertical axis or an oval shape having convex sides on both sides.

The vertical length, horizontal length, and thickness of the first support 210 may also be formed to have various values.

However, the first support 210 supports the load of the underwater illuminator 300 coupled to the seating unit 240 to be described later, and at the same time functions as a handle that can be gripped by an underwater operator, the first support 210 It is preferable that the horizontal length (width) of) is formed to have a value smaller than the average value of the middle tip of the wrist in the state where the finger of an adult man is extended.

The vertical length, or height, may vary depending on the intended use by the operator.

For example, when photographing at a deep depth, visibility is not good, and the distance between the underwater illuminator 300 and the underwater camera 10 should be formed to be small.

As a result, the vertical length of the first support 210 is the height at which the underwater illuminator 300 is coupled as the second support 230 extends upward from the first support 210.

Therefore, it is preferable that the vertical length of the first support 210 is manufactured in various ways depending on the depth of water or use that the operator intends to photograph.

However, the height of the first support 210 must be formed to have a value greater than the height of the underwater camera 10 to be used.

If the height of the first support 210 is formed smaller than the height of the underwater camera 10 installed on the frame 100, one side of the second support 230 bent inward from the first support 210 Since one surface of the underwater camera 10 is in contact, there is a problem of limiting movement of the underwater camera 10 to both ends of the frame 100.

The degree of bending of the first support 210, that is, the outer bending angle θ1 may also be formed to have various values.

However, since the first support 210 functions as a handle capable of gripping an operator during underwater work as described above, the outer bending angle θ1 is in the range of 90° to 130° based on the frame 100. It is preferably formed.

If it is bent at an angle greater than 130°, there is a problem in that it is difficult for the operator to grip the first support 210 and the support for supporting the load of the underwater illuminator 300 may be weakened.

In addition, if it is bent at an angle less than 90°, it is eventually bent inward. In this case, the space in which the underwater camera 10 can move on the frame 100 is similar to the limitation of the mobility of the underwater camera 10 described above. A shrinking problem occurs.

As shown in FIG. 2, the second support 230 is bent from the upper end of the first support 210 to the inner side in the upper direction.

The shape of the second support 230 may be formed in various forms, and the second support 230 is formed extending from the first support 210 extending from the frame 100, and the frame 100, the first It is economical in terms of manufacturing cost that the support 210 and the second support 230 are integrally manufactured through an extrusion or injection process. The shape of the second support 230 is formed in a rectangular bar shape like the frame 100 It is desirable to be.

The vertical length, that is, the height of the second support 230 may be variously formed, and the height of the first support 210 may be formed to have various heights, similar to that of the above-described first support 210 may be variously formed according to the use of the worker.

The horizontal length (width) and thickness can also be formed in various values, and as described above, it is advantageous in terms of manufacturing cost to manufacture them integrally, so they have the same value as the width and thickness of the frame 100 and the first support 210. It is preferably formed.

As shown in FIG. 2, the angle at which the second support 230 is bent may be variously formed.

However, the second support 230 is formed to be bent inward to effectively support the load of the underwater illuminator 300 coupled to the seating portion 240 to be described later, and the bending angle is small (≤90°). If formed, it is difficult to form the seating part 240 that provides the top surface in a plane by maintaining a parallel state with the frame 100, as well as the moving range of the underwater camera 10 that is coupled to be movable left and right in the frame 100 There is a problem that limits it.

Therefore, it is preferable that the inner bending angle θ2 of the second support 230 is formed in a range of 140° to 160°.

As shown in Figure 2, the seating portion 240 is formed extending outward from the second support 230.

The shape of the seating part 240 is a square. It may be formed in various shapes such as a circle, and it is preferable that the seating part 240 is formed in a rectangular shape with a wide contact area in consideration of the coupling fixing power of the life-life illuminator as various types of underwater illuminator 300 should be coupled. .

As shown in FIG. 2, the seating portion 240 is formed to extend horizontally with the frame 100.

In this way, since the seating portion 240 is formed to be horizontal with the frame 100, the seating portion 240 provides an upper surface as a plane.

As shown in FIGS. 1 and 2, in the seating portion 240 providing a flat surface, the lower portion of the underwater illuminator 300 is interviewed, thereby enhancing the coupling fixing force.

The length and width in which the seating portion 240 extends outward may be formed in various ways.

However, the width is preferably formed to have the same value as the width of the second support 230, similar to the reason why the second support 230 is formed to have the same width as the first support 210.

As shown in FIGS. 1 and 2, various types of underwater illuminators 300 are detachably coupled to the lighting coupling unit 200.

To this end, as shown in FIG. 2, a plurality of fitting holes 242 are formed in the seating part 240 to be spaced apart.

The shape or number of the fitting holes 242 may be variously formed, but the fitting hole 242 has a coupling hole 250 formed under the underwater illuminator 300 to be described later, so that a coupling member such as a screw It is fixed by (20), it is preferable that the shape and number of the fitting holes 242 are formed corresponding to the shape and number of the coupling holes 250.

As shown in FIGS. 1 and 2, an underwater illuminator 300 is coupled to the seating part 240.

This underwater illuminator 300 may be formed of a cylindrical underwater illuminator 310 and a rectangular underwater illuminator 400 as shown in FIGS. 3 to 6.

First, as shown in FIG. 3, the cylindrical underwater illuminator 310 includes a front coupling portion 313 in the front, a space is formed inside, and a housing 311 including a first rear coupling portion 330 at the rear. Is formed.

The shape and size of the housing 311 may be variously formed, for example, it may be formed in the same cylindrical shape as a general lantern.

In front of the cylindrical housing 311, as shown in FIG. 3, a front coupling portion 313 is formed, and a first light transmitting portion 317 is coupled to the front coupling portion 313.

The first light-transmitting portion 317 may be formed in various shapes, for example, it may be formed in a circular shape corresponding to the shape of a generally cylindrical lantern.

In addition, the first light transmitting part 317 may be manufactured and formed integrally with the housing 311.

In this case, there may be an advantage in that the waterproofing effect is increased and the manufacturing cost is lowered, but in consideration of the ease of repair and replacement of other components that can be replaced by each component and are accommodated and coupled therein, the housing 311 It is preferable that the and the first light transmitting part 317 are separately manufactured and combined.

As shown in FIG. 3, various methods such as screwing or an adhesive member may be used as a method in which the first light transmitting part 317 is detachably coupled to the front coupling part 313 of the housing 311.

However, in consideration of corrosiveness due to salt and moisture in underwater use containing salts such as seawater, it is preferable to use a coupling method through screwing in terms of durability and corrosion resistance.

For such screwing, a first screw line 315 must be formed on the outer circumferential surface of one surface of the front coupling part 313, and the first screw wire 315 of the front coupling part 313 is engaged with the outer circumferential surface of the first light transmitting part 317. A second screw wire 318 that can be screwed must be formed.

A method and principle in which the first screw wire 315 and the second screw wire 318 are formed so that the front coupling portion 313 and the first light-transmitting portion 317 are coupled is a known technique, and a detailed description thereof will be omitted.

As shown in FIG. 3, the first rear coupling portion 330 is formed with a first rear hole 333 that is open and formed in one direction.

In the first rear hole 333, one end of the first battery housing 340, which will be described later, is inserted and coupled. The shape of the first rear hole 333 corresponds to the shape of one end of the first battery housing 340. It is preferably formed in a shape that is.

In addition, the first rear coupling portion 330 is formed to protrude in one direction when viewed from the central portion of the housing 311.

This requires a space in which one end of the first battery housing 340 can be inserted at the rear in a state in which the first power plate 350 and the first light emitting unit described later are used in the space formed inside the housing 311 Because it does.

As shown in FIG. 3, a third screw wire 331 is formed on the inner circumferential surface of the first rear coupling part 330 and a fourth screw wire 331 meshed with the third screw wire 331 is formed on the outer circumferential surface of the first battery housing 340. A thread 341 is formed.

However, for a waterproof function, the diameter of the first rear hole 333 must be formed to a value corresponding to the diameter of one end of the first battery housing 340, and a separate waterproof member (packing, etc.) may be used.

In this way, the first rear coupling part 330 is formed to protrude rearward from the center of the housing 311 to form a space, and one end of the first battery housing 340 is inserted and coupled to the space, thereby waterproofing the underwater lighting device. There is an effect of increasing the function.

Since the detailed shape and principle of the screwing of the third screw wire 331 and the fourth screw wire 341 are known techniques, a detailed description will be omitted.

As shown in FIG. 4, the first power plate 350 is inserted into and coupled to the rear of the housing 311.

Specifically, when the first rear hole 333 is formed in a circular shape, the first power plate 350 is also formed as a circular plate, but should be formed to have a diameter smaller than the diameter of the first rear hole 333. do.

Accordingly, the first power plate 350 is accommodated and coupled to the inside of the housing 311 through the rear of the housing 311, that is, the first rear hole 333.

As shown in FIG. 3, a first power terminal part 351 is formed on one surface of the first power plate 350 to which one end (+ or-pole) of the battery contacts.

The first power terminal unit 351 is connected to a battery accommodated in the first battery housing 340 to be described later to supply power to the first light emitting unit 360, and is preferably formed of a conductor.

The shape of the first power terminal 351 may be formed in various forms such as a spring type, a surface contact type, etc., as shown in Figs. 3 and 4 in order to increase waterproofness by minimizing internal empty space when used underwater. It is preferable to be formed in a surface contact type.

As shown in FIG. 4, the first power terminal portion 351 should be formed to be located inside the first rear hole 333 when viewed from the rear of the housing 311.

As shown in FIG. 3, an electric circuit 352 is formed on the other surface of the first power plate 350, that is, a surface formed in a direction opposite to the point where the first rear hole 333 of the housing 311 is formed. do.

The circuit diagram of the electric circuit 352 may be formed in various ways, and electric energy supplied through the first power terminal 351 is transmitted to the electric circuit 352.

The material or principle of the first power plate 350 including the electric circuit 352 and the first power terminal 351 is a known technique, and a detailed description thereof will be omitted.

As shown in FIG. 3, the first light emitting part 360 is formed in front of the first power plate 350.

A plurality of first light-emitting devices 362 are formed on one surface of the first light-emitting part 360 to be spaced apart by a predetermined distance.

Various types of the first light emitting device 362 may be used, and it is preferable to use a light emitting diode (LED) in consideration of power efficiency and convenience in use to the user by minimizing the total volume.

Various types of such a plurality of light emitting diodes may be used.

However, in order to have good luminous intensity, it is advantageous to emit surface light, and it is preferable to form a plurality of densely on the same plane. As shown in FIG. 3, light emission formed in a rectangular or circular piece shape having a thin thickness. It is preferred that a diode is used.

The first light-emitting unit 360 is electrically connected to the first power plate 350, so that the electric energy provided to the first power plate 350 is transmitted to the light-emitting diode of the first light-emitting unit 360, Will be released.

The method and principle of electrically connecting the first power plate 350 and the first light-emitting unit 360 are known techniques, and a detailed description thereof will be omitted.

As shown in FIG. 3, a first battery housing 340 is coupled to the first rear coupling portion 330 of the housing 311.

As shown in FIG. 3, a space capable of accommodating a plurality of batteries is formed inside the first battery housing 340, and a positive or negative electrode of the battery accommodated in the first battery housing 340 is formed on the lower surface. The second power terminal portion 343 that comes into contact with the is formed.

The shape of the first battery housing 340 may be variously formed.

However, the first battery housing 340 functions as a handle that can be gripped by an operator in addition to a power supply function, and is preferably formed in a cylindrical shape corresponding to the shape of a human hand.

As shown in FIG. 3, a fourth screw wire 341 is formed on an outer circumferential surface of one end of the first battery housing 340 to be coupled to the third screw wire 331 of the first rear coupling part 330.

As described above, there are various ways in which the first rear coupling part 330 and the first battery housing 340 are coupled, but when considering the waterproof function and the coupling fixing force in water, it is preferable to use a screw coupling method. .

As shown in FIG. 3, the second power terminal portion 343 is formed so that an electrode opposite to the electrode of the battery that comes into contact with the first power terminal portion 351 may be in contact.

For example, as shown in FIG. 3, if the positive electrode of the battery is formed in contact with the first power terminal 351, the negative electrode of the battery is formed in the second power terminal 343.

The shape, material, and principle of the second power terminal unit 343 for providing electric energy to the first light emitting unit 360 provided inside the housing 311 by contacting the electrode of such a battery are known techniques. Omit it.

As shown in FIG. 3, a first switch unit 370 is formed outside the housing 311.

The first switch unit 370 is electrically connected to the first power plate 350 and controls the operation of the first light emitting unit 360 that is electrically connected to the first power plate 350.

However, the first switch unit 370 is coupled to enable sliding driving in multiple stages, so that the luminous intensity (intensity of light) of the first light emitting unit 360 can be adjusted.

The circuit configuration of the electrical circuit 352 diagram that enables the multi-stage sliding driving of the first switch unit 370 and the electric circuit 352 to adjust the amount of current provided to the first light-emitting unit 360 according to the multi-stage driving Bar detailed description is omitted.

5 shows a rectangular underwater illuminator 400 of another form.

The rectangular underwater illuminator 400 is composed of a front housing 410, a rear housing 430, and a second battery housing 460, as shown in FIG. 5.

The second light transmitting part 420 is coupled to one surface of the front housing 410, and a space is formed behind the position where the second light transmitting part 420 is formed.

The shape of the front housing 410 may be variously formed, such as a cylinder or a rectangle, and for example, may be formed in a rectangular shape.

As shown in FIG. 5, the second light-transmitting part 420 is preferably formed in a shape corresponding to the shape of the front housing 410 to be coupled to one front surface of the front housing 410.

Accordingly, as shown in FIG. 5, when the front housing 410 is formed in a rectangular shape, it is preferable that the second light transmitting portion 420 is also formed in a rectangular plate shape.

The second light transmitting part 420 may be manufactured integrally with the front housing 410, but as shown in FIG. 5 in consideration of ease of exchange and repair, it is preferable to be separately manufactured and combined.

Various methods may be used for the method in which the second light-transmitting part 420 is coupled to the front surface of the front housing 410, but it is preferable to be fixed by a coupling member 20 such as a screw in consideration of the coupling fixing force. In this case, a plurality of fixing holes to which the coupling member 20 can be coupled may be formed on the outer surface of the second light transmitting part 420 and the outer surface of the front housing 410.

Since the coupling method and the fixing hole through the coupling member 20 such as such a screw is a known technique, a detailed description thereof will be omitted.

As shown in FIG. 5, a space is formed inside the front housing 410.

This space accommodates the second power plate 440 and the second light emitting part 450 to be described later, and the space may be formed differently depending on the size and thickness of the second power plate 440 and the second light emitting part 450. I can.

As shown in Figure 5, the rear housing 430 is coupled to the rear of the front housing 410.

The shape of the rear housing 430 may be variously formed, but the front surface of the rear housing 430 is coupled in contact with the rear surface of the front housing 410, and the rear housing 430 is the front housing 410 It is preferable to be formed to have the same length and height.

There are various ways in which the rear housing 430 is coupled to the front housing 410, but it is preferable to be coupled through screwing as shown in FIG. 5 in consideration of the coupling fixing force.

To this end, a plurality of front housing coupling holes 415 are formed on the upper and lower surfaces of the front housing 410.

In addition, a plurality of protrusions 431 in which a rear housing coupling hole 435 corresponding to the front housing coupling hole 415 is formed are formed on the upper and lower surfaces of the rear housing 430.

5 and 6, when the rear housing 430 is coupled to the front housing 410, the protrusion 431 is placed at a point where the front housing coupling hole 415 is formed.

However, each surface of the front housing 410 and the rear housing 430 must be closely coupled to prevent water from entering the bar. As shown in FIGS. 5 and 6, the rear housing 430 It is preferable that a fitting groove 412 having a length and width corresponding to the length and width of the protrusion 431 is formed on the upper and lower surfaces of ).

The protrusion 431 is forcibly fitted to the fitting groove 412, and the front housing coupling hole 415 and the rear housing coupling hole 435 are coupled to each other to be positioned at the same point, and are coupled through screws, etc. In addition, the holding power is strengthened.

As shown in FIGS. 5 and 6, a second rear coupling portion 436 is formed at the rear of the rear housing 430.

The second rear coupling portion 436 is formed to protrude in one direction, like the first rear coupling portion 330, and a second rear hole 439 is formed therein.

Also, like the third screw wire 331 of the first rear coupling part 330, a fifth screw wire 437 is formed on the inner circumferential surface of the second rear coupling part 436.

A detailed description of this is the same as that of the first rear coupling unit 330 described above, and a detailed description thereof will be omitted.

As shown in FIG. 5, the second power plate 440 is formed in front of the rear housing 430, and a third power terminal part 441 in contact with the + or-pole of the battery is formed on one side, and electricity is on the other side. Circuit 352 is formed.

The shape of the second power plate 440 may be variously formed, but unlike the first power plate 350 that is inserted and coupled to the inside of the housing 311 through the first rear coupling part 330, the rear housing It is preferably formed in a rectangular shape corresponding to the shape of the rear housing 430, which is laminated and coupled to the front surface of the 430.

The shape and function of the third power terminal portion 441 and the electric circuit 352 are the same as those of the second power terminal portion 343 and detailed descriptions thereof will be omitted.

As shown in FIG. 5, a plurality of second light emitting devices 451 are formed on one surface of the second light emitting part 450.

Various types of the second light emitting device 451 may be used, but it is preferable that a light emitting diode is used like the first light emitting device 362.

The second light emitting part 450 is formed on the front surface of the second power plate 440 and is electrically connected.

A detailed description of this has been described above, and a detailed description thereof will be omitted.

As shown in FIG. 5, a sixth screw wire 462 is formed on the outer circumferential surface of one end of the second battery housing 460, and a space in which a plurality of batteries can be accommodated is formed, and the positive or negative pole of the battery is formed on the lower surface. A fourth power terminal part 463 that comes into contact with the is formed.

The detailed structure and function thereof are the same as those of the first battery housing 340 described above, and a detailed description thereof will be omitted.

As shown in FIG. 5, the second switch unit 470 is formed outside the front housing 410 and is electrically connected to the second power plate 440.

Like the first switch unit 370, the second switch unit 470 has a multi-stage structure so that the amount of current can be adjusted step by step.

Accordingly, the intensity of light of the second light emitting device 451 formed in the second light emitting part 450 can be adjusted step by step.

Since the shape and coupling structure of the second switch unit 470 is a known technique, a detailed description thereof will be omitted.

As shown in FIG. 5, the first notification light emitting part 500 and the second notification light emitting part 600 are formed outside the housing 311 or the front housing 410.

The first notification light-emitting unit 500 and the second notification light-emitting unit 600 easily inform the operator of the intensity of light according to the stepwise control of the first switch unit 370 or the second switch unit 470 described above. It is to give.

That is, the operator must visually recognize the intensity of the light by distinguishing the light color of the first notification light emitting unit 500 and the second notification light emitting unit 600, and the housing 311 or the front housing 410 It is not desirable to be formed on the front or back side.

The first notification light-emitting part 500 and the second notification light-emitting part 600 may be formed on the housing 311 or the like through various coupling methods. Considering their use in water, they are preferably combined in a buried type. Do.

In addition, a plurality of light-emitting diodes emitting light of different wavelengths are accommodated and combined in the interior of the first light-emitting unit 500 for notification and the second light-emitting unit 600 for notification.

In addition, each third light emitting device 501 operates according to a specific amount of current through a program of circuits formed on the first power plate 350 and the second power plate 440, thereby distinguishing the color of the emitted light. Through this, it is possible to recognize the stage of each switch unit.

This provides the advantage that the operator can easily check the state of the underwater illuminator 300 even in water with poor visibility.

As shown in FIGS. 3 and 5, a plurality of coupling holes 250 corresponding to the fitting holes 242 of the seating portion 240 are formed in the lower portion of each underwater illuminator 300.

In the case of the cylindrical underwater illuminator 310, as shown in FIG. 3, a coupling hole 250 is formed in the lower surface of the housing 311.

However, since the mounting surface of the lighting coupling unit 200 is formed in a flat plate and the lower surface of the underwater illuminator 300 must be coupled for an interview, the lower surface of the cylindrical underwater illuminator 310 is flat as shown in FIG. It is preferable to include a flat portion 320 to be formed, and further, a jaw 321 to which one end of the seating portion 240 is held may be formed on one side of the flat portion 320.

In addition, a plurality of coupling holes 250 are formed in the flat portion 320.

Thereby, the coupling hole 250 of the cylindrical underwater illuminator 310 and the fitting hole 242 of the seating part 240 come to the corresponding positions, and one end of the coupling member 20 such as a screw is the coupling hole 250 And through the fitting hole 242 is integrally coupled.

As shown in Fig. 5, the rectangular underwater illuminator 400 has a plurality of coupling holes 250 formed on the lower surface of the front housing 410, and the seating portion 240 is similar to the cylindrical underwater illuminator 310 described above. It is fixed by a coupling member 20 such as a screw.

As described above, various types of underwater lights 300 can be detachably combined with one frame 100 to provide convenience and diversity in use to underwater workers.

The contents are only examples, and various changes can be made by those of ordinary skill in the art without departing from the gist of the claims claimed in the claims, so the scope of protection of the disclosed contents is limited to the specific implementation described above. It is not limited to examples.

Although preferred embodiments of the present invention have been described with reference to the accompanying drawings, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and represent all the technical ideas of the present invention. Since it is not, it should be understood that there may be various equivalents and modifications that may be substituted for them at the time of application. Therefore, the embodiments described above should be understood as illustrative and non-limiting in all respects, and the scope of the present invention is indicated by the claims to be described later rather than the detailed description, and the meaning and scope of the claims and the All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

10: underwater camera
20: coupling member
100: frame
101: mounting hole
103: slit
200: lighting coupling unit
210: first support
θ1: outer bending angle
230: second support
θ2: inner bending angle
240: seat
242: fitting hole
250: coupling hole
300: underwater illuminator
310: Cylindrical underwater illuminator
311: housing
313: front coupling part
315: first screw line
317: first light transmitting part
318: second screw line
320: flat part
321: chin
330: first rear coupling part
331: third screw line
333: 1st rear hall
340: first battery housing
341: fourth thread
343: 2nd power terminal part
350: first power plate
351: first power terminal part
352: electric circuit
360: first light emitting unit
362: first light-emitting device
370: first switch unit
400: rectangular underwater illuminator
410: front housing
412: fitting groove
415: front housing coupling hole
420: second light transmitting part
430: rear housing
431: protrusion
435: rear housing coupling hole
436: second rear coupling part
437: fifth screw line
439: 2nd rear hall
440: second power plate
441: 3rd power terminal part
450: second light emitting unit
451: second light-emitting device
460: second battery housing
462: 6th thread
463: 4th power terminal part
470: second switch unit
500: first notification light emitting unit
600: second notification light emitting unit

Claims (9)

A frame having a bar shape, but having a mounting hole through it, and in which lighting coupling portions are formed at both ends;
An underwater camera detachable to the mounting hole of the frame and coupled to enable left and right movement; And
Underwater photographing apparatus comprising an underwater illuminator detachably coupled to the lighting coupling portion of the frame. The method of claim 1,
The frame is formed of a flat plate extending by a predetermined length with the same width,
The mounting hole is an underwater photographing apparatus, characterized in that formed in the shape of a slit penetrating along the length direction of the frame. The method of claim 1,
The lighting coupling portion is formed to be bent upwardly outward at both ends of the frame, the first support that can be gripped by an operator underwater;
A second support bent inward from an upper end of the first support; And
And a seating portion extending outward from the second support and formed to maintain a horizontal state with the frame. The method of claim 3,
An underwater photographing apparatus, characterized in that a plurality of fitting holes are formed to be spaced apart by a predetermined distance in the seating portion. The method of claim 4,
An underwater photographing apparatus, characterized in that a plurality of coupling holes corresponding to the fitting holes are formed in a lower portion of the underwater illuminator. The method of claim 1,
The underwater illuminator includes a front coupling portion to which a first light transmitting portion is coupled to a front, a space formed therein, and a housing including a first rear coupling portion having a third screw wire formed on a rear inner peripheral surface;
A first power plate inserted into and coupled to the rear of the housing and including a first power terminal on one side and in contact with the + or-pole of the battery, and on the other side of which an electric circuit is formed;
A first light-emitting unit formed in front of the first power plate and having a plurality of first light-emitting elements electrically connected to the first power plate on one surface thereof;
The second power terminal part is formed on the outer circumference of one end with a fourth screw threaded to be screwed with the third screw, and a space for accommodating a plurality of batteries is formed therein, and a second power terminal part in contact with the + or negative pole of the battery on the lower surface A first battery housing comprising a; And
And a first switch part formed outside the housing and electrically connected to the first power plate to control the operation of the first light-emitting device. The method of claim 6,
The first switch unit has a multi-stage structure capable of adjusting the brightness of the first light emitting device step by step,
An underwater photographing apparatus, wherein a plurality of first notification light emitting units are formed outside the housing to emit light of different wavelengths according to the brightness of the first light emitting device. The method of claim 1,
The underwater illuminator includes a front housing having a space formed therein and a second light-transmitting portion inserted and fixed to one surface thereof;
A rear housing including a first rear coupling portion having a fifth screw line formed on an inner circumferential surface of the rear, and inserted into and coupled to the space of the front housing;
A second power plate formed in front of the rear housing and including a third power terminal part on one side of the battery in contact with the + or-pole of the battery, and on the other side of which an electric circuit is formed;
A second light-emitting unit formed in front of the second power plate and having a plurality of second light-emitting elements electrically connected to the second power plate formed on one surface thereof;
The outer circumferential surface of one end is formed with a sixth screw that is screwed with the fifth screw, and a space for accommodating a plurality of the batteries is formed inside, and a fourth power terminal part in contact with the + or-pole of the battery is formed on the lower surface. A second battery housing including; And
An underwater photographing apparatus, characterized in that a second switch part is formed on the outside of the front housing and electrically connected to the second power plate to control the operation of the second light emitting device. The method of claim 8,
The second switch unit has a multi-stage structure capable of adjusting the brightness of the second light emitting device step by step,
An underwater photographing apparatus, characterized in that a plurality of second notification light-emitting units emitting light of different wavelengths according to the brightness of the second light-emitting device are further formed outside the front housing.

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