The present invention relates to a safety device in electrical connection devices, especially lamp-holders, comprising a number of contact parts designed to rest against an object arranged to be connected to the connection device, for example a light bulb socket, and a number of elements arranged to be connected to the electric leads of a cable, whereby the contact parts are at a distance from the respective connector elements and are arranged by means of being pushed in by a spring function to achieve contact with these during connection of said object to the device. According to the invention the device is provided with at least one insulating element, forced to be between the contact parts and the respective connector elements and thereby prevent contact between these when said object is removed from the connection device, and simultaneously arranged to be moved by means of the object during its connection to a position in which the contact parts and the respective connector elements are free from the insulating element to be pressed against each other by means of the object by its connection. SUMMARY OF THE INVENTION The present invention relates to a safety device in electrical connection devices, especially lamp-holders, comprising a number of contact parts designed to rest against an object arranged to be connected to the connection device, for example a light bulb socket, and a number of elements arranged to be connected to the electric leads of a cable, whereby the contact parts are at a distance from the respective connector elements and are arranged by means of being pushed in by a spring function to achieve contact with these during connection of said object to the device. Safety devices intended to prevent involuntary contact with current carrying parts are common in for example wall sockets. Connection devices of this type are however relatively easy to protect as the live parts are accessible only through small openings which can be provided with flaps or shutters or similar. In the case of contact fittings with larger openings it has however not proved possible to achieve practical, automatic safe-guards against involuntary contact. An example of the type of contact fitting with a great risk of involuntary contact is that of normal lamp-sockets. As long as a lamp is screwed in the risk of involuntary contact is generally small, whereas if on the other hand there is no lamp screwed into the lamp-socket the live parts are accessible through a wide opening. The object of the present invention is to achieve a safety device that creates a safe-guard against involuntary contact even in the case of such connection devices which are showing a large opening, especially lamp-holders. The purpose of the invention is achieved by constructing the safety device that at least one insulating element is forced to be between the contact parts and the respective connector elements and thereby prevent contact between these when the said object is removed from the connection device and simultaneously arranged to be moved by means of the object during its connection to a position in which the contact parts and the respective connector elements are free from the insulating element to be pressed against each other by means of the object by its connection. BRIEF DESCRIPTION OF THE DRAWING In the accompanying drawings three embodiments of the invention are shown, with FIGS. 1 and 2 showing a lamp-holder in two central elevations perpendicular to each other, FIG. 3 shows a bottom plate in the lamp-socket in front view elevation and FIG. 4 shows a detail in the lamp-socket in perspective, while FIGS. 5 and 6 demonstrate the function of the embodiment in FIGS. 1-4. FIGS. 7, 8 show the second embodiment in two positions, FIGS. 9, 10 show a bottom plate of the third embodiment in section and front view elevation respectively. DETAILED DESCRIPTION OF THE INVENTION In accordance with the figures the lamp-holder shows a casing 1 with an opening 2 and a thread 3 for screwing in the socket of a light bulb. Inside the thread 3 there are two spring contact sheet metal shields, one side shield 4 and one central shield 5, which make contact with the current collecting portion of the bulb when it is screwed in. Right opposite the opening 2 there is a hole 6 for a flex that can be joined to connector clips 7. In the usual type of lampholders the contact shields are connected directly to the connector clips, possibly via a switch. In the case of the lamp-holder according to the invention however the contact shields 4, 5 are not connected directly to the connector clips 7, but instead only make contact after overcoming the spring resistance built in to the shields and pressed with sections 8 against sections 9 which are in direct contact with the connector clips 7. Such a contact is however prevented by a bridge 10 made of insulating material forced by means of the tension in a spring section to take up a position between the contact parts 8 and 9. When there is no bulb screwed into the lamp-socket the contact shields 4 and 5 thus are forced to take up a position with their contact parts 8 at a distance from the contact parts 9 of the connector clips 7, and they are thus already out of contact with the live leads. In addition the insulating bridge 10 is between the contact parts 8 and 9 and is retained in this intermediate position by the spring section 11. This prevents contact between the contact parts 8 and 9 even if one of the contact shields 4, 5 were subjected to pressure. If however a light bulb is screwed with its socket down in the thread 3, the edge of the socket will first meet the part 11, thereby pushing the bridge 10 across to the right in FIG. 2; with this the edge of the bridge is freed from its position between the side shield 4 and its connector clip. Simultaneously a hole in the bridge 10 will be right opposite the central contact 5. As the bulb is screwed further in, its respective current collectors will press the contact shields 4, 5 towards their connector clips 7, and in this position the bridge 10 is no hindrance, instead at the lowest position the bulb socket has ensured contact between the contact parts 8 and 9, and the bulb obtains contact with the live lead. When the bulb is screwed out, the parts return to their starting positions. In order to make involuntary contact with any live parts in a lamp-holder without a bulb screwed in, one would thus first have to push the bridge 10 to its non-active position and then press down the contact shield opposite a connector clip 7 that is connected to an electric conductor. For this to take place is all but beyond the realms of probability. FIGS. 5, 6 show how the bridge 10 takes up its various positions in relation to the contact parts 8, 9 in safeguarded and contact position respectively. The basic idea of the invention is thus that the respective parts that are to conduct current to the connecting part, in this case the light bulb, are not directly connected to the current carrying lead but instead achieve this connection only by being pushed in against a spring force, which in turn is prevented by means of a device designed to be pushed aside by the connecting part. This principle can of course be applied to other electrical contact devices than lamp-holders and can also be applied irrespective of the number of contacting terminals. As to design there is a wide scope of variation, especially in the matter of the part that is to prevent the contact shields from being pushed in. In the example cited a sliding bridge is used, but in accordance with FIGS. 7 and 8 a hinged bridge 14, mounted on a axis 15, can be used. The bridge 14 is affected by a spring not shown and is forced to take up the position shown in FIG. 7, covering the contact parts 9. When a bulb is screwed in the edge of its socket meets a projecting device 16 turning the bridge 14 on the axis 15 so that the contact parts 9 are bared and the current collectors can be pressed down against the live contact parts. If instead the projecting device is placed at the end 17 of the bridge 14 and is allowed to drag against the edge of the bulb socket, instead of compressive force the friction so arising will be used to swing the bridge. Thus the bridge through this friction will be turned clockwise when the bulb is screwed in thereby exposing the contact parts 9, and anti-clockwise when the bulb is screwed out again covering the contact parts 9. The spring mentioned thus only needs to be contrived to keep the contact bridge in a covering position, when there is no bulb in the lamp-holder, while the spring does not need to be arranged to return the bridge to a covering position. This ensures an even greater guarantee that the bridge returns to its position even if there should be deformations or burns on the contact parts. The bottom plate of the third embodiment of the lamp-holder is shown in FIGS. 9 and 10. This bottom plate is comparable to the bottom plate 4, 5, 7, 8, 9 of the embodiment according to FIGS. 1 and 2. The bottom plate comprises a body 18 of insulating material on which central contact shields 19 and a side contact shield 20 are attached by means of a rivet 21. Between the parts 19, 20 is placed an intermediate plate 22 of insulating material, so that as evident from FIG. 9 the two shields are not electrically connected to each other. According to FIG. 10 the side contact shield 20 is provided with two legs, one of which has a part 23 provided to be pressed against a side contact 24 and obtain electrical connection with the same. In the same way the central shield 19 has a part 25 provided to be pressed against a contact 26. The two contacts 24 and 26 are provided with screw clips 27 intended to be connected to the conductors of the cable by means of which the lamp-holder has to be connected to the source of current. In the same way as by the first and second embodiments the contact parts 23 and 25 of the contact shields 20, 19 respectively, are separated from their respective contacts 24, 26 by means of a plate 28 of insulating material. The plate 28 is pivotable round an extension 29 of the body 18 forming a shaft for the plate 28. The second leg of the side shield 20 (pointing downwards in FIG. 10) is provided with a pin 30 in engagement with the plate 28 by means of a hole 31 in the latter. At the upper boarder of the side shield legs there are wings 32 and 33 provided to rest against the circumference of the lamp-socket when it will be screwed down into the lamp-holder. The central shield 19 is of resilient conducting material for example bronze and it is formed to be in the position shown in FIG. 9 with the contact part 25 a certain distance from the contact 26. The first leg of the side shield 20 is of the same material and formed in the same way so that the portion 23 is positioned a certain distance from the contact 24. The second leg of the side shield 20 is bent inwards as shown in FIG. 10 and forces the plate 28 by means of the pin 30 and the hole 31 to the position shown in FIG. 10 placed between the parts 23, 25 and their contacts 24, 26. If the bottom plate according to FIGS. 9, 10 is mounted in a lamp-holder of the form shown in FIGS. 1, 2 and the lamp is screwed down into the lamp-holder, the rounded border of the metal socket on which the thread of the lamp is formed will be pressed against the wings 32 and 33 of the legs of the side shield 20. Thereby the leg with the wing 33 will be pressed outwards as the sloping surface of the wing 33 slides against rounded border of the lamp-socket. As the pin 30 moves outwards the plate 28 will pivot clockwise (in FIG. 10) and the portion of the same placed between the part 23 and the contact 24 will move from this position and at the same time a hole 34 in the plate 28 will be positioned in line with the part 25 of the central shield 19 and its contact 26. The parts and their contacts are consequently free to meet each other when the first leg of the side shield 20 and the central shield 19 are pressed down by the lamp-socket when screwed further down into the lamp-holder. Thereby the shields are connected to the conductors attached to the clips 27.
A safety lamp socket including a socket body for holding a lamp bulb, a socket cap fastened to the socket body to hold down an electric wire, a center contact metal plate and a side contact metal plate fastened to said socket body and disposed in contact with the positive and negative conductors of the electric wire, a center metal spring plate and a side metal spring plate spaced inside the socket body, wherein when the lamp bulb is threaded into the socket body, the ring contact of the lamp bulb becomes fastened to the screw threads of the two mounting rods of the socket cap, the center and side metal spring plates are respectively forced by the tip and ring contacts of the lamp bulb to contact the center and side contact metal plates, causing the lamp bulb electrically connected to the electric wire.
Disclosed is a light socket and socket adapter including a socket adapter inserted in a light socket of a decorative light string to electrically connect an electric ornament to the electric circuit of the decorative light string. The two opposite contacts of the light socket are short-circuited by a conductive spring as the socket adapter was disconnected, and therefore the integrity of the electric circuit of the decorative light string is maintained.
A receptacle device includes a casing having a plurality of recesses for receiving receptacles therein. Each of said receptacles has two notches in two sides thereof. A panel has two hooks for being engaged with said two notches and at least two holes are defined through said panel and located in alignment with two slots in said receptacle. A pivotable member is pivotably engaged with the panel and a spring is biased between an end of said pivotable member and an inner periphery of said recess. Two plates respectively extend from a side of said pivotable member and each has a sloped surface and seal said two slots in said receptacle. The panel is pivoted when terminal plates of a plug slidably push the two plates of the pivotable member.
An adaptor for converting a 3-way electric light socket switch for convenient use with 1-way light bulbs provides an electrical conductor between the intermediate terminal of the switch to the central lead-in of the bulb and electrically insulates the central terminal of the socket from the components of the switch which correspond to the switch position which would normally energize the central terminal to produce a sequence of "on"-"off" conditions in the bulb from operation of the switch. A modified adaptor has conductors on each side for identical use in either orientation. A modified switch construction is also disclosed to provide optional use with either 3-way or 1-way bulbs.
A socket (11) for a discharge lamp bulb includes two power supply terminals, and a shielding wall for completely shielding the two power supply terminal from each other when a discharge lamp bulb is not properly seated in the socket (11). In different embodiments the socket (11) includes (FIGS. 2-5) a spring biased reciprocatably mounted cylindrical wall (24) to separate power supply terminals (21, 23), a (FIGS. 6, 7) center contact (21) mounted for reciprocation between a recessed position and an operating position in response to lamp insertion, a (FIGS. 9-14) rotary sliding member (34) or a rotary ring (40) both of which are spring biased to a blocking position and movable to a non-blocking position by lamp insertion into the socket, and a (FIGS. 16, 17) rotationally mounted member (47) having a plate (50) for separating power supply terminal segments (23b, 23c) prior to complete insertion of the lamp.
