CN111213619A

CN111213619A - Fish gathering lamp with monitoring system

Info

Publication number: CN111213619A
Application number: CN201910507026.8A
Authority: CN
Inventors: 黄向岸; 庄德江; 董岩; 蔡行平
Original assignee: Crystal Optoelectronics Xiamen Co Ltd
Current assignee: Crystal Optoelectronics Xiamen Co Ltd
Priority date: 2019-06-12
Filing date: 2019-06-12
Publication date: 2020-06-02
Anticipated expiration: 2039-06-12
Also published as: TW202044989A; PH22020050216U1; PH22020050216Y1; TWI724470B; CN111213619B

Abstract

The invention discloses a fish gathering lamp with a monitoring system, which comprises: a housing unit having a lower cover disposed in a vertical direction, the lower cover having a lower cover ring side portion and a lower cover bottom portion disposed at an end edge of the lower cover ring side portion; a lens arranged at the side part of the lower cover ring; a light source unit arranged at the bottom of the lower cover along the vertical direction; and the waterproof unit is arranged on the lower cover and used for coating the lens or the light source unit and providing water pressure protection. The light source unit and the lens are protected by the waterproof unit, so that when the fish gathering lamp with the monitoring system enters a deep sea area and bears water pressure, seawater can be prevented from permeating into the shell unit, and the lens and the light source unit are prevented from being damaged due to dampness.

Description

Fish gathering lamp with monitoring system

Technical Field

The invention relates to the field of illumination of fishery, in particular to a fish gathering lamp with a monitoring system.

Background

As fish light systems are becoming more common in fisheries, a number of problems are still derived in addition to power output. When an ocean fishing boat goes out of the sea, the short time is nine months, and the long time is two or three years, so that the fish gathering lamp system is designed to increase the power output, and besides, the problems that how to monitor the fish in the sea and identify the fish in the sea are needed to be considered and solved are also solved.

The seawater can be divided into a light-transmitting layer and a light-free layer according to the degree of light transmission. The euphotic layer is a region where light can reach the surface layer of the depth of the water body when sunlight irradiates the water body, algae or plankton and the like can perform photosynthesis, the depth of the euphotic layer is influenced by the water quality of the water body, and the euphotic layer can be less than 1 meter in a chaotic water body; but can reach 50 meters to 100 meters, even 200 meters in clean water. When the depth reaches 200 meters, the visible light is almost completely absorbed, the "illumination area" within 0 to 200 meters is called a light-transmitting layer in oceanology, and the "illumination area" with the depth more than 200 meters is called a light-free layer, so that the fish gathering lamp monitoring system must have the function of providing illumination when detecting without the light-transmitting layer.

In addition, each 10 meters of seawater will increase one atmosphere of water pressure, and if a fish school with a depth of 300 meters is to be monitored, the fish gathering lamp monitoring system must be able to withstand a water pressure of 30 atmospheres and avoid the damage caused by seawater leakage into the system due to pressure.

At present, an underwater photographing device which is only waterproof by a sealing ring on the market does not have a high beam with a waterproof function, the depth of the underwater photographing device is about 50 meters more, and the underwater photographing device cannot be applied to deep sea fish school detection and monitoring of the ocean. In order to monitor fish shoal over 50 meters and even 300 meters deep, in addition to solving enough light source and withstanding 300 meters deep water pressure and water resistance, the following problems need to be considered: the monitoring system has the advantages of monitoring visual angle, system volume, protection of the monitoring system against seabed reefs, sensing of environments such as depth, temperature, direction, salinity and the like, and real-time living body identification and fish species identification.

Disclosure of Invention

The object of the present invention is to solve the problem of water seepage of underwater photography device caused by water pressure problem in deep sea photography.

To achieve the above object, the present invention provides a fish gathering lamp with a monitoring system, comprising:

a housing unit having a lower cover disposed in a vertical direction, the lower cover having a lower cover ring side portion and a lower cover bottom portion disposed at an end edge of the lower cover ring side portion;

a lens arranged at the side part of the lower cover ring;

a light source unit arranged at the bottom of the lower cover along the vertical direction; and

and the waterproof unit is arranged on the lower cover and used for coating the lens or the light source unit and providing water pressure protection.

a lens arranged at the side part of the lower cover ring;

a light source unit disposed in the housing unit;

the waterproof unit is arranged on the shell unit and used for coating the lens or the light source unit and providing water pressure protection; and

and the anti-collision unit is arranged on the side part of the lower cover ring and used for protecting the lens and the light source unit.

The number of the lenses is more than four, each lens has an object side direction, each lens is arranged around the side part of the lower cover ring, and the included angle between the object side direction of each lens and the object side direction of the lens adjacent to the object side direction in the horizontal radial direction is 360 degrees/number of lenses.

Further, the number of the lenses is more than four, each of the lenses has an object side direction, each of the lenses is disposed around a side portion of the lower cover ring, and an included angle between the object side direction of each of the lenses and the object side direction of the lens adjacent to the object side direction of the lens in the vertical direction is 20 to 45 degrees.

Further, the light source unit has a heat sink and a lamp panel, the heat sink is disposed on the lower cover, the lamp panel is disposed on the heat sink and has a plurality of light emitting diodes, the light source unit further has a telephoto lens disposed on the lamp panel, each light emitting diode emits a projection direction, and the collected light converged by the telephoto lens in each projection direction has a light condensing angle of 15 to 30 degrees.

Further, the lower cover surrounds the lens and the light source unit and is respectively provided with a glue injection groove in a concave mode, the waterproof unit is provided with a transparent cover, the transparent cover is provided with a combination portion connected with the lower cover, the combination portion is arranged on the lower cover in a combined mode and seals the glue injection groove to form a cavity, and waterproof glue is filled into the cavity so as to be suitable for the environment with the water depth of 300 meters.

Further, wherein, the bottom surface of the glue injection groove surrounding the lens is convexly provided with an annular rib, the transparent cover abuts against the annular rib to divide the cavity into an outer cavity and an inner cavity, the waterproof unit is provided with a gasket, a transparent cover pressing plate and a screw locking piece, the gasket is arranged on the annular rib and is positioned between the transparent cover and the annular rib, the transparent cover pressing plate is arranged on the transparent cover and is provided with a glue filling hole, the transparent cover pressing plate seals the outer cavity and defines an annular cavity with the transparent cover, the transparent cover is concavely provided with a flow passage, the glue filling hole is communicated with the outer cavity, the flow passage and the annular cavity, and the screw locking piece locks the transparent cover pressing plate, the transparent cover and the gasket on the lower cover.

Further, the cavity surrounding the light source unit is a concave annular cavity.

Furthermore, the housing unit further has a switching cover connected with the lower cover, the switching cover is provided with a heat sink, the switching cover is provided with an image processing module, and the image processing module is connected with the lens.

Furthermore, the other end of the shell unit opposite to the lower cover is provided with an upper cover, the upper cover is provided with a handle, the handle is provided with a rope for connecting a fishing boat, and the handle is further provided with a coaxial cable arranged on the handle by a wire pressing plate.

Further, the composite cable is an optical fiber.

Furthermore, the other end of the housing unit opposite to the lower cover is provided with an upper cover, the upper cover is provided with a handle, and the upper cover is provided with a sensing unit.

Further, the sensing unit has a temperature sensor, a depth sensor, a direction sensor, a salinity sensor and a turbidity sensor.

Further, the housing unit has a switching cover connected to the lower cover, the anti-collision unit has a plurality of brackets and a connecting ring, each bracket is connected to the lower cover and extends in a direction opposite to the switching cover, and the connecting ring is connected to the other end of each bracket opposite to the lower cover.

Further, an AI living body and fish species identification system is built in the housing unit.

Further, the housing unit further has a switching cover connected to the lower cover, a lower cover glue groove is formed on one surface of the lower cover connected to the switching cover, the switching cover is connected to and seals the lower cover glue groove to form a lower cover cavity, and a waterproof glue is filled in the lower cover cavity.

Furthermore, the shell unit is further provided with a switching cover connected with the lower cover, the lower cover is provided with a lower cover inner wall surface, a middle cover is fixedly arranged in the switching cover and provided with a middle cover surrounding wall and a middle cover sealing wall, the middle cover sealing wall is annularly abutted against the lower cover inner wall surface, an annular cavity is defined between the middle cover surrounding wall and the lower cover inner wall surface, and waterproof glue is filled in the annular cavity.

Furthermore, the lower cover is provided with a lower cover glue filling hole communicated with the annular cavity in a penetrating way.

Further, the housing unit further has an adapter cover connected to the lower cover and an upper cover connected to the adapter cover, and the lengths of the upper cover, the adapter cover and the lower cover in the vertical direction are within 400 mm, and the diameter of the housing unit is within 250 mm.

Further, the light source unit has a projection direction, the lens has an object-side direction, and the object-side direction and the projection direction do not intersect

The light source unit and the lens are protected by the waterproof unit, so that when the fish gathering lamp with the monitoring system enters a deep sea area and bears water pressure, seawater can be prevented from permeating into the shell unit, and the lens and the light source unit are prevented from being damaged due to dampness.

Drawings

FIG. 1 is a perspective view of a preferred embodiment of the present invention.

Fig. 2 is an exploded perspective view of the lower cover and the waterproof unit.

Fig. 3 is a perspective sectional view and a partial enlarged view of the lower cover at the position where the lens is provided.

Fig. 4 is a plan sectional view of the lower cover.

Fig. 5 is a plan sectional view of the lens and the waterproof unit.

Fig. 6 is a bottom view of the housing unit.

Fig. 7 is an exploded perspective view of the lower cover and the light source unit.

Fig. 8 is a partial enlarged view of fig. 5.

Fig. 9 is a perspective view from another perspective of the present invention.

Fig. 10 is a plan partial sectional view of the adaptor cover, the lower cover, and the middle cover.

Fig. 11 is a partial plan sectional view of the upper cover.

FIG. 12 is a perspective view of another embodiment of the present invention.

Detailed Description

Before beginning the detailed description of the invention, reference will first be made explicitly to the accompanying drawings in which:

a housing unit 10; a lower cover 11; a lower cover annular side portion 111; a lower cover bottom 112; a lower cover surrounding wall 113; a camera hole 1131; a lower cover inner wall surface 1132; a lower cover glue filling hole 1133; a lower cover space 114; a glue injection groove 115; a cavity 116; an outer cavity 116A; an inner cavity 116B; a concave annular cavity 116C; an annular rib 117; a lower cap glue groove 118; a lower cap cavity 118A; an adaptor cover 12; adaptor cover surrounding wall 121; the adaptor cap space 122; an image processing module 145; a switch wall 124; adaptor cover ring sides 125; upper cover 13 upper cover surrounding wall 131; an upper cover space 132; a handle 133; a composite cable wire 134; a protective cap 135; an inflow hole 1351; a protective space 136; a circuit board 137; a cover glue slot 138; an upper cover cavity 138A; an upper cover wall 139; a middle cap 14; the middle lid surrounds the wall 141 middle lid sealing wall 142; an annular cavity 143; middle cover glue filling hole 144; a housing interior cavity 15; a lens 20; an object-side direction 21; a half viewing angle 211; a light source unit 30; a heat sink 31; a lamp panel 32; a light emitting diode 321; a telephoto lens 33; a waterproof unit 40; a transparent cover 41; a combining section 411; a light-transmitting portion 412; the ring cavity 413; a flow passage 414; a spacer 42; a transparent cover pressing plate 43; glue holes 431; a screw locking member 44; a collision avoidance unit 50; a bracket 51; a connecting ring 52; a sensing unit 60; a temperature sensor 61; a depth sensor 62; a direction sensor 63; a salinity sensor 64; a turbidity sensor 65; a sensor processing unit 66; a side light source 70; an upper cover lens 80; a seal ring 91; a storage device 92; a battery 93; AI living body and fish species identification system 94; projection direction L1; light ray L2 is collected; a vertical direction Y; horizontal radial Ω; a light condensing angle theta 1; the angle θ 2.

Referring to fig. 1 to 11, the present invention is a fish gathering lamp with a monitoring system, comprising:

a housing unit 10 having a lower cover 11 disposed along a vertical direction Y, the lower cover 11 having a lower cover ring side portion 111 and a lower cover bottom portion 112 disposed at an end edge of the lower cover ring side portion 111; in the present embodiment, the housing unit 10 has a transition lid 12 connected to the lower lid 11, an end of the transition lid 12 opposite to the lower lid 11 is connected to an upper lid 13, a middle lid 14 is disposed in the transition lid 12, the lower lid 11 has a lower lid surrounding wall 113, the lower lid surrounding wall 113 surrounds a lower lid space 114, the lower lid side 111 has a plurality of camera holes 1131 communicating with the lower lid space 114, the transition lid 12 has a transition lid surrounding wall 121, the transition lid surrounding wall 121 surrounds a transition lid space 122, the upper lid 13 has an upper lid surrounding wall 131, the upper lid surrounding wall 131 defines an upper lid space 132, the middle lid 14 is disposed between the transition lid space 122 and the lower lid space 114, and the upper lid space 132 communicates with the transition lid space 122.

A lens 20 disposed on the housing unit 10, specifically, the lower cover ring side 111 of the housing unit 10; in this embodiment, the number of the lenses 20 is four, and each of the lenses 20 is disposed in the lower cover space 114 and extends out of each of the camera holes 1131, each of the lenses 20 has an object side direction 21 and a half viewing angle 211, the half viewing angle of the lens 20 is 90 degrees, each of the lenses 20 surrounds the lower cover ring side portion 111 of the lower cover 11 along a horizontal radial direction Ω, and an included angle between the object side direction 21 of each of the lenses and the object side direction of the lens adjacent to the object side direction in the horizontal radial direction Ω is 90 degrees in the horizontal radial direction Ω, which is beneficial to reducing a dead angle of a monitoring system and achieving an effect of monitoring the horizontal radial direction Ω 360 degrees.

A light source unit 30 disposed on the housing unit 10, specifically, the bottom 112 of the lower cover of the housing unit 10; in this embodiment, the light source unit 30 has a heat sink 31 and a lamp panel 32, the heat sink 31 is disposed on the bottom 112 of the lower cover 11, the lamp panel 32 is disposed on the heat sink 31 and has a plurality of leds 321, and particularly, the light source unit 30 further has a diverging lens 33 disposed on the lamp panel 32, each led 321 respectively emits a projection direction L1, and the collected light L2 collected by the projecting direction L1 through the diverging lens 33 has a light collection angle θ 1 of 15 degrees to 30 degrees, which is beneficial to monitoring fish schools in deeper sea areas below. The high-beam lens can replace the light-dispersing lens to increase the angle of projection light-gathering, which is beneficial to monitoring fish school near the fish gathering lamp.

A waterproof unit 40 disposed on the lower cover 11 for covering the lens 20 or the light source unit 30 and providing water pressure protection; and

an anti-collision unit 50 disposed on the lower cover ring side 111 for protecting the lens 20 and the light source unit 30; in the embodiment, the crash prevention unit 50 has a plurality of brackets 51 and a connection ring 52, each bracket 51 is connected to the lower cover 11 and extends in a direction opposite to the direction of the adaptor cover 12, and the connection ring 52 is connected to the other end of each bracket 51 opposite to the lower cover 11.

Preferably, referring to fig. 1 and fig. 4, the lower cover surrounding wall 113 and the vertical direction Y form an angle θ 2, such that the end of the lower cover surrounding wall 113 connected to the adaptor cover 12 extends to the end provided with the light source unit 30 and tapers, and each of the lenses 20 is obliquely disposed on the lower cover 11 along the lower cover surrounding wall 113, an included angle between the object side direction 21 of each of the lenses 20 and the object side direction 21 of the lens adjacent to the lens in the vertical direction Y is 20 to 45 degrees, which is beneficial to reducing dead angle of the monitoring system to achieve the effect of monitoring a vertical viewing angle Y of 270 degrees to 320 degrees, and the included angle in this embodiment is 25 degrees.

Next, a glue injection groove 115 is respectively recessed on the lower cover 11 around the lens 20 and the light source unit 30, the waterproof unit 40 has a transparent cover 41, the transparent cover 41 has a combination portion 411 annularly connected to the lower cover 11 and a transparent portion 412 connected to the combination portion 411 and transparent, the combination portion 411 is assembled on the lower cover 11 to close the glue injection groove 115 and form a cavity 116, the cavity 116 is filled with a waterproof glue, the object side direction 21 of each lens 20 is toward the transparent portion 412 for shooting, the light source unit 30 irradiates toward the transparent portion 412, and the projection direction L1 completely passes through the transparent portion 412.

Preferably, as shown in a and B of fig. 3, wherein B of fig. 3 is a partially enlarged view of a. The lower cover 11 is provided with a ring rib 117 protruding from the bottom surface of the glue injection groove 115 surrounding the lens 20, the combination part 411 of the transparent cover 41 is assembled in the glue injection groove 115 and divides the cavity 116 into an outer cavity 116A and an inner cavity 116B, the waterproof unit 40 is provided with a gasket 42, a transparent cover pressing plate 43 and a screw locking piece 44, when assembling, the inner cavity 116B is filled with waterproof glue, so that the surrounding wall 113 of the lower cover is glued with the transparent cover pressing plate 43; the gasket 42 is disposed on the annular rib 117 and located between the transparent cover 41 and the annular rib 117, the transparent cover pressing plate 43 is disposed on the transparent cover 41 and has a glue filling hole 431, the transparent cover pressing plate 43 seals the outer cavity 116A, a ring cavity 413 is concavely disposed between the combining portion 411 and the light-transmitting portion 412 of the transparent cover 41, the transparent cover pressing plate 43 covers the ring cavity 413, a flow channel 414 is concavely disposed on the combining portion 411 of the transparent cover 41, the glue filling hole 431 is communicated with the outer cavity 116A, the flow channel 414 and the ring cavity 413, and a waterproof glue can be injected through the glue filling hole 431, so that the waterproof glue flows from the flow channel 414 to the outer cavity 116A and the ring cavity 413, thereby filling the outer cavity 116A and the ring cavity 413, and the screw 44 locks and fixes the transparent cover pressing plate 43, the transparent cover 41 and the gasket 42 to the lower cover 11.

Preferably, as shown in fig. 5 and 8, the cavity of the waterproof unit 40 for the light source unit 30 is a concave annular cavity 116C, which is designed to increase the surface area and form a concave annular structure to facilitate the assembly and protect the pressure of deep sea water, so as to achieve the waterproof effect of the same volume assembly as the waterproof unit 40 for the gasket 42, the outer cavity 116A and the inner cavity 116B of the lens 20.

Furthermore, an image processing module 145 is disposed on the adapter cover 12, and the image processing module 145 is electrically connected to each of the lenses 20, so that the images captured by each of the lenses 20 are transmitted to the image processing module 145 for information integration.

Preferably, a U-shaped handle 133 is disposed on the upper cover 13, a rope is disposed on the handle 133 for connecting to a fishing boat, a composite cable 134 is disposed on the handle 133 by a wire pressing plate, and the composite cable 134 can be an optical fiber, so as to facilitate real-time transmission of a large number of signals to the fishing boat at a depth of 200-300 m.

Specifically, as shown in fig. 11, the upper cover 13 is provided with a sensing unit 60, the sensing unit 60 has a temperature sensor 61, a depth sensor 62, a direction sensor 63, a salinity sensor 64, a turbidity sensor 65 and a sensor processing unit 66, the temperature sensor 61 can sense the temperature in the seawater under the environment with the water depth of 50-300 meters, the depth sensor 62 can sense the seawater depth of 50-300 meters, the direction sensor 63 can monitor the orientation of the fish gathering lamp with the monitoring system in the sea under the environment with the water depth of 50-300 meters, the salinity sensor 64 can monitor the salinity in the water under the environment with the water depth of 50-300 meters, and the turbidity sensor 65 can monitor the turbidity degree in the water under the environment with the water depth of 50-300 meters.

Preferably, the upper cover 13 is provided with a protective cover 135, a protective space 136 is formed between the protective cover 135 and the upper cover 13, the temperature sensor 61, the salinity sensor 64 and the turbidity sensor 65 are arranged in the protective space 136, waterproof glue is filled in the protective space 136, the protective cover 135 is provided with an inflow hole 1351, and the inflow hole 1351 allows seawater to contact with the temperature sensor 61 and the depth sensor 62 for sensing; the direction sensor 63, the salinity sensor 64 and the turbidity sensor 65 are disposed between the upper cover 13 and the protection cover 135 to be in contact with seawater, the sensor processing unit 66 is disposed on a circuit board 137, and the temperature sensor, the depth sensor 62, the direction sensor 63, the salinity sensor and the turbidity sensor are electrically connected to the sensor processing unit 66 respectively, and the sensor processing unit 66 processes and stores signals of the sensors.

It should be noted that, as shown in fig. 10 and fig. 11, a concave upper cap glue groove 138 is disposed on a surface of the upper cap 13 connected to the adaptor cap 12, the adaptor cap 12 connected to the upper cap 13 closes the upper cap glue groove 138 to form an upper cap cavity 138A, the upper cap cavity 138A is also designed in a concave ring shape and is filled with a waterproof glue, and a convex adaptor boss 124A is disposed on a surface of the adaptor cap 12 connected to the upper cap 13, a convex upper cap boss 139 is disposed on a surface of the upper cap 13 connected to the adaptor cap 12, the adaptor boss 124 is sleeved with a sealing ring 91, and the upper cap boss 139 is sleeved with a sealing ring 91, when the adaptor cap 12 is locked with the upper cap 13, the matching of the concave ring design and the two sealing rings 91 is favorable for preventing seawater from permeating into the components with larger volume, such as the housing unit 10, between the upper cap 13 and the adaptor cap 12, so as to provide better sealing effect; one side of the lower cap 11 connected to the adapting cap 12 has a lower cap glue groove 118, the adapting cap 12 is connected to and seals the lower cap glue groove 118 to form a lower cap cavity 118A, the lower cap cavity 118A is also designed as a concave ring and is filled with a waterproof glue, one side of the adapting cap 12 connected to the lower cap 11 is convexly provided with an adapting wall 124B, and the adapting wall 124B is sleeved with two sealing rings 91, thereby preventing moisture from permeating into the housing unit 10 from between the lower cap 11 and the adapting cap 12.

Specifically, as shown in fig. 10, 2 and 3 a, the lower surrounding wall 113 has a lower inner wall 1132 facing the lower space 114, the middle lid 14 has a middle surrounding wall 141 and a middle sealing wall 142, one end of the middle surrounding wall 141 is connected to the middle sealing wall 142, one side of the middle sealing wall 142 is connected to the middle surrounding wall 141, the other side of the middle sealing wall 142 abuts against the lower inner wall 1132 (as shown in fig. 5), so that an annular cavity 143 is defined between the middle surrounding wall 141 and the lower inner wall 1132, and the lower lid 11 is provided with a plurality of lower potting holes 1133 communicating with the annular cavity 143, so that the annular cavity 143 is filled with waterproof glue through each of the lower potting holes 1133.

Specifically, the middle cap 14 is provided with a middle cap glue filling hole 144 communicating with the upper cap space 132, so that the middle cap glue filling hole 144 can be filled with waterproof glue, so as to fill the upper cap space 132 with waterproof glue.

The length of the housing unit 10 in the vertical direction Y is within 400 mm, and the diameter of the housing unit 10 is within 250 mm; the preferable size is that the length of the housing unit 10 in the vertical direction Y is within 330 mm, and the diameter of the housing unit 10 is within 230 mm, so that the housing unit 10 is not easily disturbed by sea currents when it penetrates into the sea water due to its small volume.

Preferably, the lower cover space 114, the adapting cover space 122 and the upper cover space 132 together form an inner housing cavity 15, and the inner housing cavity 15 is filled with a waterproof glue, thereby preventing seawater from penetrating into the housing unit 10.

In the latter case, the light source unit 30 has the projection direction L1, and the object-side direction 21 does not intersect with the projection direction L2, so as to prevent the light of the light source unit 30 from interfering with the shooting sight of each lens 20. Therefore, the projection direction of all light sources is different from the object side direction of all lenses, which is beneficial to preventing the lenses from being affected by the strong light emitted by the adjacent light sources in the same direction to cause light damage.

Finally, the housing unit 10 is installed with a storage device 92, a battery 93 and an AI living body and fish type identification system 94, so that the images processed by the image processing module 145 can be stored in the storage device 92, the battery 93 is used for storing power, the AI living body and fish type identification system 94 is electrically connected with the image processing module 145, and the image processing module 145 is matched with the AI living body and fish type identification system 94, so that the fish type photographed by each lens 20 can be identified in time.

In the above structural configuration and connection relationship of the present invention in a preferred embodiment, the structure of the present invention can achieve the following effects:

referring to fig. 6, in the present embodiment, four lenses 20 are disposed on the lower cover ring side 111 of the housing unit 10 at equal intervals along the horizontal radial direction Ω, and the half-viewing angle 211 of each lens 20 is 90 degrees, so as to achieve monitoring at the horizontal radial direction Ω, and facilitate capturing the image of the collision avoidance unit 50, and reduce dead angles of the image.

Referring to fig. 5, since the light source unit 30 further includes the far-reaching lens 33 disposed on the lamp panel 32, the light rays are converged by the far-reaching lens 33, so that the projection direction L1 emitted by each of the light emitting diodes 321 is converged into the converged light ray L2, which can illuminate farther and deeper, and is beneficial to monitoring fish schools in deeper sea areas.

In use, the fish gathering lamp with the monitoring system of the present invention is generally thrown into the sea, the upper cover 13 faces the sea surface, the lower cover 11 faces the sea bottom, and the collision avoidance unit 50 can first receive a collision if the fish gathering lamp with the monitoring system encounters a reef or a fish during the process of sinking, thereby preventing the housing unit 10, the lens 20 or the light source unit 30 from directly receiving the collision and further preventing the damage caused by the collision.

The lenses 20 are obliquely disposed on the lower cover 11 along the lower cover surrounding wall 113, so that the images captured by the lenses 20 can be computed by the image processing module 145 to provide nearly full-view image monitoring and remove the images of the collision avoidance unit 50 captured by the lenses 20.

The cavity 116, the outer cavity 116A, the inner cavity 116B, the annular cavity 413, the concave annular cavity 116C, the upper cover cavity 138A, the lower cover cavity 118A, the annular cavity 143, the upper cover space 132 and the inner shell cavity 15 are filled with waterproof glue, so as to prevent seawater from permeating into the shell unit 10, and the waterproof glue can prevent seawater from permeating, and further improve the water pressure that the fish gathering lamp with the monitoring system can bear in deep sea, and is connected with the radiator 31 and the image processing module 145, so that the temperature of the image processing module 145 can be reduced, and further the image processing module 145 can be prevented from being damaged.

The temperature sensor 61, the depth sensor 62, the direction sensor 63, the salinity sensor 64 and the turbidity sensor 65 are arranged in the invention and used for detecting environmental information under a water depth environment of 50-300 meters so as to assist in searching for specific types of fish schools.

Referring to fig. 12, in another embodiment, the adaptor cover 12 has an adaptor cover side 125, a plurality of side light sources 70 are disposed on the adaptor cover side 125 along the horizontal radial direction Ω, the side light sources 70 are spaced at equal intervals, and the upper cover 13 further has an upper cover lens 80, so as to provide full-view images in seawater with a water depth of 200-300 m.

The foregoing describes a number of different embodiments in accordance with the present invention, in which the various features may be implemented in single or in various combinations. Therefore, the present invention is disclosed as illustrative embodiments which illustrate the principles of the present invention and should not be construed as limiting the invention to the disclosed embodiments. Furthermore, the foregoing description and the accompanying drawings are only illustrative of the present invention and are not intended to limit the present invention. Variations or combinations of the other components are possible without departing from the spirit and scope of the invention.

Claims

1. A fish gathering lamp with a monitoring system, comprising:

a lens arranged at the side part of the lower cover ring;

2. A fish gathering lamp with a monitoring system, comprising:

a lens arranged at the side part of the lower cover ring;

a light source unit disposed in the housing unit;

3. The fish gathering lamp with the monitoring system as claimed in claim 1 or 2, wherein the number of the lenses is more than four, each of the lenses has an object side direction, each of the lenses is disposed around a side portion of the lower cover ring, and an included angle between the object side direction of each of the lenses and the object side direction of the lens adjacent to the object side direction in the horizontal radial direction is 360 degrees/number of lenses.

4. The fish gathering lamp with monitoring system as claimed in claim 1 or 2, wherein the number of the lenses is more than four, each of the lenses has an object side direction, each of the lenses is disposed around a side portion of the lower cover ring, and an angle between the object side direction of each of the lenses and the object side direction of the lens adjacent to the object side direction in the vertical direction is between 20 and 45 degrees in the vertical direction.

5. The fish gathering lamp with the monitoring system as claimed in claim 1 or 2, wherein the light source unit has a heat sink and a lamp panel, the heat sink is disposed on the lower cover, the lamp panel is disposed on the heat sink and has a plurality of light emitting diodes, the light source unit further has a telephoto lens disposed on the lamp panel, each light emitting diode emits a projection direction, and the collected light from each projection direction through the telephoto lens has a light collection angle of 15 degrees to 30 degrees.

6. The fish gathering lamp with monitoring system as claimed in claim 1 or 2, wherein the lower cover has a glue injection groove around the lens and the light source unit, and the waterproof unit has a transparent cover with a combination part connected to the lower cover, the combination part is assembled on the lower cover to close the glue injection groove and form a cavity, and the cavity is filled with a waterproof glue suitable for an environment with a water depth of 300 m.

7. The fish lamp with monitoring system as claimed in claim 6, wherein the bottom of the glue-injecting groove surrounding the lens has a protruding ring rib, the transparent cover abuts against the ring rib to divide the cavity into an outer cavity and an inner cavity, the waterproof unit has a gasket, a transparent cover pressing plate and a screw lock, the gasket is disposed on the ring rib and located between the transparent cover and the ring rib, the transparent cover pressing plate is disposed on the transparent cover and has a glue-injecting hole, the transparent cover pressing plate seals the outer cavity and defines a ring cavity with the transparent cover, the transparent cover has a recessed flow channel, the glue-injecting hole is communicated with the outer cavity, the flow channel and the ring cavity, and the screw lock locks the transparent cover pressing plate, the transparent cover and the gasket to the lower cover.

8. The fish gathering lamp with monitoring system as recited in claim 6 wherein the cavity surrounding the light source unit is a concave ring cavity.

9. The fish gathering lamp with the monitoring system as claimed in claim 1 or 2, wherein the housing unit further has an adapter cover connected to the lower cover, the adapter cover is provided with a heat sink, the adapter cover is provided with an image processing module, and the image processing module is connected to the lens.

10. The fish gathering lamp with the monitoring system as claimed in claim 1 or 2, wherein the housing unit has an upper cover at the other end thereof opposite to the lower cover, the upper cover has a handle, the handle has a rope for connecting a fishing boat, the handle has a composite cable line disposed thereon by a line pressing plate.

11. A fish gathering lamp as recited in claim 9 wherein the composite cable is an optical fiber.

12. The fish gathering lamp with the monitoring system as claimed in claim 1 or 2, wherein the housing unit has an upper cover at the other end opposite to the lower cover, the upper cover is provided with a handle, and the upper cover is provided with a sensing unit.

13. The fish gathering lamp with monitoring system as claimed in claim 1 or 2, wherein the sensing unit has a temperature sensor, a depth sensor, a direction sensor, a salinity sensor and a turbidity sensor.

14. The fish gathering lamp with the monitoring system as recited in claim 2, wherein the housing unit has a transition cover connected to the lower cover, the collision avoidance unit has a plurality of brackets and a connecting ring, each bracket is connected to the lower cover and extends in a direction opposite to the transition cover, and the connecting ring connects the other end of each bracket opposite to the lower cover.

15. The fish gathering lamp with the monitoring system as claimed in claim 1 or 2, wherein an AI living body and fish species recognition system is built in the housing unit.

16. The fish gathering lamp with the monitoring system as claimed in claim 1 or 2, wherein the housing unit further has an adapter cover connected to the lower cover, a surface of the lower cover connected to the adapter cover has a lower cover glue groove, the adapter cover is connected to and closes the lower cover glue groove to form a lower cover cavity, and the lower cover cavity is filled with a waterproof glue.

17. The fish gathering lamp with the monitoring system as claimed in claim 1 or 2, wherein the housing unit further has an adapter cap connected to the lower cap, the lower cap has an inner wall surface of the lower cap, a middle cap is fixedly installed in the adapter cap, the middle cap has a middle cap surrounding wall and a middle cap sealing wall, the middle cap sealing wall annularly abuts against the inner wall surface of the lower cap, so that an annular cavity is defined between the middle cap surrounding wall and the inner wall surface of the lower cap, and the annular cavity is filled with a waterproof adhesive.

18. The fish lamp with monitoring system of claim 22, wherein the lower cover has a lower cover glue filling hole communicating with the annular cavity.

19. The fish gathering lamp with the monitoring system as recited in claim 1 or 2, wherein the housing unit further has an adapter cover connected with the lower cover, and an upper cover connected with the adapter cover, and the upper cover, the adapter cover and the lower cover have a length in the vertical direction of 400 mm, and the housing unit has a diameter of 250 mm.

20. The fish gathering lamp with the monitoring system as recited in claim 1 or 2, wherein the light source unit has a projection direction, the lens has an object side direction, and the object side direction does not intersect with the projection direction.