Background of the invention Rechargeable flashlights have been known for a considerable time. Disclosed in US patent 5847540 is a rechargeable flashlight having a plug unit supported in the flashlight housing for rotation between a non-charging position, in which blades of the plug unit are retracted into the housing, and a charging position in which the blades are projecting from the housing for insertion into an AC outlet. The plug unit co- operates with a switch unit in the housing for connecting a rechargeable battery to a bulb circuit and disconnecting the battery from a charging and indicating circuit when the plug unit is in the non-charging position. The switch unit also disconnects the battery from the bulb circuit and connects the battery to the charging circuit and indicating circuit when the plug unit is in the charging position. This document teaches that the plug unit can be rotated into and out of the body of the flashlight while remaining connected thereto.

Another flashlight is disclosed in US patent 4515790 which has a rechargeable power pack or cartridge which discloses a plug structure for use with standard electricity sockets or supply outlets, whereas the power cartridge also has a shape which allows the plug structure to be utilised for example with a cigarette lighter outlet of a motor vehicle so that the user has the option of recharging from either electricity supply outlets or from a cigarette lighter outlet of a motor vehicle or a boat.

The battery is removed from the flashlight as it is a part of the power pack for recharging purposes. The construction thus can result in the separation of the power pack from the flashlight during the recharging process, which will decrease the ready to use state of the flashlight by comparison to the flashlight disclosed in US patent 5847540.

The applicant does not concede that the prior art discussed above forms part of the common general knowledge in the art of the skilled addressee that the priority date of this application.

Summary of the invention The present invention provides a flashlight having: a body with a light means at one end, a battery, and a circuit therebetween, so that when said circuit is closed said light means will generate light; recharging terminals for recharging said battery and an adaptor having electrical connectors for connecting to a power supply; structural connection means on said body and or said adaptor to releasably connect said body and said adaptor; and electrical connection means on both said body and said adaptor to releasably electrically connect said terminals and said adaptor.

The adaptor and the body have said structural connection means disconnected in order for said electrical connection means to electrically connect said terminals and said adaptor.

The structural connection means can include a female portion on one of said body or said adaptor, with the other having a male portion. The female portion or said male portion when present on said body has said electrical connectors extending therefrom. The female portion or the male portion of said adaptor has said electrical connectors extending therefrom.

The female portion or male portion said body can include cavities to receive said electrical connectors.

The female portion or male portion of said adaptor can include cavities to receive said terminals.

The adaptor can be shaped so that when said structural connection means connect said body and said adaptor, said adaptor is of a shape which substantially matches the shape of said body in the vicinity of said adaptor.

The adaptor can be shaped so that when said structural connection means connects said body and said adaptor is the rear part of the body.

The adaptor can include a socket to receive said recharging terminals.

When said electrical connectors are in a power supply socket with a vertically oriented front face, said adaptor can have an upper face into which said rechargeable terminals are inserted, the upper face being at an angle to the horizontal so that a line normal to the upper face extends away from the adaptor on a divergent path away from the vertical.

The body can have a female portion and said adaptor can have a male portion.

The male portion can be of a shape and or size to fit between said recharging terminals.

The adaptor can include a hinged cover to overlay said electrical connection means on said adaptor.

The hinged cover can act to limit movement of said flashlight on said adaptor when they are electrically connected.

The present invention also provides a flashlight having a body with a light means at one end, a battery, and a circuit therebetween, so that when said circuit is closed said light means will generate light; said light means including a conical reflector, a white light LED emitting a conical light output and a double convex lens portion, said double convex lens portion being located away from said LED so that the outside diameter of said double convex lens portion will be struck by a circle of light from said LED which is of substantially the same diameter.

Around said double convex lens portion can be a straight sided lens. The straight sided lens and said double convex lens portion can be integrally formed in a single lens member.

A flashlight as claimed in any one of claims 28 to 30 wherein said light means produces a beam emitted from said flashlight which has four bands of differing light intensity.

Preferably there is a circular centre and at least three annular bands of light there around.

The circular centre preferably has the highest light intensity relative to said annular bands. The first band adjacent to said circular centre preferably has the lowest light intensity relative to said annular bands. The second band adjacent said first band preferably has a light intensity less than said circular centre but greater than said first

band. The third band adjacent said second band can have a light intensity less than said second band but greater than said first band.

Brief description of the drawings An embodiment of the present invention, will be described by way of example only, with reference to the accompanying drawings, in which: Figure 1 illustrates a perspective view of a rechargeable flashlight; Figure 2 illustrates a rear perspective view of the flashlight of figure 1 with the rear adaptor removed; Figure 3 illustrates a front perspective view of the rear adaptor of the flashlight of figure 1.

Figure 4 illustrates the flashlight of figure 1 mounted on the adaptor and positioned in an electricity socket; Figure 5 illustrates an adaptor similar to figure 3 with a cover in the open position.

Figures 6 and 7 illustrate perspective views of shutter members; Figure 8 illustrates the shutter member of figure 6 assembled into an adaptor; Figure 9 illustrates a perspective view of a flashlight body's end having three pins.

Figure 10 is a side elevation of figure 9; Figure 11 is a plan view of figure 9; Figure 12 is a cross section through the forward end of the flashlight of figure 1; and Figure 13 is a schematic representation of the light output of the lens assembly of figure 12.

Detailed description of the embodiments Illustrated in Figure 1 is a flashlight 10 which has a body 12 with a lens assembly 14 at its forward end. At the top of the body 12 is a three position switch 16 and a red LED 18 positioned behind the switch 16.

At the rear of the body 12 is located an adaptor 20. Illustrated in figure 3 the adaptor 20 has two electrical connectors 22 and 24 for insertion into a wall socket.

The format of the electrical connectors 22 and 24 are to suit the spacing and shape required for European wall sockets and it will be understood that the shape and spacing of these can be varied according to requirements in various countries around the world.

The connectors 22 and 24 extend away from a hexagonally shaped male portion 26 which has cut aways 28 and 30 on opposite sides leading to a recess 32 shown on the right side with a similar recess which is not visible on the left. (A left recess is visible in figure 5 and is labelled with the numeral 33. ) The right side 34 of the adaptor 20 as illustrated in figure 3 will become the upper surface of the adaptor 20 when the adaptor 20 is in use in a wall socket as illustrated in figure 4.

The side 34 has a rotating cover 36 which covers and protects the sockets 38 and 39 in the adaptor 20. In figure 5 the cover 36 is rotated to the open position.

As can be seen from figures 1 and 3, the shape of the adaptor 20 with the cover 36 closed, complements and finishes the rear of the flashlight body 12. The lines and starting point of the outward surfaces of the front 45 of the adaptor 20, blend with the lines and finishing point of the outward surfaces of the rear 40 of the flashlight body 12.

The rear 40 of the flashlight body 12 has a cavity 42, which has a complementary shaped hexagonal recess 43 to receive the hexagonal male portion 26 of the adaptor 20. The recess 43 receives the male portion 26 therein whilst the cavities 32 (and 33) at the sides of the hexagonal male portion 26 receive therein recharging terminals 44 and 46 which are of a generally cylindrical shape, and which project outwardly from the cavity 42. The hexagonal male portion 26 has shallow recesses 51 so that complementary shaped protrusions 53 on the cavity 42 can sit therein to lock the adaptor 20 and body 12 together, until sufficient force is applied to separate the two components.

While the above discussion and figs. 1,2, 3 and 4 utilise a recess 43 and male portion 26 which are generally hexagonal in shape, this hexagonal shape is only a preferment. As can be seen from figure 5, a different shaped male portion 26A is used.

As can be seen from figure 4, the side 34, when in situ in a wall socket is upwardly facing. It will also be noted from the side elevation of figure 4, that an imaginary line 48, which is normal or perpendicular to the side 34, divergently

extends away from the adaptor 20, at an angle 59 from the vertical 57 represented by the wall 50, to which the socket 47 is attached.

This angle 59 also has the same magnitude as the angle 61 which is the angle between the side 34 and the horizontal 63, as shown in figure 4.

The angles 59 and 61 are approximately 8'but can be in the range of 5° to 30°.

This angle allows the flashlight body, to rest on the adaptor 20 in an equilibrium condition due to the flashlight body 12 having a contoured forward end whereby the lighting means and lens assembly 14 are oriented at an angle to the longitudinal axis of the rest of the flashlight body 12. The cover 36 also opens outwardly to an angle of similar magnitude as angle 59, so as to provide support to the rear end 40 of the flashlight body 12, by engaging the face 33, which is located on the top (when the flashlight is in the orientation of figure 1) of the body 12. This helps to keep the flashlight 10 in position on the adaptor 20 and limits the movement which may separate the flashlight 10 from the adaptor 20. The movement is thus limited to a side to side movement, generally parallel to the wall 50 in which the power socket is located, and not toward or away from the wall 50.

Once the adaptor 20, is located in a power socket 71 which is then switched on, then the rechargeable batteries in the flashlight 10 will be recharged.

During recharging the LED 19 will switch on intermittently. Once full recharging has occurred, the LED will be lighted continuously.

Once recharging has occurred, the flashlight can be simply taken off the adaptor 20, and is useable without the adaptor 20 being reconnected to the rear of the flashlight.

However, for aesthetic purposes the adaptor 20 can be reconnected to the rear 40 of the body 12.

The two position switch 16 has an intermediate off position and a first on position which lights the lamp means with a low level current. The second on position will light the lamp means with a relatively high level current.

The lamp means is preferably provided by means of 1 or more LEDs.

By using LED's the flashlight will have a relatively long run time before the rechargeable batteries are drained.

Alternatively other type of lamp means can be utilised.

As can be seen in figure 2, the flashlight 10 has the two terminals 44 and 46 extending away from the rear thereof. The terminals 44 and 46 are mounted in and extend away from a plug member which is assembled, captured and held by the rear end of the flashlight 10 when it is assembled. However, in another embodiment, an alternative plug member 400 as illustrated in figure 9 to 11 can be utilised for assembly into, capture and holding by the rear end of the flashlight 10. The plug 400 includes the terminals 44 and 46, as well as an additional central pin 120. The pin 120 will prevent a terminal 44 or 46 from being inserted into an aperture 38 or 39 in such a manner that would otherwise have had the other terminal 46 or 44 exposed on the outside of the adaptor 20. The pin 120 performs this preventative task because unless the terminals 44 and 46 and pin 120 are aligned with apertures 38 and 39 and a third aperture 41 (see figure 5) then the terminals 44 and 46 will not individually be able to enter the adaptor 20.

Other means to prevent improper use can be provided such as shutters 100 and 130 in figures 6 and 7, which will now be described.

Illustrated in figure 6 is a shutter member 100 for use with a flashlight having a plug 400 of figures 9 to 11. The shutter 100 has two angled faces 102 and 104 at its ends. The angle on the faces 102 and 104 is approximately 45° to the base of the shutter 100. Between the angled faces 102 and 104 is a bight 106. The faces 102 and 104 will be engaged by terminals 44 and 46 on the flashlight 10, whereas the bight 106 can receive central third pin 120. Behind the bight 106 is a three sided recess 108 which has a central face 110. The face 110 and recess 108 receives the end of a compression spring 114 (see figure 8) and provides a bearing surface for the end of the spring 114 to push against.

The shutter member 100 can be made of injection moulded plastic and located or assembled in the adaptor 20 as illustrated in figure 8 so that the faces 102 and 104 overlie the contacts (no illustrated) which will be engaged by terminals 44 and 46. The shutter system 100 can be utilised with a flashlight similar to that of figure 2 having only two terminals (44 and 46) but it is thought to be best used with a flashlight having three pins: namely terminals 44 and 46 and central pin 120 (see figures 9,10 and 11).

The terminals 44 and 46 will pass through apertures 38 and 39 in the adaptor 20 while pin 120 will pass through a central aperture 41 (see figure 5 where it is indicated in dashed linework). The terminals 44 and 46 will engage the surfaces 102 and 104 respectively to thereby push the shutter 100 in a rearward direction 112 against the bias of the spring 114 which is illustrated in figure 8. As the shutter 100 moves in the direction of arrow 112 further pushing of the rear of the flashlight 10 towards the adaptor 20 will mean that the shutter 100 will move completely out of the way of the terminals 44 and 46 allowing the terminals 44 and 46 ultimately push past the shutter 100 so as to engage the contacts located below the shutter 100. As the terminals 44 and 46 are moving inward, the pin 120 will simultaneously pass through the central aperture 41 and into the bight 106 which will not interfere with the movement of the shutter 100 in the direction of 112.

When the terminals 44 and 46 push past the shutter 100 and engage the contacts below the shutter 100 the recharging process can begin once the adaptor 20 is inserted into a power socket, which can then be switched on.

Illustrated in figure 7 is another shutter 130 which has only a central angled face 132 (being at an angle of approximately 45'to the base of the shutter 130) and flat faces 134 and 136 on either side thereof. The shutter 130 operates in much the same manner as the shutter 100 except that the shutter 130 will move in the direction of arrow 112 only when the central pin 120 engages the angled face 132. Thus should the pin 120 fracture or otherwise break the terminals 44 and 46 will not cause the shutter 130 to move in the direction 112, as they will perpendicularly engage the flat faces 134 and 136, thereby preventing access to the contacts below the shutter 130.

Contrasted with this the shutter 100 of figure 6 will continue to perform even if the central pin 120 were not present, as the shutter 100 will still move in the rearward direction 112. Thus the shutter 130 is inherently better in operation than the shutter 100.

The central pin 120 if utilised with a shutter 100 serves the purpose of preventing the terminal 44 or 46 from being placed into one of the apertures 38 or 39 with the other terminal 46 or 44 being left in an exposed condition outside of the adaptor 20. However, in an embodiment which utilises the shutter 130, the central pin 120 has the additional purpose of moving the shutter 130 to its open condition

allowing the terminals 44 and 46 to gain access to the contacts located underneath the shutter.

Illustrated in figure 12 is a cross section through the reflector and lens assembly 14 of flashlight 10 of figure 1. As can be seen from figure 12 flashlight 10 has a lens assembly 14 which consists of a conical reflector 200 in which is centrally positioned a white LED 202. The lens assembly 14 also includes a lens 204 which has a double convex central lens portion 206 (which can also be seen in figure 1) surrounded by an annular straight sided lens portion 208. The lens 206 is positioned at a suitable distance from the LED 202 so that when the cone angle 210 of the LED 202 is taken into consideration, the outside diameter of the double convex lens portion 206 is positioned away from the LED 202 so that it will be struck by the cone of light 212 when the cone has a diameter of substantially the same dimension as the diameter of the lens 204. The annular straight sided portion 208 of the lens 204 will transmit the light from LED 202 which is reflected off the walls 214 of conical reflector 200. This will produce the effect of a concentrated central beam with a less bright halo concentrically arranged around the centre of the central beam.

It has also been noticed that this reflector and lens assembly 14 will produce a series of concentric rings as illustrated in figure 13, whereby the centre portion 300 is the brightest with at least three annular bands 301, 302 and 303 around the centre 300.

The first annular band 301 is a relatively dark ring (darker than the outer two annular bands 302 and 303 and the centre portion 300). The second annular band 302 is brighter than the third annular band 303, but is of less intensity than the centre portion 300. This effect has been found to produce a useful light output even though only relatively little power is being consumed from the power source.

The bands 301,302 and 303 are illustrated as being homogenous, however, in practice the bands 301,302 and 303 may be interspersed with flecks of light or possibly thin lines of light.

Due to the power plug requirements of some countries, the adaptor used may need to be of a shape and size which will not permit the adaptor to be attached, when not in use, to the rear of the flashlight. Thus such an adaptor can be stored separately from the flashlight, with an end cap being provided to cover the terminals 44 and 46 at the rear of the flashlight, when recharging is not required. While some of the features

of the adaptor 20 would not be required on such an adaptor, such an adaptor can include the shutter systems described above to attempt to prevent misuse.

It will be understood that the invention disclosed and defined herein extends to all alternative combinations of two or more of the individual features mentioned or evident from the text or drawings. All of these different combinations constitute various alternative aspects of the invention.

The foregoing describes embodiments of the present invention and modifications, obvious to those skilled in the art can be made thereto, without departing from the scope of the present invention.