CN214475560U - Low-power consumption command signal lamp - Google Patents

Abstract

The utility model relates to a low power consumption command signal lamp, which comprises a lamp post, a storage battery, a solar cell panel and a control system; the lamp post is connected with a lamp body through a connecting rod, the lamp body comprises a plurality of LED light-emitting units, all the LED light-emitting units are coplanar and form a signal display surface, and the horizontal section of the signal display surface is an arc-shaped vertical cylindrical surface; the control system comprises an AIS unit, a radar, a processor and a controller, wherein the AIS unit and the radar are electrically connected with the processor, the processor and the storage battery are electrically connected with the controller, and the controller is electrically connected with the LED light-emitting unit. The utility model discloses, a plurality of LED luminescence unit splice into an curved light emitting area, make the signal lamp have wider visual angle, and control system only controls just to the work of a plurality of LED luminescence units of boats and ships, realizes guaranteeing that the signal lamp reduces the consumption of signal lamp when to boats and ships commander's effect to improve the electric power duration of signal lamp.

Description

Low-power consumption command signal lamp

Technical Field

The utility model belongs to the technical field of navigation ware traffic control on water, concretely relates to low-power consumption command signal lamp.

Background

Inland waters include rivers, lakes, reservoirs, artificial canals, channels and the like, and a channel for ship navigation in the inland waters is called an inland waterway; the inland waterway control river segment is also called as a restrictive waterway, namely a waterway which has obvious restriction effect on ship navigation due to narrow water surface, small section coefficient, sharp bend, rapid water flow and the like; such as canals, channels, narrow gated channels, narrow channels in water network areas, and dangerous beach channels having the above characteristics.

Because the risk that the ship navigates in the inland waterway control river reach is higher, the inland waterway control river reach can only navigate in one way generally, and when the ship navigates in the waterway, the ship navigates in general by using a map, a GPS and other aids, but the GPS and other tools can only guide the route, and the specific situation in the waterway cannot be completely predicted and avoided.

At present, a signal lamp arranged at a river section of an inland waterway for controlling a river section generally only passively provides a light signal at night, and the condition that a ship cannot be identified due to insufficient illumination often occurs, particularly in severe weather such as haze, sand storm, heavy rain, snowfall and the like; or a signal lamp similar to a road traffic command is used, the color identification degree of the signal lamp is high, the luminous intensity is good, but the luminous surface is a plane, and the visual angle is small; different from the situation that the signal lamp can directly face the direction of the coming vehicle when the vehicle runs on a road, the signal lamp for channel traffic command needs a wider visual angle and a longer visual distance, so that a plurality of ships with different directions in a part of river section area controlled by an inland waterway can receive command signals from the signal lamp; in addition, because the signal lamps arranged on the bank side of the inland waterway are required to be adjusted and maintained along with the fluctuation of water level, most of the current signal lamps adopt photovoltaic power supplies, and are not beneficial to the endurance of electric power of the signal lamps in rainy days for a long time, and the signal lamps have high luminous intensity and high power consumption; how to reduce power consumption and improve the cruising ability of the signal lamp is also a problem to be solved.

Disclosure of Invention

The above-mentioned not enough to prior art, the to-be-solved technical problem of the utility model is to provide a low-power consumption command signal lamp, solve the problem that the visual angle of present signal lamp is little to gain the stronger effect of signal lamp electric power duration.

In order to solve the technical problem, the utility model adopts the following technical scheme: a low-power consumption command signal lamp comprises a vertical lamp post, a storage battery for supplying power to the signal lamp and a solar cell panel for charging the storage battery; the LED lamp comprises a lamp post, a connecting rod, a lamp body and a signal display surface, wherein the connecting rod is arranged on one side of the lamp post, one end of the connecting rod is connected with the lamp post, the other end of the connecting rod is connected with the lamp body, the lamp body comprises a plurality of LED light-emitting units, all the LED light-emitting units are coplanar and form the signal display surface, and the signal display surface is a vertical cylindrical surface with an arc-shaped horizontal section so as to display command signals through a convex surface of the vertical cylindrical surface;

the signal lamp further comprises a control system, the control system comprises an AIS unit, a radar, a processor and a controller, the AIS unit and the radar are electrically connected with the processor, the processor and the storage battery are electrically connected with the controller, and the controller is electrically connected with the lamp body to control the LED light-emitting unit of the lamp body, which only correspondingly faces the ship, to light up.

In the utility model, the signal display surface is an arc-shaped luminous surface formed by splicing a plurality of LED luminous units, so that the signal lamp has a wider visual angle; during the use, the boats and ships are equipped with marine radar, ARPA automatic radar plotter and on-board AIS equipment, this AIS unit and radar signal detect connection boats and ships, a position information for exploring the boats and ships in the signal lamp irradiation range, the position of the relative signal lamp of boats and ships promptly, the treater is used for handling the boats and ships position information who comes from AIS unit and radar, the control signal who sends to the controller according to the position of the relative signal lamp of boats and ships, just to the work of a plurality of LED luminescence units of boats and ships in the control signal lamp, realize guaranteeing the signal lamp and when the boats and ships commander effect, reduce the consumption of signal lamp, in order to improve the electric power duration ability of signal lamp.

Further, the LED light-emitting unit is an LED screen or an LED lamp.

Therefore, the signal lamp has better identification degree due to good luminous effect and adjustable color of the LED screen and the LED lamp.

Furthermore, the number of the lamp bodies is a plurality of and the lamp bodies are arranged at intervals in the vertical direction, and the lamp bodies are connected to the lamp post through the connecting rods one to one.

Therefore, the signal display surfaces of the lamp bodies can simultaneously display the same command signals so as to enhance the visual range of the command signals, and can also simultaneously display different command signals so as to increase command information transmitted to a ship by the signal lamp; thereby increasing the use effect and flexibility of the signal lamp.

Furthermore, the lamp post is of a hollow cylinder structure, and one side of the lamp post is provided with a vertically extending opening;

but the lamp pole overcoat is equipped with vertical gliding sliding sleeve, the inboard of sliding sleeve has a traversing the opening is to the inside extension that extends of lamp pole, and all connecting rods all are connected with the lamp pole through the sliding sleeve.

Therefore, the signal display surface formed by splicing the LED light-emitting units is connected with the lamp post in a sliding manner through the sliding sleeve to realize vertical movement, and in the weather of strong wind or heavy rain, the signal lamp can be ensured to work stably by reducing the height of the signal display surface, so that the signal lamp is prevented from being damaged due to overlarge stress of the signal display surface; meanwhile, the extension part on the inner side of the sliding sleeve penetrates through the opening and extends to the inside of the lamp post, the opening can limit the range of vertical movement of the sliding sleeve along the vertical length, and the extension part is limited by the opening, so that the sliding sleeve can be prevented from rotating in the vertical movement process to change the orientation of a signal display surface, and further the signal lamp is influenced to transmit command information to a ship.

Further, the connecting rod can be horizontally and rotatably connected to the sliding sleeve.

Like this, drive the connecting rod level through corresponding the drive structure who sets up on the sliding sleeve and rotate, make the orientation of signal show face can adjust in a flexible way to the condition that the visual scope that the adaptation made the signal lamp needs the adjustment because of channel water level changes.

Furthermore, a driving chain wheel is arranged at the inner top of the lamp post, a driven chain wheel is arranged at the inner bottom of the lamp post, the driving chain wheel is connected with the driven chain wheel through a chain, and the chain is fixedly connected with the extending part.

Thus, the chain is respectively meshed with the driving chain wheel and the driven chain wheel, and the driving chain wheel rotates to drive the sliding sleeve to move up and down through the chain.

Further, the sliding sleeve outside is connected with horizontal backup pad, solar cell panel sets up in the backup pad.

Therefore, the solar cell panel rises and falls along with the signal display surface, so that the stress of the signal lamp on severe weather such as strong wind is further reduced, and the stability of the signal lamp is improved.

Compared with the prior art, the utility model discloses following beneficial effect has:

1. in the utility model, the signal display surface is an arc-shaped luminous surface formed by splicing a plurality of LED luminous units, so that the signal lamp has a wider visual angle; the control system only enables the plurality of LED light-emitting units which are over against the ship to work, so that the power consumption of the signal lamp is reduced while the command effect of the signal lamp on the ship is ensured, and the electric power endurance of the signal lamp is improved.

2. The utility model discloses in, the signal show face accessible sliding sleeve that splices into by a plurality of LED luminescence unit realizes vertical motion with the sliding connection of lamp pole, and in strong wind or rainy weather, the accessible reduces the height that the signal show face and guarantees the stable work of signal lamp, avoids appearing leading to the condition that the signal lamp damaged because of the too big atress of signal show face.

3. The utility model discloses in, drive the connecting rod level through corresponding the drive structure that sets up on the sliding sleeve and rotate, make the orientation of signal show face can adjust in a flexible way to the adaptation makes the condition that the visual scope of signal lamp needs the adjustment because of channel water level variation.

Drawings

Fig. 1 is a schematic perspective view of a low-power-consumption command signal lamp according to a first embodiment;

fig. 2 is a schematic front view of a low power consumption command signal lamp according to a first embodiment;

FIG. 3 is a block diagram of the control system according to an embodiment;

fig. 4 is a schematic structural diagram of a low-power consumption command signal lamp according to a second embodiment;

fig. 5 is a schematic structural diagram of a low-power consumption command signal lamp according to a third embodiment;

fig. 6 is a schematic structural diagram of a low power consumption command signal lamp according to a fourth embodiment;

fig. 7 is a schematic view illustrating the effect of the low power consumption command signal lamp of the present invention with a wider viewing angle;

FIG. 8 is an effect diagram of the low power consumption command signal lamp of the present invention illuminating the corresponding LED light-emitting unit in combination with the position of the ship;

the LED screen comprises a lamp post 1, an opening 11, a connecting rod 21, a supporting rod 22, an LED screen 3, a sliding sleeve 4, an extending portion 41, a winch 51, a traction rope 52, a driving chain wheel 53, a driven chain wheel 54, a ball screw 55, a nut 56, a chain 57, a supporting plate 6 and a solar cell panel 7.

Detailed Description

The following describes the present invention in further detail with reference to the accompanying drawings.

The first embodiment is as follows:

referring to fig. 1-3, a low power consumption command signal lamp includes a vertical lamp post 1, a storage battery (not shown) for supplying power to the signal lamp, and a solar panel 7 for charging the storage battery; a connecting rod 21 is arranged on one side of the lamp post 1, one end of the connecting rod 21 is connected with the lamp post 1, the other end of the connecting rod 21 is connected with a lamp body, the lamp body comprises a plurality of LED screens 3, all the LED screens 3 are coplanar and form a signal display surface, and the signal display surface is a vertical cylindrical surface with an arc-shaped horizontal section so as to display command signals through a convex surface of the vertical cylindrical surface;

in the embodiment, the LED light-emitting unit adopts the LED screens 3, the LED screens 3 can be mutually and fixedly connected and spliced to form an arc-shaped light-emitting surface, and the connecting rod 21 is fixedly connected with the plurality of LED screens 3;

during implementation, the LED light emitting unit may adopt an LED screen 3 or an LED lamp, the LED screen 3 or the LED lamp is fixedly connected to an arc-shaped fixing plate convenient for physical connection and electrical connection, and the connecting rod 21 is fixedly connected to the fixing plate.

The utility model discloses be the light emitting source that curved light emitting area comes as inland waterway control river reach current command signal lamp with the concatenation of a plurality of LED luminescence units, curved light emitting area makes the signal lamp have wider visual angle, and during the in-service use, the wider visual angle's of signal lamp effect please see figure 7.

Wherein, the signal lamp still includes control system, control system includes AIS unit, radar, treater and controller, the treater is connected to AIS unit and radar electricity, treater and battery electricity connection director, and the controller is connected with the lamps and lanterns body electricity and is lighted only corresponding LED screen 3 towards the boats and ships on combining the concrete position control lamps and lanterns body of boats and ships.

When the system is implemented, the AIS unit is composed of partial components of an AIS system, the aim is to realize that a signal lamp probes the position of a ship relative to the signal lamp in a certain range, the AIS unit and a radar are matched for use, the aim is to improve the accuracy and precision of probing the position of the ship, the AIS system is the prior art, namely an automatic ship identification system, which is a novel navigation aid system applied to maritime safety and communication between ships and banks and between ships, and the system is usually composed of a VHF communication machine, a GPS locator and a communication controller connected with a ship-mounted display, a sensor and the like, and can automatically exchange important information such as ship position, navigational speed, course, ship name, call sign and the like; the processor can be a controller with data processing and simple logic control functions, such as a single chip microcomputer.

In practice, the battery and controller may be located in or adjacent to the lamppost; AIS unit, radar and treater can be located in lamp pole 1 or by lamp pole 1, also can separate in the signal lamp setting, keep the treater with the signal connection of controller can to in protection AIS unit, radar and treater.

When the system is implemented, the control system only controls the LED screens 3 which are just opposite to the ship in the signal lamp to work, so that the power consumption of the signal lamp is reduced as much as possible while the command effect of the signal lamp on the ship is ensured, and the cruising ability of the signal lamp is improved; in actual use, please refer to fig. 8 for the effect when the LED screen 3 of the signal lamp just facing the ship is lighted.

During implementation, the starting rule of the signal lamp can be set in the processor, namely when the AIS unit and the radar probe that ships appear in the effective command range of the signal lamp, the signal lamp is started, the power consumption of the signal lamp is further reduced, the cruising ability is improved, and meanwhile, the service life of the LED screen 3 is prolonged.

During implementation, in order to increase the overall luminous intensity of the signal lamp and increase the command information transmitted by the signal lamp, the connecting rods 21 are two, the two connecting rods 21 are vertically arranged at intervals, and the tail ends of the connecting rods 21 are provided with arc-shaped luminous surfaces formed by splicing the LED screens 3.

During implementation, in order to improve the connection strength between the connecting rods 21 and the lamp post 1, a supporting rod 22 is further arranged below each connecting rod 21, one end of each supporting rod 22 is fixedly connected with the connecting rod 21 at a position close to the plurality of LED screens 3, and the other end of each supporting rod 22 is obliquely downwards connected with the lamp post 1.

Example two:

referring to fig. 4, the difference between the second embodiment and the first embodiment is: the lamp post 1 is of a hollow cylinder structure, and one side of the lamp post 1 is provided with a vertically extending opening 11; the lamp post 1 is sleeved with a sliding sleeve 4 capable of vertically sliding, the inner side of the sliding sleeve 4 is provided with an extending part 41 transversely penetrating through the opening 11 and extending towards the inside of the lamp post 1, and all the connecting rods 21 are fixedly connected with the sliding sleeve 4, so that the sliding connection between the connecting rods 21 and the lamp post 1 is realized;

during the implementation, for effective restriction sliding sleeve 4 takes place to rotate when vertical slip, avoid appearing making the light emitting area orientation of signal lamp change and lead to the condition that the signal lamp became invalid because of sliding sleeve 4 rotates, extension 41 is followed opening 11 width direction's size with opening 11's width equals or is close, two medial surfaces of opening 11 promptly with extension 41 side offsets or is close.

Wherein, the connecting rod 21 can be horizontally and rotatably connected on the sliding sleeve 4.

When in implementation, the sliding sleeve 4 is provided with a driving structure for driving the connecting rod 21 to horizontally rotate, and the driving structure can be a motor which is arranged on the sliding sleeve 4 and can drive the connecting rod 21 to horizontally rotate.

Wherein, the sliding sleeve 4 outside still is connected with horizontal backup pad 6, solar cell panel 7 sets up in backup pad 6.

Wherein, a lifting structure for driving the sliding sleeve 4 to slide up and down along the lamp post 1 is correspondingly arranged outside the lamp post 1 or inside the lamp post 1;

during implementation, the lifting structure is a small-sized winch 51 arranged at the inner top of the lamppost 1, the traction rope 52 of the winch 51 is fixedly connected with the extension part 41, and the traction rope 52 is retracted or released when the winch 51 works, so that the sliding sleeve 4 is driven to move up and down.

Example three:

referring to fig. 5, the difference between the third embodiment and the second embodiment is: when the lamp post is used, the lifting structure is a chain transmission structure arranged inside the lamp post 1, the top of the lamp post 1 is provided with the driving chain wheel 53, the bottom of the lamp post 1 is provided with the driven chain wheel 54, the driving chain wheel 53 is connected with the driven chain wheel 54 through the chain 57, one part of the chain 57 is fixedly connected with the extension part 41, and when the driving chain wheel 53 rotates to drive the chain 57 to rotate around the driving chain wheel 53 and the driven chain wheel 54, the chain 57 drives the whole sliding sleeve 4 to move up and down through the extension part 41. Thus, the chain is respectively meshed with the driving chain wheel and the driven chain wheel, and the driving chain wheel rotates to drive the sliding sleeve to move up and down through the chain.

Example four:

referring to fig. 6, the difference between the fourth embodiment and the second embodiment is: during implementation, elevation structure is vertical ball 55 in lamp pole 1 for setting up, ball 55's nut 56 with extension 41 fixed connection, lamp pole 1 inside or outside is equipped with the power supply that is used for driving ball 55, like the motor, the motor rotates and drives ball 55 and rotate, and nut 56 and extension 41 fixed connection are unable rotatory, and nut 56 drives sliding sleeve 4 through extension 41 and reciprocates. Like this, drive the lead screw through corresponding the drive structure who sets up in ball one end and rotate, because the nut with the extension is connected, and the extension receives the unable horizontal rotation of opening restriction to make when the lead screw rotates, the nut drives the sliding sleeve up-and-down motion.

Finally, although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the present invention can be modified or replaced by other means without departing from the spirit and scope of the present invention, which should be construed as limited only by the appended claims.

Claims (7)

1. A low-power consumption command signal lamp comprises a vertical lamp post, a storage battery and a solar cell panel for charging the storage battery; the method is characterized in that: the LED lamp comprises a lamp post, a connecting rod, a lamp body and a signal display surface, wherein the connecting rod is arranged on one side of the lamp post, one end of the connecting rod is connected with the lamp post, the other end of the connecting rod is connected with the lamp body, the lamp body comprises a plurality of LED light-emitting units, all the LED light-emitting units are coplanar and form the signal display surface, and the signal display surface is a vertical cylindrical surface with an arc-shaped horizontal section so as to display command signals through a convex surface of the vertical cylindrical surface;

the signal lamp further comprises a control system, the control system comprises an AIS unit, a radar, a processor and a controller, the AIS unit and the radar are electrically connected with the processor, the processor and the storage battery are electrically connected with the controller, and the controller is electrically connected with the lamp body to control the LED light-emitting unit of the lamp body, which only correspondingly faces the ship, to light up.

2. A low power consumption command signal lamp as claimed in claim 1, wherein: the LED light-emitting unit is an LED screen or an LED lamp.

3. A low power consumption command signal lamp as claimed in claim 1, wherein: the quantity of lamps and lanterns body is a plurality of and vertical interval sets up, and lamps and lanterns body is connected on the lamp pole through the connecting rod one to one.

4. A low power consumption command signal lamp as claimed in claim 3, wherein: the lamp post is of a hollow cylinder structure, and one side of the lamp post is provided with a vertically extending opening;

but the lamp pole overcoat is equipped with vertical gliding sliding sleeve, the inboard of sliding sleeve has a traversing the opening is to the inside extension that extends of lamp pole, and all connecting rods all are connected with the lamp pole through the sliding sleeve.

5. The low-power command signal lamp of claim 4, wherein: the connecting rod can be horizontally and rotatably connected to the sliding sleeve.

6. The low-power command signal lamp of claim 4, wherein: the lamp post is characterized in that a driving chain wheel is arranged at the inner top of the lamp post, a driven chain wheel is arranged at the inner bottom of the lamp post, the driving chain wheel and the driven chain wheel are connected through a chain, and the chain is fixedly connected with the extending part.

7. The low-power command signal lamp of claim 4, wherein: the sliding sleeve outside is connected with horizontal backup pad, solar cell panel sets up in the backup pad.

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