KR101344762B1 - Omnidirectional surveillance cameras - Google Patents

Abstract

The present invention relates to a surveillance camera which is installed in the parking lot, etc. to photograph and record the access of a vehicle or various situations and, more particularly to a surveillance camera which comprises a camera module inserted into a divided sphere transparent cover body, wherein the camera module includes a fisheye lens formed to be combined, and wherein the camera module including the fisheye lens has the pan/tilt function by a rotary combining element rotated from an internal case and a module combining element combined to be angle-adjusted from the rotary combining element. Thereby, the surveillance camera of the present invention can be easily installed by being simply fixed to a race way installed in a ceiling of the parking lot, etc., and the larger area can be photographed and managed with the single surveillance camera by applying the fisheye lens. Furthermore, since the camera module located inside of the case is rotated and is angle-adjusted by the artificial force, the surveillance camera may be adjusted and installed in the best and optimum photographing direction and photographing angle, thereby bringing both of the economic efficiency of the existing low-priced surveillance camera and the functional advantage of the high-priced surveillance camera.

Description

Omnidirectional surveillance cameras with pan tilt structure

The present invention relates to a surveillance camera installed in a parking lot and the like to record and record the entry and exit of a vehicle, and more particularly, to a fan-filtrating means in a spherical case that is dividedly formed. By forming a camera module to be fixed and coupled to the camera module, by securing the wide shooting range by the fisheye lens coupled to form the fisheye lens and through the pan filter means to be installed to secure the best shooting angle and range It's about one omnidirectional surveillance camera.

In general, a parking lot in a building is installed with a large number of lights using a ceiling slab, and with such lights, surveillance cameras for the purpose of preventing the record of a car's entry or a safety accident or theft and crime in the parking lot. Will install

In the case of such a surveillance camera is to be recorded and monitored at all times through the recording device and monitor provided in the management room or operation room.

In addition, in the near future, as a separate detection sensor is installed together with the above-mentioned lighting lamp, the lighting is usually turned on with low illuminance, but when the vehicle or a person approaches, the lighting is turned on with a brighter illumination. In order to save energy, the recording means as described above also prevents unnecessary data storage or monitoring as the recording is performed only when a vehicle or a human motion is detected.

In particular, the recently introduced lighting and management system in the parking lot is connected to the above-described lighting and recording means together, when a person or a car approaches the event recording is made by sending a signal to the lighting means of the lamp such that the above lighting It is configured to be lit together so that more efficient operation is achieved through linkage operation between each other. From this, more advanced technology, when the parking area in the parking lot is empty through the recording means, the illumination of the lighting of the corresponding position is The driver who wants to park by differentiating the difference between them recognizes it from a long distance and makes it easier to secure a parking space and to park the vehicle.

In the case of such a surveillance camera, by applying an aspherical optical lens such as Patent Registration No. 10-1104032, a single surveillance camera can be used to shoot and record a larger area. Parking surface management system using a omnidirectional camera as in 0976441, and a management method thereof has been proposed, and an omnidirectional security system equipped with a light emitting diode capable of adjusting the light emission intensity using an omnidirectional camera as in Patent No. 10-0991104; The omnidirectional security method using this has been devised.

However, the surveillance cameras applied to the systems and methods described above have problems such as blind spots due to limitations in the shooting range and free control of the shooting angle. will be.

In addition, since the surveillance cameras of many individuals are installed in order to prevent the blind spots from occurring as described above, it has a high cost of installation and a considerable amount of manpower and time to manage and monitor them.

That is, the surveillance cameras as described above are mostly used by combining a ready-made camera module with a case, and thus have a characteristic of shooting only at a unique angle of view possessed by the original camera module. When using an aspherical optical lens, such as a registered patent, the angle of view may be extended, but there is a problem that cannot effectively cope with a large area such as a parking lot.

In addition, since the surveillance cameras applied to the parking system as described above are applied in large quantities to a large area, relatively inexpensive surveillance cameras are used. Such a surveillance camera has an extremely simple angle adjustment structure for the camera module. It is designed to have a problem that the camera module can not be accurately set to the required angle and direction.

As a result, a relatively expensive surveillance camera having a pan-filt structure is applied, but the pan-tilt structure for the camera module is mostly made automatically by a plurality of drive motors, which is very expensive and the angle is adjusted. Surveillance cameras that need to shoot only a fixed range in the unfavorable problem in terms of economics and efficiency.

The present invention is to solve the problems as described above, the camera module is inserted into the inside of the spherical transparent cover to be divided into the camera module is formed by combining the fisheye lens and the camera module having the fisheye lens from the inner case As configured to have a pan-tilt function by the rotary coupler is rotated and the modular coupler coupled to the angle adjustment from the rotary coupler,

Due to the 180 ° angle of view of the fisheye lens, the camera module having the fisheye lens can be freely rotated and angled by artificial force by the rotating and spherical module. It is an object of the present invention to provide an omnidirectional surveillance camera having a pan tilt structure that can be set and installed at the most optimal shooting direction and shooting angle.

The present invention for achieving the object as described above, the hemispherical upper cover body and the semi-spherical transparent lower cover body is formed by coupling the upper and lower by the coupling ring of the middle portion, the inner surface of the upper cover body as described above A cover body is formed to be coupled, and an inner side of the inner cover body is coupled to form a separate rotatable splice to be rotatable from the inner cover body. It is formed by coupling to adjust the angle from the rotating coupling, the camera module is made by combining a separate fisheye lens.

The present invention is easy to install because it can be easily fixed to the raceway (Race-way) is installed on the ceiling of the parking lot, etc., shooting a wider area using a single surveillance camera by applying a fisheye lens And management can be made, and the camera module located inside the case is variously rotated and angled by artificial force, so it can be installed at the most optimal and optimal shooting direction and shooting angle. And it has the effect that can produce all the functional advantages of the expensive surveillance cameras.

1 is an example of the use of the surveillance camera according to the invention installed
2 is an overall perspective view of a surveillance camera according to the present invention
3 is an exploded perspective view of the surveillance camera according to the present invention
4 is a cross-sectional view of the surveillance camera according to the present invention
5 is an exploded cross-sectional view of a surveillance camera according to the present invention.
Figure 6 is a perspective view of the internal module of the surveillance camera according to the present invention
Figure 7 is an exploded perspective view of the internal module of the surveillance camera according to the present invention
8 is an exploded perspective view of the module rotating unit of the surveillance camera according to the present invention
9 is an exploded perspective view of the module angle adjustment unit of the surveillance camera according to the present invention
Figure 10 is a side view showing a module angle adjustment state of the surveillance camera according to the invention

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor may properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exemplary view illustrating the use of a surveillance camera according to the present invention, FIG. 2 is an overall perspective view of the surveillance camera according to the present invention, FIG. 3 is an exploded perspective view of the surveillance camera according to the present invention, and FIG. 5 is an exploded cross-sectional view of the surveillance camera according to the present invention, Figure 6 is a perspective view of the internal module of the surveillance camera according to the present invention, Figure 7 is a separation of the internal module of the surveillance camera according to the present invention Perspective view.

As shown in FIG. 1, the surveillance camera according to the present invention is installed in association with a plurality of lamps 120 with respect to a wiring conduit 110 installed from a ceiling 100 as a preferred embodiment as shown in FIG. 1. When the recording and the event occurs inside the parking lot by the recording is to be made with this and it is possible to control the flashing for the lamp 120.

Such a surveillance camera of the present invention is divided into a transparent hemispherical upper cover body 11 and also a transparent hemispherical lower cover body 12 and these upper cover body 11 and the lower cover body 12 are combined separately It is to have a spherical shape while being coupled up and down by the ring body (10).

At this time, the upper cover body 11 may be firmly fixed to each other by bonding them in a state that the lower end is inserted into the coupling ring body 10, the lower cover body 12 is a coupling ring ( It would be ideal to apply a screwing structure to each other so that separation and coupling can be made freely from 10).

In addition, a separate screw fastener 13 is formed on the upper outer side of the upper cover body 11 as described above, and the upper cover body 11 and the screw fastener 13 are lower ends of the screw fastener 13. It will be desirable to be able to be firmly fixed to the upper cover body 11 by a locking jaw formed in the screw fasteners 13 as described above by forming a separate fastening nut 14 is combined Surveillance camera of the invention can be easily fixed and installed in the wiring pipe.

That is, in the insertion hole (not shown in the drawing) formed in the wiring conduit 110, the screw fastener 13 protrudes to the upper side of the insertion hole in the state where the screw fastener 13 is inserted as described above. As the fastening nut 14 is formed firmly coupled, the monitoring camera of the present invention may be easily and easily fixed to the wiring line.

Such a surveillance camera of the present invention is that a separate inner cover body 20 is formed on the inner surface of the upper cover body 11, the inner cover body 20 is made of a hemispherical through the opaque resin The inside of the surveillance camera is prevented from being seen through the transparent upper cover body 11 and the built-in camera module 50 serves to rotate along the virtual vertical axis of the surveillance camera. .

In addition, the lower side of the inner cover body 20 as described above is a separate rotation coupling sphere 30 is rotatably formed from the inner cover body 20, the rotary coupling sphere 30 as described above As a separate module coupler 40 having a camera module 50 is formed to be coupled, the module coupler 40 is coupled so that the angle adjustment can be made from the rotary coupler (30) and eventually The same camera module 50 is able to adjust the angle from the rotary coupler (30).

Here, the inner cover body 20 as described above, as shown in Figure 8 is formed at least two protruding downward projections on the inner end of at least two places, the locking bullet strip 21 is rotated. It has elasticity in the up and down direction by the incision line (not shown in the figure) penetrated in the "c" shape from the upper surface of the coupler (30).

In addition, the rotating coupling sphere 30 rotated from the inner cover body 20 as described above, the angle adjustment grooves 31, 31 ′ formed on the upper surface to interfere with the engaging bullet strip 21 repeatedly formed radially. On both sides, downward support plates 32 and 32 'are integrally formed, and in the support plates 32 and 32' as described above, the hinge hole 33 and the hinge hole 33 It consists of a slit hole (34) formed on the upper side, the bottom of the rotary coupling sphere 30 as described above, at least two or more elastic fastening by the incision line to pass through the upper and lower in the form of "c" The sphere 35 is formed to protrude downward.

Such a rotary coupling device 30 uses a mutual coupling structure or a separate fixing ring or coupling ring from the upper cover body 11 or the inner cover body 20 or the screw fastener 13 by the locking jaw. As it is fixed to be rotated from the vertical axis center of the inner cover body 20 by holding the rotary coupler 30 by hand and rotated by artificial force to catch the engaging ball 21 and the angle adjustment groove ( 31) to overcome the interference force by the 31 'and the free rotation of the rotary coupler 30 can be made.

In addition, the locking force acting between the locking carbon sphere 21 of the inner cover body 20 and the angle adjusting grooves 31 and 31 'of the rotary coupling port 30 is the rotary coupling hole 30. Serves to prevent the rotation of the arbitrarily rotated, only when the rotary coupler 30 is forcibly rotated by an artificial force, the rotational action on the rotary coupler 30 can be achieved while overcoming the mutual interference force will be.

As shown in FIG. 9, a separate module coupler 40 is fastened from the bottom to the rotary coupler 30 as described above, and a separate camera module is inserted into the module coupler 40 as described below. 50 is coupled to each other, and the rotating shaft portion 41 corresponding to the hinge hole 33 of the rotary coupling sphere 30 is formed on both sides of the module coupling sphere 40 as described above, Guide protrusions 42 to be inserted into the slit hole 34 of the rotary coupler 30 is formed to protrude to both sides.

In addition, at both ends of the module coupling sphere 40 as described above, the engaging teeth 43 for engaging the resilient locking holes 35 formed on the bottom of the rotary coupling sphere 30 is formed.

Accordingly, the rotary shaft portion 41 of the module coupling sphere 40 is inserted into the hinge hole 33 of the rotary coupling sphere 30 as described above, and the guide protrusion 42 is formed inside the slit hole 34. To be inserted, the resilient locking hole 35 is to be assembled to the engaging module (40) with respect to the rotary coupling sphere 30 is to be engaged with the engaging teeth (43).

At this time, the locking teeth 43 is formed in a curved shape on the circumferential surface of the rotary shaft portion 41 as the axial center at the time of angular rotation of the module coupling sphere 40 with respect to the rotary coupling sphere 30 The resilient latch 35 is to cause a continuous interference force with the engaging type 43.

In addition, since the guide protrusion 42 of the module coupling hole 40 is inserted into the slit hole 34 of the rotary coupling hole 30, the above-described guide protrusion (at the time of angular rotation with respect to the module coupling hole 40 as described above). 42 may be rotated only in the slit hole 34 so that it serves as a stopper for limiting the range of angle adjustment for the module coupling hole 40.

Accordingly, as shown in FIG. 10, the modular coupling hole 40 as described above may have a free angle control within the range of the slit hole 34 using the hinge hole 33 of the rotary coupling hole 30 as an axial point. In the angle adjustment process as described above, as the engaging latch 35 of the rotary coupler 30 and the engaging type 43 of the module coupler 40 continues to interfere, the module coupler 40 is Instead of being rotated arbitrarily, it can only be rotated at a desired angle when an artificial force is applied.

In addition, the camera module 50 which is inserted upward from the bottom of the module coupling sphere 40 as described above is a normal camera module 50 built in a general surveillance camera, depending on the performance in color or black and white depending on the performance and various image quality When the event occurs in the parking lot by the camera module 50 as described above, it is possible to build a more effective lighting and security system in the parking lot through the flashing of lights or the difference in illumination in connection with the camera module 50 at the same time. It is.

In this case, as a separate fisheye lens 51 is formed at the bottom of the camera module 50 as described above, it is possible to photograph a larger area due to the wide angle of view of the fisheye lens 51. Similarly, since the fisheye lens 51 generally has an angle of view of about 180 °, when the fisheye lens 51 is formed in close contact with the camera module 50, the camera module 50 is 180 ° from the installation angle. Since the inside of the parking lot can be photographed with an angle of view of inside and outside, a very large area can be photographed even with a single surveillance camera, thereby greatly reducing the number of surveillance cameras required for installation.

In addition, since the blind angle does not occur as the angle of view of the surveillance camera is widened, it is possible to prevent and solve various crimes and safety accidents as well as the difficulty caused by the disputes occurring in the blind spots. .

As the fisheye lens 51 is accommodated and fixed by the fastening ring 52 coupled to the lower end of the camera module 50, the general camera module 50 is applied as it is to complete the omnidirectional surveillance camera having a wide angle of view. To be.

In addition, the camera module 50 as described above is located in the transparent lower cover body 12 to face the room can be protected by the lower cover body 12 from dust or impact.

In particular, the coupling ring 52 of the camera module 50 as described above, as the module cover body 53 of the upward curved coupling form the lower cover body 12 of the transparent due to the module cover body 53 By acting to conceal the camera module 50 shown as to be able to produce a more beautiful exterior of the surveillance camera of the present invention.

Accordingly, the surveillance camera of the present invention can be easily installed by using a bezel pipeline such as a parking lot, and is also installed by using a wiring pipeline, so that flashing and linked control of adjacent lights can be made. This can significantly reduce the number of surveillance cameras installed.

In addition, it is possible to perform the pan tilt function by the rotary coupling sphere 30 and the module coupling sphere 40 fixing the camera module 50 as described above, the shooting direction or angle for the camera module 50 If it is necessary to adjust the separation of the lower cover body 12 from the coupling ring body 10, while holding the rotary coupling sphere 30 while holding it in the vertical axis direction to perform adjustment for the shooting direction It is possible, and the adjustment of the angle of the module coupling sphere 40 from the rotary coupling sphere 30 in the state that the adjustment for the shooting direction is to be made to precisely adjust the shooting angle.

Therefore, even when the surveillance camera of the present invention is fixedly installed, it is possible to freely adjust the shooting direction or the shooting angle of the camera, and if the adjustment is made for the direction and the angle, the stable camera is maintained because it is stably adjusted. Installation and thereby efficient management and maintenance of the parking lot.

As described above, the surveillance camera of the present invention may be used for the purpose of maintenance and management of the parking lot and crime prevention, and may be installed for various purposes in various places, such as indoors and outdoors, as necessary. It can be used for many purposes without any distinction of application.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the present invention as defined by the appended claims. Examples should be understood.

10: coupling ring body 11: upper cover body
12: lower cover body 13: screw fastener
14: Tightening Nut
20: inner cover body 21: jam bullet strip
30: rotating coupling 31,31 ': angle adjustment groove
32,32 ': Support plate 33: hinge hole
34: slit ball 35: elastic hook
40: module coupling port 41: rotating shaft portion
42: guide protrusion 43: hook type
50: camera module 51: fisheye lens
52: fastening ring 53: module cover body

Claims (7)

The hemispherical upper cover body 11 and the hemispherical transparent lower cover body 12 are formed to be coupled up and down by the coupling ring body 10 in the middle portion.
The inner cover body 20 is formed on the inner surface of the upper cover body 11 as described above, and a separate rotary coupler 30 is rotated from the inner cover body 20 inside the inner cover body 20. Formed to be coupled to enable, the rotary coupler 30 is coupled to form a separate module coupling sphere 40 to the camera module 50 is coupled to the lower side to adjust the angle from the rotary coupling sphere 30,
In the camera module 50, the omnidirectional surveillance camera having a pan-tilt structure formed by combining a separate fisheye lens 51,
A radial angle adjusting groove 31 is formed at the inner end of the inner cover body 20 so as to protrude downwardly from the engaging carbon strip 21, and the engaging carbon strip 21 is inserted into the upper surface of the rotary coupler 30. 31 '), the rotation is caused by the interference force acting between the engaging ball 21 of the inner cover body 20 and the angle adjusting grooves 31 and 31' of the rotary coupler 30. All-in-one surveillance camera having a pan tilt structure, characterized in that the coupling sphere 30 is configured to be made only by artificial force.
The method of claim 1,
The rotary coupler 30 forms a support plate 32, 32 'protruding downward to both sides so that the module coupler 40 is inserted between the support plate 32, 32',
The support plates 32 and 32 ′ form a hinge hole 33 in the middle portion and a slit hole 34 above the hinge hole 33, and the hinge hole 33 on both sides of the module coupling hole 40. ) To form a rotating shaft portion 41 and the guide protrusion 42 inserted into the slit hole 34,
The guide hole 42 is positioned inside the slit hole 34 so that the module coupler 40 is rotated from the rotary coupler 30 by the coupling of the hinge hole 33 and the rotary shaft part 41. The omnidirectional surveillance camera having a pan tilt structure, characterized in that configured to be limited by the rotation angle of the module coupling sphere (40) by.
3. The method of claim 2,
Both ends of the module engaging port 40 is formed with a catching tooth 43, and the inner engaging end of the rotary engaging tool 30 corresponding to the catching tooth 43 is formed by protruding downwardly the elastic catching hole 35 By the interference force of the locking type 43 and the resilient locking hole 35, the module coupling sphere 40 is configured to be angled from the rotary coupler 30 only by artificial force, characterized in that the pan tilt structure Omnidirectional surveillance camera. delete delete delete delete

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