Electrical services pole

An electrical services pole which is height adjustable for clamping between the floor and the ceiling of a room. The pole comprises an upper tubular core section vertically overlapping a lower tubular core section and forming therewith a vertical conduit for cables. A plurality of socket outlets are provided on the lower core section and removable cladding forming an outer sleeve is provided around at least the lower tubular core section to protect but give access to the socket outlets.

TECHNICAL FIELD 
The present invention is concerned with an electrical services pole of the 
type which is height adjustable for clamping between the floor and ceiling 
of a room to carry cabling between the ceiling void and floor level. 
BACKGROUND OF THE INVENTION 
It is known to provide a service pole which comprises a tubular core for 
carrying cabling from the ceiling void of a room down to floor level. 
Known service poles of this type are formed in two sections which are 
telescopically adjustable to give the necessary height adjustment and the 
lower section is formed with socket outlets to enable connections to be 
made with the cabling carried in the core. 
These known types of service pole are unsatisfactory in a number of 
respects. They are usually rectangular in section rather than a circular, 
thus giving an untidy effect when a plurality of them are positioned in a 
room and seen from different angles. The sockets are located on the outer 
face of the lower section of the pole and are thus unsightly and, being 
unprotected, both the sockets and any plugs mounted in the sockets are 
liable to damage. In many cases the height adjustment mechanism is visible 
and therefore both unsightly and liable to damage. 
DISCLOSURE OF THE INVENTION 
It is therefore an object of the present invention to provide an improved 
electrical service pole which has an improved appearance and design and 
which ensures that both the socket outlets and any plugs mounted on the 
socket outlets are fully protected from damage and interference. It is a 
further object of the present invention to provide an electric service 
pole in combination with a lighting source and light reflector. 
Accordingly, in one embodiment of the present invention, we provide an 
electrical services pole which is height adjustable for clamping between 
the floor and the ceiling of a room, comprising an upper tubular core 
section vertically overlapping a lower tubular core section and forming 
therewith a vertical conduit for cables and a plurality of socket outlets 
on the lower core section, characterized in that removable cladding 
forming an outer sleeve is provided around at least the lower tubular core 
section to protect but give access to the socket outlets. 
In a further embodiment of the present invention we provide an electrical 
services pole which is height adjustable for clamping between the floor 
and the ceiling of a room comprising a tubular core section forming a 
vertical conduit for cables and a light source and light reflector mounted 
on and supported by the core section. 
The light reflector in this embodiment may be designed to throw light 
upwardly or downwardly as desired. Preferably, the light source and light 
reflector are housed in a lighting bowl which is mounted on the service 
pole, the tubular core section passing through the lighting bowl.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
In the drawings, an electrical services pole is indicated generally at 10 
which comprises an upper tubular core section 11 and a lower tubular core 
section 12. Both the upper core 11 and lower core 12 are generally 
circular in section and the upper core 11 is divided into three 
compartments by vertical partition walls 13 and 14. A vertical opening 15 
extends down one side of the upper core 11 and is closed by an arcuate 
flexible snap engageable cover plate 16. Screw sockets 17 are provided on 
the partition walls 13 and 14 to receive self tapping screws and a 
T-section slot 18 is provided on the inner face of the core 11 between the 
partition walls 13 and 14. Mounted on the screw sockets 17 is a support 
plate 19 for a spring loaded plunger 20 which, as shown in FIG. 3, spring 
loads the pole against a main ceiling surface 21, which is located above a 
false ceiling 22 to create a void 23 for cables and other services. 
As can be seen from FIG. 5, the upper core extends downwardly into the 
lower core 12, on which it is mounted by means of a suitable height 
adjustment mechanism such as a turn buckle tensioning device 24. The lower 
core is part circular having a longitudinally extending opening 25 running 
its full length. Opposite the opening 25 the inner face of the lower core 
is formed with a lengthwise extending T-section slot 26. Projecting 
radially outwardly from the lower core 12 are four spacing members 27, 28, 
29 and 30, each of which defines an outwardly facing groove 31, and a 
spacing rib 32 which is positioned diametrically opposite the opening 25. 
A lower channel section support 33 for the turn buckle tensioning device 24 
is mounted in the T-section slot 26 and locked in position with the aid of 
screws. The upper end of the turn buckle tensioning device 24 is attached 
to an upper channel section support 34 which is mounted on the bottom end 
of the upper core 11. By turning the turn buckle of the tensioning device 
24, the upper core 11 can be raised and lowered relative to the lower core 
12 against the bias of the spring loaded plunger 20. 
The opening 25 in the lower core 12 is closed in the region of the upper 
part of the core by an arcuate cover plate 35. The cover plate 35 have end 
flanges 36 and 37 and is mounted on the lower core 12 by self tapping 
screws, not shown, which are threaded through the flanges 36 and 37 into 
the grooves 31 in the spacing members 27 and 30, as shown in FIG. 5. The 
cover plate 35 is also formed with two longitudinally extending outer 
grooves 38 to receive screws, a radially outwardly projecting spacing rib 
39 and an inwardly opening T-section slot 40. 
In the area below the cover plate 35, the opening 25 is closed by a flat 
plate 41 having end flanges 42 and 43 which overlie the grooves 31 of the 
spacing members 27 and 30 and which are attached thereto by screws. The 
cover plate 41 is formed with a plurality of apertures, not shown, to 
receive various types of socket outlets which are mounted on the back of 
the plate. 
The lower core 12 is covered and protected over the whole of its length by 
arcuate cladding panels 44, 45 and 46 and by arcuate door panels 47, 48 
and 49 which give access to the socket outlets. The cladding panel 44 
extends over the full length of the lower core 12 and is attached thereto 
by screws which are threaded into the groove 31 in spacing members 28 and 
29. The spacing rib 32 on the lower core 12 serves to support and balance 
the panel 44 at a position intermediate the spacing members 28 and 29 and 
to provide two separate cavities B and C between the lower core 12 and the 
cladding panel. The outer face of the cladding panel 42 is formed with 
longitudinally extending grooves 50 and 51 to receive the screws which are 
engaged in the groove 31 of spacing members 28 and 29. 
The cladding panel 45 is mounted on the opposite side of the lower core 12 
to the panel 44 in a similar fashion by screws which are threaded into the 
grooves 31 of support members 27 and 30, passing through flanges 36 and 37 
on the cover 35. The panel 45 is also formed with longitudinally extending 
grooves 52 and 53 to receive the screws and to complement the 
longitudinally extending grooves 50 and 51 in the panel 44. 
The arcuate door panels 47, 48 and 49 may be of different size, portion and 
length to suit different users requirements but are otherwise similar in 
their design and method of mounting on the lower core 12. Only the door 
panel 47 will therefore be described in detail. The door panel 47 is 
formed with outer longitudinally extending grooves 54 and 55 which are 
designed to form continuations of the grooves 52 and 53, respectively. A 
hinge 56 for the door 45 comprises a bracket 57, which is mounted in a 
T-section slot 58 in the lower core, and a hinge plate 59 which is 
attached to the bracket by screws. The hinge plate 59 carries a vertical 
hinge pin 60. The door 47 is mounted on the pin 60 for hinged movement 
from a closed position to the open position shown in FIG. 7 in which 
access is provided to the cover plat 41. A rib 61 is provided on the cover 
plate 41 to hold the door panel 47 in the closed position and enable it to 
be opened by finger pressure. The door panels 48 and 49 are mounted for 
opening and closing on the lower core 12 in a similar manner. At the 
bottom end of the door 47 is a cut-away section, which may be of any 
suitable size and shape and which defines an outlet 61 for cables. 
The cladding panel 46 which is positioned below the bottom door panel 49, 
is similar to the cladding panel 45 and will not therefore be described in 
detail. 
Mounted on the upper end of the lower core 12 is a light reflector bowl 70. 
The upper core 11 passes through the centre of the bowl 70 and through a 
bearing plate 71 which is positioned between the upper end of the lower 
core 12 and the bottom of the bowl 70 to provide a bearing and support for 
the upper core 11 when it is adjusted relative to the lower core 12 by 
means of the turn buckle device 24. Housed within the bowl 70 are a 
plurality of reflectors 72 carrying lamps 73 to provide an uplight on the 
false ceiling 22. Any number and type of lamps may be provided in the bowl 
70. 
In use, the pole 10 is mounted between the floor and ceiling of a room with 
the turn buckle device adjusted to ensure that the pole is firmly and 
securely clamped in place. Cables for data, telephone and other electrical 
apparatus and equipment, which run in the ceiling void 23, are fed into 
the upper core 11 through apertures, not shown, in the cover plate 16. The 
cables can be appropriately separated in the compartments a, b and c 
formed in the upper core 11 by the partition walls 13 and 14 so as to 
minimize any risk of electrical interference. The cables then pass down 
the upper core, into the lower core 12 where they are connected to the 
socket outlets which are mounted in space A on the back face of the cover 
plate 41. 
Appliances can then be plugged into the various socket outlets and the door 
panels 47, 48 and 49 closed so as to cover and protect the socket outlets 
and plugs, with the wires to the appliances passing through apertures 161 
provided therefor in the door panels. The socket outlets and the plugs are 
thus fully protected from damage or interference and completely hidden 
from view. 
Preferably, the socket outlets are grouped so that each door gives access 
to one group of cables, such as telecommunications, power or data 
processing. This minimises the risk of electrical interference and misuse. 
If necessary the door panels can be fitted with locks to prevent 
unauthorised access. 
The cables for the lamps in the lighting bowl may pass down the upper core 
11 to a circuit breaker mounted on the cover plate 41 and then back to the 
lighting bowl 70 through the void between the upper and lower cores. 
It will be seen that the electrical services pole 10 being approximately 
circular in section has an identical appearance from every angle so that a 
plurality of poles positioned within a room and seen as a group will give 
a pleasing and symmetrical appearance. It will also be seen that all of 
the socket outlets and plugs connected thereto are hidden from view by the 
door panels thereby ensuring a clean and pleasing appearance at all times. 
The socket outlets and plugs are also hidden and protected so as to 
minimize damage and possible interference and misuse. 
It will also be seen that the outer cladding forming the outer sleeve for 
the lower core can be quickly and easily removed to give access to the 
core and to the cables carried therein. 
All of the component panels of the lighting pole 10 are preferably formed 
from extruded aluminum section but they may also be formed from any other 
suitable materials which give the required strength and rigidity. 
Although the lighting bowl 70 is designed to throw light on the ceiling it 
is envisaged that the bowl may be designed so as to provide a down light 
rather than an up light. It is also envisaged that other lighting elements 
may be mounted on the pole 10 as required. 
It will also be apparent that the lighting bowl may be omitted completely. 
In this event it is envisaged that the outer cladding panels may be 
provided over the whole length of the pole from floor to ceiling level.