Café light strings are strings of lights configured to provide lighting over an open expanse, such as, for example a grassy lawn or a patio. Various other types of light strings can also be configured to provide lighting over such open expanses. These café lights are usually configured as strings of lights suspended over the open expanse between securing structures. A distance between such securing structures can dictate the number of lights and the dimension of a string of such lights. Distances between securing structures at different venues will dictate different numbers of lights and different dimensions of strings of such lights, which are required for these different venues. Thus, every venue requires customized requirements for providing café lighting. An adaptable system for providing café lighting would facilitate installation of café lights in these various venues.
Some café lighting venues can be quite expansive. For such expansive venues, overhead suspension of strings of light can require high tension in support cabling. Should multiple strings of lights be required to span such large expanses, such high tension could cause uncoupling of mechanical and/or electrical connectors or other failures. Such failures can result in inhibiting power to café lights, destruction of the strings of café lights, or even injury to persons situated below the suspended café light strings. Reliable and secure mechanical and electrical connection of multiple strings is needed, especially for large venues.
Apparatus and associated methods relate to a lighting section that includes a structural support cable and a light string. The structural support cable includes a first connecting member at a first end of the structural support cable. The first connecting member is configured to mechanically connect to a second connecting member of a second end of an adjacent upstream structural support cable. The structural support cable also includes a second connecting member at a second end of the structural support cable. The second connecting member is configured to mechanically connect to a first connecting member and a first end of an adjacent downstream structural support cable. The light string is coupled to the structural support cable so as to be extended along the structural support cable between the first and second connecting ends of the structural support cable. The light string includes a first electrical connector at a first end of the light string. The first electrical connector is configured to receive electrical power from a second electrical connector of an adjacent upstream café light string. The light string includes a second electrical connector at a second end of the light string. The second electrical connector is configured to receive electrical power to a first electrical connector of an adjacent downstream café light string. The light string also includes an electrical cable extending between the first and second electrical connectors.
Apparatus and associated methods relate to a lighting system configured to be suspended overhead between two supporting structures. A tensile force will be imparted to the lighting system as a consequence of suspending the lighting system overhead. The lighting system can include one or more lighting sections connected end to end. Each of the lighting sections has a structural support cable and a light string coupled thereto. Each of the lighting sections has first and second end connectors on first and second ends of the lighting section. The first and second end connectors provide mechanical connection between adjacent structural support cables as well as electrical connection between adjacent light strings. The lighting sections are configured such that the tensile force imparted to the lighting section is mostly borne by the structural support cable.
Each of lengths 18, 20, 22, and 24 includes one or more café lighting sections, interconnected to one another so as to form the length. For example, length 18 has café lighting sections 26A, 26B, and 26C. Each of café lighting sections 26A, 26B, and 26C includes structural support cable 28A, 28B, and 28C and café light string 30A, 30B, and 30C, respectively. Interconnection of café lighting sections 26A, 26B, and 26C of length 18 can be performed by interconnecting structural support cables 28A, 28B, and 28C to one another and interconnecting café light strings 30A, 30B, and 30C to one another.
Interconnecting structural support cables 28A, 28B, and 28C to one another includes mechanically securing adjacent ends of adjacent structural support cables 28A and 28B to one another and mechanically securing adjacent ends of adjacent structural support cables 28B and 28C to one another. Structural support cables 28B has first connecting member 32B at a first end of structural support cable 28B. First connecting member 32B is configured to mechanically connect to second connecting member 34C at a second end of structural support cable 28C, which is adjacent and upstream thereto. Structural support cables 28B has second connecting member 34B at a second end of structural support cable 28B. Second connecting member 34B is configured to mechanically connect to first connecting member 32C at a first end of structural support cable 28A, which is adjacent and downstream thereto. Structural support cables 28A and 28C are configured in a similar fashion as structural support cable 28B, even though only connected to one adjacent structural support cable—structural support cable 28B.
Interconnecting café light strings 30A, 30B, and 30C to one another includes connecting electrical connectors at adjacent ends of adjacent café lighting strings 30A and 30B to one another and connecting electrical connectors at adjacent ends of adjacent café lighting strings 30B and 30C to one another. Café light string 30B has first electrical connector 36B at a first end of café light string 30B. First electrical connector 36B is electrically connect to second electrical connector 38C at a second end of café light string 30C, which is adjacent and upstream thereto. Café light string 30B has second electrical connector 38B at a second end of café light string 30B. Second electrical connector 38B is electrically connect to first electrical connector 38A at a first end of café light string 30A, which is adjacent and downstream thereto. Café light strings 30B also has an electrical cable 40B extending between first and second electrical connectors 36B and 38B. Café light strings 30A and 30C are configured in a similar fashion as café light strings 30B, even though only connected to one adjacent café light strings—café light strings 30B.
Each of café light strings 30A, 30B, and 30C can further include a plurality of café lighting taps 42. Each of the lighting taps 42 can include one or more of the following: i) a cable coupler; ii) a light socket; iii) a pigtail cable; and iv) a light emitting device. As depicted in
Each of lengths 18, 20, 22, and 24 will have a tensile force applied thereto due to the force required to suspend each length 18, 20, 22, and 24 in its corresponding suspension configuration. Many electrical connectors, such as electrical connectors 32A and 32B, are not configured to maintain good electrical connection therebetween in high tensile situations. Furthermore, applying large tensile forces to electrical elements, such as café light strings 30A, 30B, and 30C, can cause failure of such electrical elements. Therefore, controlling a tensile force applied to interconnected café light strings 30A, 30B, and 30C can facilitates reliability of electrical power provided to the café lights of interconnected café light strings.
Café light string 30B is slidably coupled to structural support cable 28B so as to slidably extended along the structural support cable between first and second mechanical connecting members 32B and 34B of the structural support member 28B. In the depicted embodiment, slidable coupler 52B of lighting tap 42B provides slidable coupling between café light string 30B and structural support member 28B. In other embodiments, slidable couplers need not be associated with lighting taps, such as lighting tap 42B. A series of slidable coupling members can be distributed along café light string 30B. In some embodiments, structural support cable 28B can include first and second retention features configured to retain the plurality of slidable couplers of café light string 30B between first and second connecting members 32B and 34B, respectively, of structural support cable 28B.
To control tensile forces applied to interconnected café light strings 30A, 30B, and 30C, structural support cable 28A, 28B, and 28C have cable lengths that are less than string lengths of café light strings 30A, 30B, and 30C. Such control of cable and string lengths permit tension to be applied to the interconnected structural support cables 28A, 28B, and 28C without such high tension being simultaneously applied to interconnected café light strings 30A, 30B, and 30C.
Each of lighting taps 42 includes cable coupler 44, light socket 48, light emitting device 50, and slidable coupler 52. Lighting tap 42 is depicted in closeup fashion in
Various types of light emitting devices can be used. For example, incandescent, fluorescent bulbs can be used. In some embodiments, light emitting diodes (LEDs) can be used as light emitting devices 42. Light sockets 48 are configured to receive the type of light emitting device for which café light string 30 is configured. In some embodiments, cable length of structural support cable 28, when in tensile condition (such as when supporting café light section 26) is substantially equal to string length of café light string 30 under substantially no tension. In other embodiments the cable length of structural support cable 28 is less than the string length of café light string 30. For example, in some embodiments, a ratio of cable length to string length is less than 0.99, 0.98, 0.95 or 0.93, for example.
Café lighting section 26 further includes a plurality of coupling members 51 that provide coupling between the café light string and the structural support cable. In some embodiments, the coupling members can provide slidable coupling between structural support cable 28 and café light string 30. In such embodiments, a string length of light string 30 is greater than or equal to a cable length of structural support cable 28, so as to ensure that tensile forces associated with suspension of café lighting section 26 are borne primarily by structural support cable 28 and not by light string 30. In other embodiments, the coupling members can provide fixed coupling between structural support cable 28 and café light string 30. In such embodiments, a string section lengths of light string 30 between adjacent coupling members 51 are greater than or equal to corresponding cable section lengths of structural support cable 28 between the adjacent coupling members 51, so as to again ensure that tensile forces associated with suspension of café lighting section 26 are borne primarily by structural support cable 28 and not by light string 30.
While the invention has been described with reference to an exemplary embodiment(s), it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment(s) disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.