CN213089484U - Industrial and mining lamp - Google Patents

Abstract

The utility model relates to an industrial and mining lamp, include: the battery bin comprises a bin body and a bin door; a first storage space and a second storage space are arranged in the bin body; the bin door is arranged to cover the first storage space; an emergency battery detachably disposed in the first storage space; the emergency power supply is arranged in the second storage space and is connected with the emergency battery; the light source component is connected with the emergency power supply to be connected into the emergency power supply under an emergency working condition and connected into a mains supply under a normal working condition; and the detection circuit is connected with the emergency power supply to detect whether the light source component operates normally regularly and/or irregularly by remote control. The mining lamp can simplify the emergency battery replacement and the light source assembly detection process, and saves labor cost.

Description

Industrial and mining lamp

Technical Field

The utility model relates to a lamps and lanterns, more specifically say, relate to an industrial and mining lamp.

Background

In the industrial and mining lamp on the market, an emergency power supply and a battery are fixedly arranged inside the lamp and cannot be replaced, the industrial and mining lamp does not have a detection function, and in addition, the industrial and mining lamp is generally applied to high-altitude places, and if the detection or replacement of the battery is needed, the whole lamp is required to be detached from a ground workbench to complete work. The service life of the battery of the lamp is not long, the battery or the whole lamp needs to be replaced after the mining lamp works to reach the service life of the battery, the working time of the whole process is long, the dismounting and mounting processes are complicated, the professional can work, and various cost expenses are high; in addition, the industrial and mining lamp cannot directly detect whether various functions of the emergency industrial and mining lamp working at high altitude are normal on the ground, the detection needs the high altitude operation of professional personnel, the workload of various regular detection is large, and the consumption of manpower and material resources is not economical.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model lies in that, a modified industrial and mining lamp is provided.

The utility model provides a technical scheme that its technical problem adopted is: constructing a mining lamp comprising:

the battery bin comprises a bin body and a bin door; a first storage space and a second storage space are arranged in the bin body; the bin door is arranged to cover the first storage space;

an emergency battery detachably disposed in the first storage space;

the emergency power supply is arranged in the second storage space and is connected with the emergency battery;

the light source component is connected with the emergency power supply to be connected into the emergency power supply under an emergency working condition and connected into a mains supply under a normal working condition;

and the detection circuit is connected with the emergency power supply to detect whether the light source component operates normally regularly and/or irregularly by remote control.

Preferably, the cartridge body comprises a first shell and a second shell which is arranged at one end of the first shell and connected with the first shell;

the first storage space is formed inside the first shell;

the second storage space is formed inside the second shell;

the bin gate and the first shell can be arranged in an opening and closing mode.

Preferably, one side of the bin door is provided with a hinge structure;

the bin gate and the first shell are rotatably connected through the hinge structure.

Preferably, the battery compartment further comprises a first waterproof sealing structure arranged on one side of the compartment door opposite to the compartment body so as to seal the compartment door and the first shell when the compartment door covers the first storage space.

Preferably, the device also comprises a heat dissipation shell,

the light source assembly is arranged on the heat dissipation shell;

the battery bin is arranged on one side, opposite to the light source component, of the heat dissipation shell;

the second storage space is arranged on one side of the battery compartment, which is opposite to the heat dissipation shell.

Preferably, a second waterproof sealing structure is arranged between the battery compartment and the heat dissipation shell.

Preferably, the heat dissipation shell is provided with an accommodating cavity for accommodating the light source assembly;

a lens is arranged on the heat dissipation shell and positioned in the light emitting direction of the light source component;

and a third waterproof sealing structure is arranged between the heat dissipation shell and the lens.

Preferably, the detection circuit comprises an automatic detection circuit which starts the emergency power supply at a set time to supply power to the light source assembly so as to detect whether the light source assembly normally operates under an emergency working condition;

and/or the mining lamp further comprises a remote controller connected with the emergency power supply;

the detection circuit comprises a remote control detection circuit which is connected with the remote controller and the emergency power supply so as to switch a power supply mode through the remote controller and detect whether the light source assembly normally operates under the emergency working condition.

Preferably, a first indicator light which is continuously turned on when the emergency battery supplies power to the light source assembly under the emergency working condition is arranged on the battery compartment;

and/or a second indicator light which indicates that the emergency battery is charging through flashing is arranged on the battery bin;

and/or a third indicator light for indicating that the emergency battery is fully charged is arranged on the battery bin.

Preferably, the light source assembly comprises a substrate and a plurality of LED lamp beads arranged on the substrate;

an interface is arranged on the battery bin;

and a transformer connected with the emergency power supply is arranged in the battery bin.

Implement the utility model discloses a mining lamp has following beneficial effect: this industrial and mining lamp can dismantle to set up in this first storage space to set up and connect the detection circuitry who carries out the detection to whether normal operating of light source subassembly in this emergency power supply, thereby can make things convenient for emergency battery's change, and can detect this light source subassembly regularly or through the remote control is indefinite, need not staff's high altitude construction, thereby can simplify emergency battery and change and light source subassembly detection process, practice thrift the cost of labor.

Drawings

The invention will be further explained with reference to the drawings and examples, wherein:

fig. 1 is a schematic structural view of a mining lamp according to some embodiments of the present invention;

FIG. 2 is a schematic view of the mining lamp of FIG. 1 in use;

FIG. 3 is an exploded view of the mining lamp of FIG. 1;

FIG. 4 is a cross-sectional view of the mining lamp of FIG. 1;

FIG. 5 is an automatic detection circuit of the mining lamp of FIG. 1;

fig. 6 is a remote detection circuit of the mining lamp of fig. 1.

Detailed Description

In order to clearly understand the technical features, objects, and effects of the present invention, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Fig. 1 shows some preferred embodiments of the industrial and mining lamp of the invention. The mining lamp can be applied to the production of high altitude such as factory buildings, production workshops and stations, and not only can be used for lighting under normal working conditions, but also can be used for lighting under emergency industrial and mining. The mining lamp is convenient to replace the battery, does not need to carry out high-altitude detection operation, and can save the labor cost.

As shown in fig. 1, the industrial and mining lamp may include a battery compartment 10, a heat-dissipating case 20, an emergency battery 30, an emergency power source 40, a light source assembly 50, and a detection circuit. The battery compartment 10 may be used to house an emergency battery 30 and an emergency power supply 40. The heat dissipation housing 20 can be used for mounting the battery chamber 10 and the light source assembly 50. In some embodiments, the battery chamber 10 and the light source assembly 50 can be disposed on the heat dissipation housing 20 opposite to each other, i.e., the battery chamber 10 can be disposed on one side of the heat dissipation housing 20, and the light source assembly 50 can be disposed on the other side of the heat dissipation housing 20. Specifically, in some embodiments, the battery chamber 10 can be disposed at the top of the heat dissipation housing 20, and the light source assembly 50 can be disposed at the bottom of the heat dissipation housing 20. The emergency battery 30 is detachably disposed in the battery compartment 10, and the emergency power source 40 is disposed in the battery compartment 10. This light source subassembly 50 can insert the commercial power under normal operating mode and carry out and emergency power source is inserted to emergent operating mode to can throw light on under normal operating mode and the emergent operating mode. The detection circuit may be connected to the emergency power supply 40, and may periodically detect whether the light source assembly is operating normally and/or may irregularly detect whether the light source assembly 50 is operating normally by remote control.

As shown in fig. 2 to 4, further, in some embodiments, the battery compartment 10 may include a compartment body 11 and a compartment door 12, the compartment body 11 may include a first shell 111 and a second shell 112; the first housing 111 can be connected to the second housing 112, and the first housing 111 and the second housing 112 can be integrally formed, specifically, in some embodiments, the first housing 111 and the second housing 112 can be integrally formed by injection molding. The first casing 111 is a hollow structure with an opening, the first casing 111 can be rectangular, and the side wall thereof can be opened with an opening. The second housing 112 may be a disk shape having a hollow structure with an opening at one side, and a top wall of the second housing 112 may be connected to the first housing 111. In some embodiments, a first storage space 1111 and a second storage space 1121 can be disposed in the cartridge body 11, and specifically, in some embodiments, the first storage space 1111 can be formed inside the first casing 111. In some embodiments, the second storage space 1121 can be formed inside the second housing 112 and located at a side of the battery compartment 10 opposite to the heat dissipation housing 20, and can be used for storing the emergency power 40. In some embodiments, a transformer 90 may be disposed in the battery compartment 10, and the transformer 90 may be located in the second storage space 1121 and may be connected to the emergency power source 40, and the transformer may be a 347V transformer or a 480V transformer. The door 12 is openable and closable with the first housing 111. In some embodiments, the door 12 may be rotatably connected to the first housing 111, and may cover the first storage space 1111, and the door 12 may have a rectangular shape. When the emergency battery 30 needs to be replaced, the door 12 can be opened to take out the emergency battery 30, and a new emergency battery can be put into the first storage space 1111.

Further, in some embodiments, the battery compartment 10 may further include a first waterproof sealing structure 13, and the first waterproof sealing structure 13 may be disposed on a side of the compartment door 12 opposite to the compartment body 11, and may be detachably connected to the compartment door 12. In some embodiments, the door 12 may be provided with a limiting groove for limiting the first waterproof sealing structure 13. In some embodiments, the first waterproof sealing structure 13 may be a waterproof sealing ring, which can seal the door 12 and the first housing 111 when the door 12 covers the first storage space 1111.

Further, in some embodiments, a hinge structure 14 is disposed on one side of the door 12, and the hinge structure 14 can be used to rotatably connect the door 12 and the first housing 111. The hinge structure 14 may include a first connection portion 141, a rotation shaft 142, and a second connection portion 143; the first connecting portion 141 may be disposed at one side of the door 12, the second connecting portion 143 may be disposed at one side of the first housing 111, and the rotating shaft 142 may be disposed in the first connecting portion 141 and the second connecting portion 143 to rotatably connect the first connecting portion 141 and the second connecting portion 143.

Further, in some embodiments, the door 12 and the first housing 111 may be fixed by a connecting assembly 15. In some embodiments, the connecting component 15 may be a screw, a screw hole is provided on one side of the first housing 111, a through hole is provided on one side of the door 12, and the screw passes through the through hole and into the screw hole to be screwed with the screw hole. After the mining lamp is installed, the screws can be directly loosened to open the bin door 12 of the emergency battery 30, the screws at two ends of the emergency battery 30 are taken down, and the emergency battery 30 can be replaced conveniently and quickly.

Further, in some embodiments, an interface 16 may be provided on the battery compartment 10. In some embodiments, the interface 16 may be disposed in the first storage space 1111 and connected to the emergency battery 30. In some embodiments, the interface 16 may be a conductive connection terminal that can be connected to an external power source via a connection wire. In some embodiments, the interface 16 may be a plurality of interfaces, which may be 480V,347V and 277V, wherein the 480V and 347V interfaces are connected to the corresponding wiring ports of the transformer 90, the transformer 90 is connected to the emergency power source 40 through wires, and the 277V interface may be directly connected to the port of the emergency power source 40

Further, in some embodiments, the heat dissipation housing 20 may include a first disk-shaped body 21, a second disk-shaped body 22, and a plurality of fins 23, and the first disk-shaped body 21 may be used for mounting the light source assembly 50. The second disk member 22 can be disposed on the first disk member 21 and spaced apart from the first disk member 21, and can be used for mounting the battery compartment 10. The plurality of fins 23 may be disposed between the first disk member 21 and the second disk member 22 at intervals, and connected to the first disk member 21 and the second disk member 22, respectively, and may be disposed along the circumferential direction of the first disk member 21 and the second disk member 22. The fins 23 may be used to dissipate heat from the light source assembly 50 and the emergency power supply 40. In some embodiments, the heat dissipation housing 20 may be provided with a receiving cavity for receiving the light source element 50, and the receiving cavity may be a ring cavity.

Further, in some embodiments, the emergency battery 30 may be a storage battery, which may be disposed in the first housing 111, and may be connected to the emergency power source 40, and may be connected to the interface 16, and may supply power to the light source assembly 50.

Further, in some embodiments, the light source module 50 may be a plurality of light source modules, which may be arc-shaped and may be spliced together to form a circular ring shape. The light source assembly 50 can be accommodated in the accommodating cavity of the heat dissipation housing 20. In some embodiments, the light source assembly 50 may include a substrate and a plurality of LED beads. The substrate can be an aluminum substrate, and the LED lamp beads can be arranged on the aluminum substrate at intervals.

Further, in some embodiments, a second waterproof sealing structure 60 may be disposed between the battery compartment 10 and the heat dissipation housing 20, and in particular, the second waterproof sealing structure 60 may be disposed between the second housing 112 and the second disk-shaped body 22 of the heat dissipation housing 20. The second waterproof sealing structure 60 can be used to waterproof seal the second housing 12 and the heat dissipation housing 20. In some embodiments, the second waterproof sealing structure 60 can be a second waterproof sealing ring, which can be a rubber ring, on the second disk-shaped body 22, and when the battery compartment 10 is assembled with the heat dissipation housing 20, it can prevent dust and water from entering the second storage space 1121 of the battery compartment 10.

Further, in some embodiments, a lens 70 may be disposed on the heat dissipation housing 20 in the light emitting direction of the light source assembly 50, and the lens 70 may transmit light emitted by the light source assembly 50. The lens 70 can be placed in the receiving cavity, and the lens 70 can include a plurality of arc-shaped lens units, which can be spliced together to form a ring structure and matched with the receiving cavity.

Further, in some embodiments, a third waterproof sealing structure 80 may be disposed between the heat dissipation housing 20 and the lens 70, and the third waterproof sealing structure 80 may be located in the receiving cavity and may be configured to hermetically connect the heat dissipation housing 20 and the lens 70, so as to prevent water and dust from entering the receiving cavity. In some embodiments, the third waterproof sealing structure 80 may be a third waterproof sealing ring, and specifically, the third waterproof sealing ring may be a silicone ring.

Further, in some embodiments, the mining lamp may further include a leading-out structure 100 for leading out the AC line 500, the leading-out structure may include an adapter 101, a tooth tube 102 connected to the adapter 101, the adapter 101 may be a hollow adapter nut, the adapter nut may be connected to the battery compartment 10, and the tooth tube 102 may be detachably connected to the adapter nut and is in communication with the adapter nut. The AC line 500 may exit the dental canal 102.

Further, in some embodiments, a first indicator light 201, a second indicator light 202 and a third indicator light 203 are further disposed on the battery compartment 10, the first indicator light 201 and the second indicator light 202 may be red indicator lights, and the third indicator light 203 may be green indicator lights, although it is understood that in other embodiments, the first indicator light 201 and the second indicator light 202 may be different colors. The first indicator light 201 can be continuously lit when the emergency battery 30 supplies power to the light source assembly 50 under the emergency condition. The second indicator light 202 may indicate by flashing to indicate that the emergency battery 30 is charging. The third indicator light may indicate that the emergency battery is fully charged. It is understood that in some embodiments, only the first indicator light 201, the second indicator light 202 or the third indicator light 203 may be disposed on the battery compartment 10.

Further, in some embodiments, the mining lamp may further include a hanging structure 300, specifically, the hanging structure 300 may be a hook, and the hook may be disposed on the battery compartment 10, which may facilitate hanging and hanging of the mining lamp. The hook can be detachably connected with the battery chamber 10. Aiming at the suspended application place, the screw thread at the lower end of the hook can be screwed into the top of the battery bin 10, and the screw thread of the hook is tightly locked by the screw to prevent the mining lamp from falling off. Aiming at the application place of pipe connection, the screw thread at the lower end of the adapter 101 can be screwed into the top of the battery bin 10, the tooth pipe 102 is screwed into the inner tooth at the upper opening of the adapter 101, the screw is locked to tightly push the tooth pipe 102, and the tooth pipe 102 is guaranteed not to slide.

Further, in some embodiments, the mining lamp may further include a safety rope 400, one end of the safety rope 400 may be fixed to the heat dissipation housing 30, and the other end may form a free end to be fixed to some mounting structure, such as a wall surface, so that the mining lamp may be protected during the installation process of the mining lamp, and the lamp may be prevented from falling. In some embodiments, the safety line 400 may be a steel wire rope.

In some embodiments, the mining lamp may further include a remote controller connectable to the emergency power supply 40 for remotely detecting the emergency power supply 40, and the detection circuit may include an automatic detection circuit and a remote detection circuit. The specific circuit principle of the automatic detection circuit can be seen in fig. 5, and the automatic detection circuit can be a conventional circuit, and can start the emergency power supply 40 at a set time to supply power to the light source assembly 50, so that whether the light source assembly 50 normally operates under emergency working conditions can be detected. If the light source assembly 50 is lighted, the light source assembly 50 normally operates under emergency conditions; specifically, the emergency power supply 40 may be switched into AC power and then the timer may be started, and if the light source unit 50 is not turned on, the light source unit 50, the battery pack 30, and the emergency power supply 40 may need to be manually checked. Through setting up this automatic check circuit, can be 5 minutes at the meeting automatic start emergency function of whole lamp after working 30 days, can 90 minutes at the meeting automatic start emergency function of whole lamp continuous operation 12 after 30 days, and then realize regularly detecting light source assembly 50 emergency state under emergent operating mode. In some embodiments, the specific circuit principle of the remote detection circuit can be seen in fig. 6, and the remote detection circuit can be a conventional circuit. This remote control detection circuitry can be connected with this remote controller and this emergency power source 40, through operating this remote controller, can manually switch over the power supply mode of this light source subassembly 50, and then can detect whether normal operating is under emergent operating mode to this light source subassembly 50. In some embodiments, the remote controller can be aligned to the remote control sensing receiving head below the mining lamp, the light source assembly 50 is powered off by manually operating the keys of the remote controller, the light source assembly 50 is powered by the emergency battery 30, the light source assembly 50 enters the emergency working condition, if the light source assembly 50 operates normally, the light source assembly 50 is lighted, the first indicator lamp is correspondingly lighted, and if the light source assembly 50 is not lighted, manual troubleshooting is required to be performed on the light source assembly 50, the emergency power supply 40 and the emergency battery 30. The remote controller key is manually operated to supply commercial power to the light source assembly 50, and the light source assembly 50 can be quitted from the emergency mode, so that the light source assembly 50 is turned off, and the emergency battery 30 is charged through the commercial power. The remote control detection circuit can be used for rapidly and conveniently performing random inspection on the mining lamp at irregular intervals, so that the detection work can be efficiently finished, and the labor cost is saved.

It is to be understood that the foregoing examples merely represent preferred embodiments of the present invention, and that the description thereof is more specific and detailed, but not intended to limit the scope of the invention; it should be noted that, for those skilled in the art, the above technical features can be freely combined, and several modifications and improvements can be made without departing from the concept of the present invention, which all belong to the protection scope of the present invention; therefore, all changes and modifications that come within the meaning and range of equivalency of the claims are to be embraced within their scope.

Claims (10)

1. A mining lamp, comprising:

the battery bin (10) comprises a bin body (11) and a bin door (12); a first storage space (1111) and a second storage space (1121) are arranged in the bin body (11); the bin gate (12) is arranged to cover the first storage space (1111);

an emergency battery (30) detachably disposed in the first storage space (1111);

an emergency power supply (40) disposed in the second storage space (1121) and connected to the emergency battery (30);

the light source component (50) is connected with the emergency power supply (40) so as to be connected into the emergency power supply (40) under an emergency working condition and connected into a mains supply under a normal working condition;

and a detection circuit connected to the emergency power supply (40) for periodically detecting and/or aperiodically detecting by remote control whether the light source assembly (50) is operating normally.

2. The mining lamp according to claim 1, wherein the cartridge body (11) comprises a first housing (111), and a second housing (112) disposed at one end of the first housing (111) and connected to the first housing (111);

the first storage space (1111) is formed inside the first housing (111);

the second storage space (1121) is formed inside the second housing (112);

the bin gate (12) and the first shell (111) can be arranged in an opening and closing mode.

3. The mining lamp according to claim 2, characterized in that one side of the bin door (12) is provided with a hinge structure (14);

the bin gate (12) is rotatably connected with the first housing (111) by the hinge structure (14).

4. The mining lamp according to claim 2, wherein the battery compartment (10) further comprises a first waterproof sealing structure (13) provided at a side of the compartment door (12) disposed opposite to the compartment body (11) to seal the compartment door (12) and the first housing (111) when the compartment door (12) covers the first storage space (1111).

5. The mining lamp of claim 1, further comprising a heat-dissipating housing (20),

the light source assembly (50) is arranged on the heat dissipation shell (20);

the battery bin (10) is arranged on one side, opposite to the light source component (50), of the heat dissipation shell (20);

the second storage space (1121) is disposed at a side of the battery compartment (10) opposite to the heat dissipation housing (20).

6. The mining lamp according to claim 5, characterized in that a second waterproof sealing structure (60) is provided between the battery compartment (10) and the heat-dissipating housing (20).

7. The mining lamp according to claim 5, wherein the heat-dissipating casing (20) is provided with a receiving cavity for receiving the light source assembly (50);

a lens (70) is arranged on the heat dissipation shell (20) and positioned in the light emitting direction of the light source component (50);

and a third waterproof sealing structure (80) is arranged between the heat dissipation shell (20) and the lens (70).

8. The mining lamp of claim 1, wherein the detection circuit comprises an automatic detection circuit that activates the emergency power supply (40) at a set time to power the light source assembly (50) to detect whether the light source assembly (50) is operating normally in an emergency condition;

and/or the mining lamp further comprises a remote controller connected with the emergency power supply (40);

the detection circuit comprises a remote control detection circuit which is connected with the remote controller and the emergency power supply (40) so as to switch a power supply mode through the remote controller and detect whether the light source assembly (50) normally operates under the emergency working condition.

9. The mining lamp according to claim 1, wherein the battery chamber (10) is provided with a first indicator lamp (201) which is continuously lighted when the emergency battery (30) supplies power to the light source component (50) under the emergency working condition

And/or a second indicator lamp (202) which indicates that the emergency battery (30) is charging through flashing is arranged on the battery bin (10);

and/or a third indicator light (203) for indicating that the emergency battery (30) is fully charged is arranged on the battery bin (10).

10. The industrial and mining lamp of claim 1, wherein the light source assembly (50) comprises a substrate and a plurality of LED beads disposed on the substrate;

an interface (16) is arranged on the battery bin (10);

and a transformer (90) connected with the emergency power supply (40) is arranged in the battery bin (10).

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