GB2466464A

GB2466464A - Wind powered hazard warning light

Info

Publication number: GB2466464A
Application number: GB0823302A
Authority: GB
Inventors: Wolfgang Gunther Schadeberg
Original assignee: Individual
Current assignee: Individual
Priority date: 2008-12-22
Filing date: 2008-12-22
Publication date: 2010-06-23
Also published as: GB0823302D0

Abstract

A self-contained wind powered hazard warning light comprising two concentric rings of Light Emitting Diodes forming a sphere shape, inside which is mounted a wind turbine, a rechargeable battery and control circuitry. A fin is placed on the edge of one of the rings/hoops, whilst a grab handle (containing a daylight sensor) is on the upper part of the sphere and a swivel joint on the lower part to allow the whole sphere to rotate on a supporting rod as directed by the wind pressure on the tail fin. The hazard warning light unit can be mounted on a supporting rod via internal swivel unit to allow a full 360 degree rotation. Function control is permitted via a bank of select switches.

Description

Table of contents

Hazard Light Unit 1) Form 1

2) Specification

3) claims 4) Abstract 5) Drawings Diagram 1 -Conceptual placement Diagram 2 -side view Diagram 3 -Front view Diagram 4 -Plan view

Specifications

Hazard Light Unit Diagrams 1, 2, 3 and 4 in Drawings section to accompany specification.

This invention relates to a self-contained, self-recharging device for emitting warning lights.

For those dangerous hazards that exist either as a temporary situation (such as a road traffic accident), semi-permanent situation (such as road works) or a permanent one (such as a radio mast) warning lights are erected to warn of their existance.

Traditional hazard lights have to have a direct feed to power the lights or contain sufficient battery charge to sustain operation for the period needed.

On permanent hazards extensive wiring may be required to provide permanent energy to warning lights.

It is often a tedious task to rechar9e sets of warning lights ready to replace those in place as their charge deminishes. In reality twice as many warning lights are required when the recharging method is being employed.

The hazard light unit described in this invention may be placed without consideration for power source or method of recharging internal batteries. Once placed the internal wind turbine ensures that the battery is sufficiently charged to emit the warning lights in the pattern required. The issues described with traditional hazard lights no longer exist.

When placed on a fixed hazard the very nature of the hazards situation (such as high up on top of a hill) ensures that there is enough wind available to provide sufficient charge for the batteries in the hazard light un-it.

When placed on a traffic cone passing traffic generate enou9h wind which is suitable to provide sufficient charge for the batteries in the hazard light Unit.

The hazard light unit may be placed for the duration, be it of a permanent or temporary nature, without consideration of charge. There is no need to have another unit on charge in readiness for replacement.

Refer to Drawings section for all diagrams.

Diagram 1 introduces the conceptual use of the hazard li9ht unit. In the upper part of the drawing the hazard li9ht module is placed on the supporting rod, which is in turn attached to a high tower, high building or any other remote, hazardous or inaccessable construction.

(Such placements would include marine and aircraft warning beacons.) In the lower part of the drawing the hazard light module is placed on the supporting rod, which is in turn attached via a collar to a traffic cone.

Refer to Diagrams 2, 3 and 4 for the following paragraphs.

The hazard light module is spherical with four hoops containing LED5 (light emitting diodes) running from the top pole to the bottom pole. (These may be conceptually regarded as four longitudinal lines around a globe.) On the upper part of the sphere there is a grab-handle that contains a daylight sensor. On one set of the hoops is a tail fin. On the lower part of the sphere is an embedded swivel that allows the whole sphere to rotate on the supporting rod as directed by the wind pressure on the tail fin.

within the sphere is the wind turbine, the electronic circuit board unit with switch bank and the rechargeable battery pack.

Contemporary LED5 (light emitting diodes) consume very little power, modern batteries hold their charge for very long periods and modern wind turbines provide suitable energy needs for the hazard light unit. The hazard light unit is able to operate almost indefinately on relatively little wind.

Drawings Hazard Light Unit 1) Diagram 1 introduces the conceptual use of the hazard light unit.

In the upper part of the drawing the hazard light module is placed on the supporting rod, which is -in turn attached to a high tower, high building or any other remote, hazardous or inaccessable construction. Such placements would include marine and aircraft warning beacons.

In the lower part of the drawing the hazard light module is placed on the supporting rod, which is -in turn attached via a collar to a traffic cone.

2) Diagram 2 is a side elevation view of the hazard light module.

The grab handle containing the daylight sensor is shown on the top of the hazard light module.

To the rear is the tail fin and internally are the wind turbine, the electronic circuit and the rechargable battery units. The switch bank is shown on the side of the electronic circuit unit. The lights are shown as LED (light emitting diodes) units and are placed on the outside citcumference of the external hoops. At the lower end of the hazard light unit is the swivel unit where the supporting rod -is inserted.

3) Diagram 3 is a front elevation view of the hazard light module.

The grab handle is shown on the top of the hazard light module. Internally are the wind turbine, the electronic circuit and the rechargable battery units. The lights are shown as LED (light emitting diodes) units and are placed on the outside citcumference of the external hoops. At the lower end of the hazard light unit is the swivel unit where the supporting rod is inserted.

4) Diagram 4 is a plan elevation view of the hazrd light module.

The grab handle containing the daylight sensor is shown -in the center of the hazard light module. To the right is the tail fin and internally are the wind turbine, the electronic circuit and the rechargable battery units. The lights are shown as LED (light emitting diodes) units and are placed on the outside citcumference of the external hoops.

Claims

Claims Hazard Light Unit 1) A self-contained, wind-rechargable hazard light unit comprising of daylight sensor, warning lights, electronic circuit, control switches, rechargable batteries and a wind turbine.
2) A hazard light unit according to claim 1 with a control switch that allows selectable operation for night-time or Continuous day and night operation.
3) A hazard light unit accordin9 to all preceeding claims with a control switch that allows selectable light emitting offering a choice between (but not limited to) short quick pulses and longer slower flashes.
4) A hazard light unit according to all preceeding claims with a control switch that allows selectable light colours offering choices such as (but not limited to) red, orange or blue.
5) A hazard light unit according to all preceeding claims with a control switch that allows selectable alternate light colours offering choices such as (but not limited to) red and blue.
6) A hazard light unit according to all preceeding claims with a control switch that allows selectable alternate light colours each with separate light pulsing frequencies offering choices such as (but not limited to) red at a slow pulse and blue on a quick strobe.