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Claims  |
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What is claimed is:
1. A protection system for a telephone distribution frame for
interconnecting inside and outside lines and having at least one set of
contacts individually associated with each line connected thereto, said
system comprising an interface module means which may be connected to said
set of contacts, said module including contacts with a geometry which is
selected to complete a desired make/break sequence of circuit connections
when said module is plugged into or removed from said set of contacts,
means on said module for receiving a further module containing electronic
circuitry protecting equipment, means within said distribution frame for
connecting said further module to said line, and means within said module
for continuously applying ground to outside lines while enabling an
isolation of inside lines from said outside lines.
2. The system of claim 1 wherein said protecting equipment is a surge
protection means.
3. The system of claim 1 wherein said protection equipment is lightning
protection means.
4. The system of claim 1 wherein said protection equipment is data
transmission protection equipment.
5. The system of claim 1 wherein said further module either comprises means
for selectively connecting said further module either to one line or to
two lines.
6. The system of claim 1 wherein said module has an operate position for
operational interconnection of said inside and outside lines and a detente
position for providing said isolation.
7. An add-on protector for a distribution frame in a telephone system, said
distribution frame comprising a plurality of sets of primary terminals for
making connections with various wires and a plurality of sets of secondary
terminals for testing said wires, means in said distribution frame for
internally interconnecting said terminals in a predetermined pattern for
forming said primary terminals into pairs and for individually associating
said secondary terminals with said pair of said primary terminals, said
add-on protector comprising module means for making connections into said
secondary terminals and from these through said predetermined pattern to
said individually associated pair of primary terminals, and electronic
protection means associated with said module means for providing a data
transmission grade of protection to outside lines while isolating inside
lines for installation, maintenance, and repair.
8. The add-on protector of claim 7 wherein said distribution frame
comprises a plurality of layers of conductive and insulation materials,
said conductive layers being cut and folded to provide said terminals
whereby said pattern is formed by superimposing said conductive layers,
said primary terminals projecting from said distribution frame as upper
and lower pairs and said secondary terminals project at right angles
thereto from a point between said upper and lower primary terminals, and
said add-on module means comprises a plurality of terminals which plug
into said projecting secondary terminals and means for applying an
independent ground.
9. The add-on protector of claim 7 wherein said projecting secondary
terminals comprises a pair of outer leaf spring terminals with its closest
confronting pair of inner leaf spring terminals therebetween, least one
contact between each of said outer leaf spring contacts and its closest
confronting one of said inner leaf spring contacts, whereby said at least
one contact interconnects said outer and closest confronting inner leaf
springs until said leaf springs are flexed to open said at least one
contact, and means responsive at least in part to geometrically selected
dimensions for other leaf springs in said add-on module means for closing
one selected circuit before opening at least one other selected circuit
via said secondary contacts.
10. The add-on protector of claim 9 wherein said other leaf springs
selectively interleave with said outer and inner leaf springs of said
secondary terminals for causing and flexing.
11. The add-on protector of claim 10 wherein said module comprises an
insulating part having said other leaf springs embedded in one side
thereof and a receptacle formed in another side thereof, and said
electronic protection means is plugged into said receptacle.
12. The system of claim 7 wherein said module has an operate position for
operational interconnection of said inside and outside lines and a detente
position for providing said isolation.
13. An add-on protector for a distribution frame in a telephone system,
said distribution frame comprising a plurality of sets of primary
terminals for making connections with various wires and a plurality of
sets of secondary terminals for testing said wires, means in said
distribution frame for internally interconnecting said terminals in a
predetermined pattern for forming said primary terminals into pairs and
for individually associating said secondary terminals with said pairs of
said primary terminals, said add-on protector comprising module means for
making connections into said secondary terminals and from these through
said predetermined pattern to said individually associated pair of primary
terminals, electronic protections means associated with said module means
for providing a data transmission grade of protection, said electronic
protection means comprises a module having terminals with different
lengths, and means for indexing the position of the electronic protection
means relative to said module means according to the lengths of said
terminals, whereby said further module is selectively coupled to different
circuits depending upon its indexed position.
14. The add-on protector of claim 13 wherein said electronic protection
means further comprises a surge protection means.
15. The add-on protector of claim 13 wherein said electronic protection
means further comprises a lightning protector.
16. A distribution frame originally having electromechanical capability for
protecting the transmission of both voice and data signals through said
frame at electromechanical speeds, said frame not originally having
capabilities for protecting the transmission of data signals through said
frame at electronic speeds, protection means for protecting the electronic
speed data signals transmission capabilities, interface means for
attaching said protection means to existing terminals on said frame for
imparting said electronic speed data signal transmission protection means
to existing terminals on said frame for imparting said electronic speed
data signal transmission protection capabilities to said frame thereby
upgrading said frame without having to rebuild it in order to provide
protection for both said electromechanical and electronic speed voice and
said data signal data transmission capabilities, and terminals on said
interface protection means for receiving plug-in connections of
specialized circuits, whereby said distribution frame may be further
modified in the future.
17. The distribution frame of claim 16 wherein said distribution frame
comprises a Type-301 connector having test terminals and said protection
means has a geometry which plugs into said test terminals.
18. The distribution frame of claim 17 wherein said geometry causes
selected circuits to close before other circuits open.
19. THe distribution frame of claim 18 wherein said interface protection
means has plug-in connectors for mating with said existing terminals on
said frame, said plug-in connectors enabling said interface protection
means to be moved to either of two positions in order to selectively
engaged and open or close circuits in different combinations in response
to placing said plug-in connectors in either of two positions. |
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Claims |
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Description |
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This invention relates to electrical protectors for use on telephone
distribution frames, and, more particularly, to protectors for upgrading
distribution frame equipment originally designed for use with
electromechanical equipment so that it may serve electronic equipment.
A distribution frame is a mechanical structure which provides a field of
connector terminals. The terminals are interconnected within the structure
so that a wire that is connected to one terminal is electrically joined to
another wire that is connected to another terminal. An example of a use
for such a distribution frame is at the electrical entrance to a central
telephone office. Incoming cables may have hundreds or even thousands of
wires which join the central office to subscriber lines or to other
central offices. Each of these incoming wires is attached to a terminal on
the distribution frame. The corresponding and internally connected
terminal on the distribution frame is connected to equipment within the
central office which services the needs of the incoming line. This frame
provides both identification so that the incoming line may be found
quickly and flexibly so that some other central office equipment may be
assigned to serve the incoming line, as when needs change, equipment is
replaced or repaired, or when service expands.
Usually central office telephone equipment has a lifetime which may be in
the order of forty years. Therefore, equipment in current use may have
been designed much more than forty years ago. During that period of time
the development of telephone equipment has involved many revolutionary
advances, one of which is the advent of data transmission under the
control of electronic computer-line equipment.
Therefore, there is a problem since many items which still have many years
of useful life are obsolete and should be replaced, not because they are
worn out, but because the demands upon them are more than they can
deliver. An example of such obsolete equipment is a distribution frame,
which is little more than rows of terminals onto which wires may be
connected. Since a distribution frame does not have parts which experience
a substantial amount of wear, it does not normally wear out. Moreover, the
extensive amounts of hand labor required to make the millions of
connections that would be necessary to replace all existing distribution
frames would be extremely expensive.
The equipment connected to such distribution frames has advanced from
electromechanical devices for processing calls involving voice signals
alone to electronic devices for also processing very high frequency data
transmission. Therefore, it has become imperative to provide such things
as surge protection, a different form of faster acting lightning
protection, and the like. Those who are skilled in the art will readily
think of many other examples where electronic data transmission equipment
must receive a much higher level of protection as compared to the level of
protection given to electromechanical equipment.
As a practical matter, this kind of protection should be located at or near
the distribution frames because that is where the uncontrolled environment
of outside wiring enters the controlled environment within the central
office. However, there is little or no room to add such new types of
equipment at this location.
It is necessary to provide means for opening and closing the lines that are
joined at a distribution frame in order to test them. It is also necessary
to open and close circuits including those lines in the proper order. For
example, an incoming line should be first connected through a breakdown
device to ground and only then should it be connected to the central
office equipment. If there is a high voltage on a faulty line, the
breakdown device conducts to ground so that the high voltage is grounded
before it can reach and damage the central office equipment.
One existing type of distribution frame includes a device which is known in
one of its several forms as a "Type-301 connector" and in another of its
forms as a "Type-444C jack". This device, hereinafter called a "Type-301
connector", is designed so that test equipment may be connected to the
lines at the distribution frame where the outside line enters the
exchange. When the test device including the Type-301 connector is
operated in one manner, the outside line is tested, unaffected by anything
in the central office. When the test device is operated in another manner
the line inside the central office is tested, unaffected by anything on
the outside line.
One problem with the Type-301 connector is that each section of the
distribution frame has enough terminals to serve the needs of one hundred
lines, with successive connector sections abutting one another and with no
spare room for add-on surge protectors. Therefore, if an attempt is made
to add the surge protectors at this point, they cannot occupy any more
space than the Type-301 connector was designed to accommodate. Moreover,
the added surge protectors must be easily removed so that the above
described line testing may be carried out.
Accordingly, an object of this invention is to provide new and improved
protection which upgrades electromechanical devices to serve the needs of
electronic equipment. Here, an object is to provide protection for data
transmission over lines originally designed to carry only voice signals.
In this connection, an object is to upgrade existing equipment at a
minimum cost to meet these needs.
Another object of this invention is to provide the described forms of
protection in a manner which enables a continued modernization as more
stringent requirements come into effect. Here an object is to provide such
protection in a manner so that the design may become a standard for new
equipment and not just an interim correction to be used pending
replacement of the existing equipment.
In keeping with an aspect of the invention, these and other objects are
accomplished by providing a connector or adaptor designed to plug into the
test contacts on a distribution frame, which contacts are used to open the
line for test purposes. The inventive connector provides a number of
contacts which are adapted to receive a further module that contains any
suitable electronic components. For example, these further modules may
provide surge protection or newer forms of lightning protection, or any
suitable combination thereof. By the simple expedient of changing the
electronic module, almost any new and suitable requirements may also be
accommodated in the future. This way, the existing distribution frame
hardware may continue to be updated and used for the indefinite future.
A preferred embodiment of the invention is shown in the attached drawings,
in which:
FIG. 1 is an end view of an existing distribution frame having test
contacts for separately testing the lines extending into and through the
central office;
FIG. 2 shows the distribution frame of FIG. 1, in cross section and
exploded to reveal its internal construction;
FIG. 3 is a side elevation which shows the distribution frame with the
inventive connector in place over the test contacts;
FIG. 4 is a stop-motion view which shows the inventive connector being
installed so that one set of contacts is closed before another set of
contacts is opened;
FIG. 5 is a second stop motion view showing the inventive connector in a
second position, with both sets of contacts in their open position;
FIG. 6 is a top plan view (partially in cross section) taken along line
6--6 of FIG. 3;
FIG. 7 is an end elevation view (partially in cross section) taken along
line 7--7 of FIG. 3;
FIG. 8 is an exemplary electrical circuit through the distribution frame,
inventive module, and further electronic module; and
FIG. 9 is a perspective view of the further electronic module.
The prior art distribution frame 20 (FIG. 1) includes upper and lower
primary terminals 22, 24 for receiving wires of any suitable kind. For
example, the four terminals that are shown could receive two pairs of tip
and ring conductors designated T1, R1, T2, R2, respectively. Three upper
primary terminals could also receive tip, ring and sleeve of one line and
a lower three terminals could receive the tip, ring and sleeve conductors
associated with central office equipment. One of these sets of primary
terminals could be connected to the incoming line, bringing a connection
from the outside into the central office. The other of the sets of primary
terminals could be connected to wires which extend through the central
office. The internal construction of the distribution frame interconnects
the various terminals in a predetermined pattern. While the drawings show
solder-type terminals, they may also be wire wrap, or any other suitable
terminals.
In addition to the primary terminals 22, 24, the distribution frame of the
FIG. 1 frame has secondary or test leaf spring terminals 26, 28 which may
be used to open the lines for testing purposes. The secondary terminals
26, 28 project from this frame at right angles (as shown by the angle A)
with respect to the orientation of the primary terminals. For example, it
might be desirable to use the terminals 26, 28 in order to test the
incoming lines connected to terminals 22 while terminating the in-office
lines connected to terminals 24, or the other way around. Each of the
secondary or test terminals 26, 28 comprise two outside terminals 30-36.
Each of the test terminals 26, 28 also include two interior contacts
46-52, which have contacts 38-44 that come together to make a circuit from
outside contact springs 38-44 (such as 30) to confronting interior contact
springs (such as 46), respectively, for example. The geometry is such that
the interior contacts are engaged first to close circuits before the
contacts 38-44 open circuits.
The internal construction of the distribution frame is seen in FIG. 2 where
there is an expanded or exploded view of a stack of leaf spring metal
contacts (such as 56) and insulator boards (such as 58, 60). The metal
contact material is preferably die cut to interconnect selected ones of
the terminals. For example, as seen at 56, layers 62, 30 are bolted
together in a face-to-face contact to make an electrical connection. The
upper terminal R2 is connected to the lower terminal R2 via face-to-face
contact layers 62, 30, contacts 38, and confronting leaf spring contact
46. Likewise, upper terminal T2 is connected to lower terminal T2 via
face-to-face contact layers 64, 32, contacts 40, and confronting leaf
spring contact 48. The interrelationship between the parallel primary
terminals 22, 24 and the perpendicular thereto test terminals 26, 28
should also be apparent from an inspection of this figure. It should be
noted that the contact layers 30, 46, 48, 32 may be made longer or shorter
relative to each other in order to control which contacts make or break
first.
As best seen in FIG. 3, the inventive module 70 is designed to slip over
and fit into the test terminals 26, 28 of this Type-301 prior art
connector 20. More particularly, the inventive module 70 includes a
preferably molded plastic or other insulating piecepart 71 which receives
contacts 72, 74 which have preferably been die cut from flat sheets of
spring material. These contacts may also have any suitable length so that
they may be designed to make before a break in any suitable sequence,
which may be the same manner that the prior art test devices operated, for
example. By altering the geometry of these springs, different sequences of
contact making or breaking may be accommodated.
The opposite ends 76 of these contact springs may be either connected or
adapted to receive the contacts of further modules containing any suitable
electronic circuits or devices. Thus, for example, one of the further
modules may have a surge protector built into it. Another may have an
improved lightning protection built into it. Still a third may have both
surge protection and lightning protection. In a similar manner, any
suitable circuits may be built into these further modules in order to give
almost any desired present or future characteristics. A full range of such
protectors are available from the Cook division of Northern Telecom, Inc.
of 6201 Oakton Street, Morton Grove, Ill. 60053-2722, and are sold under
the trade designation "MPC Connector."
At 78 there is a space which may represent either arbitrary cross wiring or
pre-determined through connections, as may be required. For present
purposes, it may be assumed that all contacts are through-connected, as
contact 80 is shown connected at 82 to contact 84. Each of the contacts
76, similar to 80, has an associated receptacle terminal r socket 86 for
receiving the further module 87, on a plug-in basis.
Each of the further modules 87 (FIGS. 3, 9) has a tab or handle 89 which
may be gripped to pull the module out of the receptacle terminals 86. As
shown in FIG. 3, three of the further modules are fully installed. A
fourth 87a of these further modules is shown in the process of being
pushed into or pulled out of the receptacle terminal 86.
A detent D1 is formed on each of the further modules 87 (FIGS. 3, 9). The
inventive module 70 has keeper K1 for receiving a detent D1 on each
further module. The further module has a pair of long terminals 100, 102
(FIG. 9) and a pair of short terminals 104, 106. Therefore, when detent D1
is indexed to snap over edge K2 (FIG. 3) of keeper K1, surge or lightning
protection is provided to the outside line via the long terminals 100,
102, the short terminals 104, 106 being then disconnected. When detent D1
is indexed in the keeper K1 window, all four terminals 100-106 of the
farther module 87 are connected. Then, the electronic protection device is
active both inside and outside the exchange. This way, depending upon the
indexing of detent D1, the office is always protected against a lightning
strike on the outside line, for example, even when the inside line is
open, as for testing purposes.
The internal contacts, within module 70 are shown in the stop-motion views
of FIGS. 4, 5. The module 70 contains leaf spring contacts 88-94. The
outer contacts 88, 90 make a connection with outer secondary contacts 30,
32 on the distribution frame. The inner contacts 92, 94 make a connection
with the inner contacts 46, 48. As shown in the stop motion view FIG. 4,
the inner contacts 92, 94 in module 70 have made contact with the leaf
spring contacts 46, 48 as the inventive module is being installed on the
distribution frame. At this time, the contact 30, 32 have not yet made
contact with the module contacts 88, 90. Therefore, leaf spring contacts
30, 46 are still connected via closed contacts 38. Likewise, leaf spring
contacts 32, 48 are still connected via closed contacts 40. Thus, there is
a make-before-break contact combination.
In stop motion view FIG. 5, the module 70 is shown in a second position as
it is being installed over the test terminals 26. At this point, outer
leaf spring contacts 30, 32 have flexed and been deflected to open
contacts 38, 40 and thereby disconnect outer leaf spring contacts 30, 32
from inner leaf spring contacts 46, 48, respectively. Thus, there is a
circuit break after the contacts 46, 92 and 48, 94 have made.
The reason for the make-before-break sequence is irrelevant. The point is
that by varying the relative lengths of the various contacts, almost any
combination of make-break sequences may be provided. For example, FIG. 4
shows the initial contact with the incoming (outside of plant) lines. Upon
module insertion, a connection to ground is first established through a
breakdown device and then a circuit to the central office is thereafter
established so that a faulty incoming line will cause the breakdown device
to conduct to ground in order to absorb any dangerous condition and short
a high voltage to ground.
FIGS. 6, 7 show how the further electronic modules may be added to the
module 70. More particularly, the contacts 76 on the module 70 are
connected to terminals 84 (FIG. 3) in receptacles or sockets 86. Each of
the further electronic modules 87 plugs into an associated one or ones of
the sockets 86. Therefor, surge protection, for example, may be built into
the module 87 which is connected to the line via module 70. If the surge
protector is to be replaced, it is only necessary to pull one of the
modules 87 from socket 86 and to replace it with a new one.
The circuit to this surge module is shown in FIG. 8 where the various
reference numbers identify the same parts which are identified in other
figures by the same reference numerals. This circuit of FIG. 8 may be
traced from contacts 22 (FIG. 2) terminal R2, for example, through
conductive layer 62, leaf spring contact 30, contact 88, interconnection
82, contacts 84 in socket 86 (FIG. 7), terminal 100, module 87, terminal
102, contact 84a in socket 86, interconnection 82a, contact 92, leaf
spring contact 46, and contacts 24 (FIG. 2) terminal R2. Similar circuits
may be traced through FIG. 2 for each of the other terminals on the
distribution frame.
The advantages of the invention should now be clear. Existing distribution
frames which were originally designed for electromechanical equipment may
be upgraded to serve electronic equipment without requiring replacement.
Any suitable sequence of make/break circuit connections may be
accommodated. The surge protector may be designed to fit any needs and may
be replaced with other protectors when the needs change.
Those who are skilled in the art will readily perceive how to modify the
invention. Therefore, the appended claims should be construed to cover all
equivalent structures.
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Description |
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