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| United States Patent | 5477217 |
| Link to this page | http://www.wikipatents.com/5477217.html |
| Inventor(s) | Bergan; Terry (Saskatoon, CA) |
| Abstract | A bidirectional road traffic sensor include several respective lengths of
coaxial piezoelectric cable each having a conductive core, a conductive
polymer surrounding the core, a conductive sheath therearound and an
electrically non-conductive jacket therearound. The cables are spliced
together such that conductive core and conductive sheath of one length of
piezoelectric cable is spliced respectively to the conductive sheath and
conductive core of another piezoelectric cable. The splices are
encapsulated in an electrically non-conductive material so that the
spliced lengths of piezoelectric cables respectively constitutes positive,
neutral and negative piezoelectric sensors. Pressure changes in the
piezoelectric sensors are caused by vehicle passage thereover. In such a
manner, electrical pulses are responsively produced by passage of vehicles
traversing respective detection zones defined by the sensors and moving in
respective particular directions so that such passage of such vehicles may
be registered. |
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Title Information  |
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Drawing from US Patent 5477217 |
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Bidirectional road traffic sensor |
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| Publication Date |
December 19, 1995 |
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| Filing Date |
February 18, 1994 |
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Title Information |
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References |
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| Market Size |
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Estimate the gross annual revenues of the relevant market
sector:
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| Reasonable Royalty |
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What percentage of gross sales should the inventor or assignee be paid?
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Public's "Guesstimation" of Royalty Value
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Market Review |
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Technical Review |
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Claims |
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I claim:
1. A bidirectional road traffic sensor comprising:
(i) a first length of a coaxial piezoelectric cable having a conductive
core, a conductive polymer surrounding the core, a conductive sheath
therearound and an electrically non-conductive jacket therearound;
(ii) a second length of a coaxial piezoelectric cable having a conductive
core, a conductive polymer surrounding the core, a conductive sheath
therearound and an electrically non-conductive jacket therearound;
(iii) a first splice between the first length of coaxial piezoelectric
cable and the second length of piezoelectric cable in which the conductive
core of the first length of piezoelectric cable is spliced to the
conductive sheath of the second piezoelectric cable, and in which the
conductive sheath of the first piezoelectric cable is spliced to the
conductive core of the second piezoelectric cable, the first splice being
encapsulated in an electrically non-conductive material, thereby
constituting the first length of piezoelectric cable as a positive
piezoelectric sensor;
(iv) a third length of a coaxial piezoelectric cable having a conductive
core, a conductive polymer surrounding the core, a conductive sheath
therearound, and an electrically non-conductive jacket therearound; and
(v) a second splice between the second length of coaxial piezoelectric
cable and the third length of piezoelectric cable in which the conductive
core of the second length of piezoelectric cable is spliced to the
conductive core of the third piezoelectric cable, and in which the
conductive sheath is spliced to the conductive sheath of the second
piezoelectric cable, the second splice being encapsulated in an
electrically non-conductive material; thereby constituting the second
length of piezoelectric cable as a neutral piezoelectric sensor, and
further constituting the third length of piezoelectric cable as a negative
piezoelectric sensor.
2. The bidirectional road traffic sensor of claim 1 wherein said conductive
core is made of copper.
3. The bidirectional road traffic sensor of claim 1 wherein said conductive
sheath is formed of braided copper.
4. The bidirectional road traffic sensor of claim 1 wherein said conductive
polymer is polyvinylidene chloride.
5. The bidirectional road traffic sensor of claim 1 wherein said
non-conductive jacket is formed of polyethylene.
6. The bidirectional road traffic sensor of claim 1 wherein said first and
said second splices are encapsulated in polyethylene.
7. The bidirectional road traffic sensor comprising:
(i) a shielded coaxial cable including a conductive core, a conductive
sheath and an electrically non-conductive jacket therearound;
(ii) a first length of a coaxial piezoelectric cable having a conductive
core, a conductive polymer surrounding the core, a conductive sheath
therearound and an electrically non-conductive jacket therearound;
(iii) a splice between the shielded coaxial cable and the first length of
coaxial piezoelectric cable in which the conductive core of the coaxial
lead cable is spliced to the conductive core of the first length of
piezoelectric cable, and in which the conductive sheath of the coaxial
lead cable is spliced to the conductive core of the first piezoelectric
cable, the third splice being encapsulated in an electrically
non-conductive material, thereby constitutes the shielded coaxial cable as
a lead cable;
(iv) a second length of a coaxial piezoelectric cable having a conductive
core, a conductive polymer surrounding the core, a conductive sheath
therearound and an electrically non-conductive jacket therearound;
(v) a first splice between the first length of coaxial piezoelectric cable
and the second length of piezoelectric cable in which the conductive core
of the first length of piezoelectric cable is spliced to the conductive
sheath of the second piezoelectric cable, and in which the conductive
sheath of the first piezoelectric cable is spliced to the conductive core
of the second piezoelectric cable, the first splice being encapsulated in
an electrically non-conductive material, thereby constituting the first
length of piezoelectric cable as a positive piezoelectric sensor;
(vi) a third length of a coaxial piezoelectric cable having a conductive
core, a conductive polymer surrounding the core, a conductive sheath
therearound, and an electrically non-conductive jacket therearound; and
(vii) a second splice between the second length of coaxial piezoelectric
cable, and the third length of piezoelectric cable, in which the
conductive core of the second length of piezoelectric cable is spliced to
the conductive core of the third piezoelectric cable, and in which the
conductive sheath is spliced to the conductive sheath of the second
piezoelectric cable the second splice being encapsulated in an
electrically non-conductive material, thereby constituting the second
length of piezoelectric cable as a neutral piezoelectric sensor, and also
constituting the third length of piezoelectric cable as a negative
piezoelectric sensor.
8. The bidirectional road traffic sensor of claim 7 wherein said conductive
core is made of copper.
9. The bidirectional road traffic sensor of claim 7 wherein said conductive
sheath is formed of braided copper.
10. The bidirectional road traffic sensor of claim 7 wherein said
conductive polymer is polyvinylidene chloride.
11. The bidirectional road traffic sensor of claim 7 wherein said
non-conductive jacket is formed of polyethylene.
12. The bidirectional road traffic sensor of claim 7 wherein said first and
said second splices are encapsulated in polyethylene.
13. The bidirectional road traffic sensor of claim 7 wherein said third
splice is encapsulated in natural or synthetic rubber.
14. A system for selective detection of vehicles passing over at least one
lane of a multiple number of lanes said system comprising at least two
vehicle detector zones, each zone including a single bidirectional road
traffic sensor comprising:
(i) a shielded coaxial cable including a conductive core, a conductive
sheath and an electrically non-conductive jacket therearound;
(ii) a first length of a coaxial piezoelectric cable having a conductive
core, a conductive polymer surrounding said core, a conductive sheath
therearound and an electrically non-conductive jacket therearound;
(iii) a splice between said shielded coaxial cable and said first length of
coaxial piezoelectric cable in which said conductive core of said coaxial
lead cable is spliced to said conductive core of said first length of said
piezoelectric cable, and in which said conductive sheath of the coaxial
lead cable is spliced to said conductive core of said first piezoelectric
cable, said third splice being encapsulated in an electrically
non-conductive material, which thereby constitutes said shielded coaxial
cable as a lead cable;
(iv) a second length of a coaxial piezoelectric cable having a conductive
core, a conductive polymer surrounding said core, a conductive sheath
therearound and an electrically non-conductive jacket therearound;
(v) a first splice between said first length of coaxial piezoelectric cable
and said second length of piezoelectric cable in which said conductive
core of said first length of piezoelectric cable is spliced to said
conductive sheath of said second piezoelectric cable, and in which said
conductive sheath of said first piezoelectric cable is spliced to said
conductive core of said second piezoelectric cable, said first splice
being encapsulated in an electrically non-conductive material, which
thereby constitutes said first length of piezoelectric cable as a positive
piezoelectric sensor;
(vi) a third length of a coaxial piezoelectric cable having a conductive
core, a conductive polymer surrounding said core, a conductive sheath
therearound, and an electrically non-conductive jacket therearound; and
(vii) a second splice between said second length of coaxial piezoelectric
cable, and said third length of piezoelectric cable, in which said
conductive core of said second length of piezoelectric cable is spliced to
said conductive core of said third piezoelectric cable, and in which said
conductive sheath is spliced to said conductive sheath of said second
piezoelectric cable, said second splice being encapsulated in an
electrically non-conductive material; wherein pressure changes in said
piezoelectric sensor caused by vehicle passage thereover responsively
produce electrical pulses for registering the passage of vehicles moving
in respective particular directions and which respectively traverse one
and another of said vehicle detection zones.
15. The system of claim 14 includes two spaced-apart bidirectional
piezoelectric road traffic sensors for classifying moving traffic.
16. A traffic counter including:
(a) at least two bi-directional road traffic sensors comprising:
(i) a shielded coaxial cable including a conductive core, a conductive
sheath and an electrically non-conductive jacket therearound;
(ii) a first length of a coaxial piezoelectric cable having a conductive
core, a conductive polymer surrounding the core, a conductive sheath
therearound and an electrically non-conductive jacket therearound;
(iii) a splice between said shielded coaxial cable and said first length of
coaxial piezoelectric cable in which said conductive core of said coaxial
lead cable is spliced to said conductive core of said first length of
piezoelectric cable, and in which said conductive sheath of said coaxial
lead cable is spliced to said conductive core of said first piezoelectric
cable, said third splice being encapsulated in an electrically
non-conductive material, which thereby constitutes said shielded coaxial
cable as a lead cable;
(iv) a second length of a coaxial piezoelectric cable having a conductive
core, a conductive polymer surrounding said core, a conductive sheath
therearound and an electrically non-conductive jacket therearound;
(v) a first splice between said first length of coaxial piezoelectric cable
and said second length of piezoelectric cable in which said conductive
core of said first length of piezoelectric cable is spliced to said
conductive sheath of said second piezoelectric cable, and in which said
conductive sheath of said first piezoelectric cable is spliced to said
conductive core of said second piezoelectric cable, said first splice
being encapsulated in an electrically non-conductive material, which
thereby constitute said first length of piezoelectric cable as a positive
piezoelectric sensor;
(vi) a third length of a coaxial piezoelectric cable having a conductive
core, a conductive polymer surrounding said core, a conductive sheath
therearound, and an electrically non-conductive jacket therearound; and
(vii) a second splice between said second length of coaxial piezoelectric
cable, and said third length of piezoelectric cable, in which said
conductive core of said second length of piezoelectric cable is spliced to
said conductive core of said third piezoelectric cable, and in which said
conductive sheath is spliced to said conductive sheath of said second
piezoelectric cable, said second splice being encapsulated in an
electrically non-conductive material; wherein pressure changes in said
bi-directional road traffic sensors caused by vehicle passage thereover
responsively produce electrical pulses;
(b) means for removably mounting said bi-directional road traffic sensor to
a roadway;
(c) signal transmitting means connected to, and actuated by, said
bi-directional road traffic sensor for transmitting said electrical
pulses; and
(d) tally means triggered by said pulses from said signal transmitting
means for tallying said pulses.
17. The traffic counter of claim 16 including two spaced-apart
bidirectional piezoelectric road traffic sensors for classifying moving
traffic. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to a bidirectional road traffic sensor which is
capable of simultaneously monitoring two or more lanes of traffic for
counting and/or classifying individual vehicles.
2. Description of the Prior Art
The term "road traffic" is used to include wheeled vehicles such as
automobiles, having flexible or pneumatic tires covering a substantial
area of the roadway in supporting the weight of the vehicle on wheels
spaced-apart transverse to the direction of movement of the vehicle, and
includes automotive vehicles in a toll collection lane or in a low speed
vehicle weighing lane for example.
One of the problems facing highway engineers is the necessity to provide
adequate traffic control systems which can readily handle the ever
increasing loads of automotive traffic. Vital to the solution of this
problem is the need for continuous accurate information concerning the
number of vehicles and/or type (classification) of vehicles passing over a
particular stretch of highway. Often, in order to provide maximum
utilization of given highway facilities, it is necessary to use a
particular single traffic lane for vehicles moving in both directions,
e.g., the center lane of a three-lane highway, or multi-lane highways
using all but one lane for traffic in a particular direction during rush
hours.
It is frequently necessary in the control of vehicular traffic to provide
means for the selective detection and/or counting of vehicles in
accordance with their direction of travel as they pass through a defined
detection area.
The U.S. Federal Highway Administration and other government agencies both
in Canada and in the U.S.A., often require the submission of reports
concerning truck travel at specific locations on roadways before
authorizing funding for the repair and improvement of such roadways. Such
reports are typically submitted in a format known as the Federal Highway
Administration vehicle Classification Scheme. A number of classifying
machines are currently in manufacture. Typically, they require two axle
detector inputs positioned a known distance apart. The machine measures
the time between axle actuations, calculates the speeds at which the axles
are travelling, counts the number of axles travelling at the same rate of
speed, and then, depending upon results, records the vehicle type in a
predetermined classification bin. Such studies are typically undertaken
over a continuous 24 hour period and are broken down into one hour
increments. Portable axle detector devices manufactured and available
today vary greatly in cost, durability, limitations of operation and set
up procedure difficulty.
Heretofore, in traffic counting systems on a multi-lane highway, a treadle
switch was embedded in each lane of the highway for actuation by the
wheels of a vehicle, and each treadle controlled a circuit operating a
counter to count the vehicle axles passing over the lane. In such systems
it was necessary to add the counts of each counter in order to obtain the
total count in all lanes. Furthermore, the initial cost of such systems
proved expensive, and the operating expenses attached thereto, also proved
to be slightly higher than most road authorities had anticipated.
Such treadle switch traffic counting system are now obsolete. In more
recent traffic counting systems, it has been found that vehicles usually
cross the sensing mechanisms in different lanes, simultaneously or
substantially so, so that the time between actuation of the sensors is
less than it takes to operate a counter.
The art replete with patents directed to traffic counting in a single lane
of traffic and/or for unidirectional traffic. Typical examples include the
following: D. Katz U.S. Pat. No. 1,992,214 patented on Feb. 26, 1933;
Power U.S. Pat. No. 2,067,336 patented Jan. 12, 1937; C. D. Cutler U.S.
Pat. No. 2,161,896 patented Jun. 13, 1939; J. M. Paver U.S. Pat. No.
2,163,960 patented Jun. 27, 1939; R. R. Armstrong U.S. Pat. No. 2,244,933
patented Jun. 10, 1941; G. V. Nolde U.S. Pat. No. 2,319,153 patented May
11, 1943; E. J. Schulenburg U.S. Pat. No. 2,823,279 patented Feb. 11,
1958; H. A. Wilcox U.S. Pat. No. 2,885,508 patented May 5, 1959; U.S. Pat.
No. 2,909,628 to Cooper; J. P. Roscoe U.S. Pat. No. 2,922,003 patented
Jan. 19, 1960; H. A. Wilcox U.S. Pat. No. 3,188,422 patented Jun. 8, 1965;
U.S. Pat. No. 3,486,008; G. Fischel U.S. Pat. No. 3,732,384 patented May
8, 1973; V. Necloff U.S. Pat. No. 3,927,389 patented Dec. 16, 1977; C.
Abhodanto U.S. Pat. No. 4,013,851 patented Mar. 22, 1977; C. M. Tromp U.S.
Pat. No. 4,799,381 patented Jan. 24, 1989; A. Buckley U.S. Pat. No.
4,839,480 patented Jun. 13, 1989; B. Sobut U.S. Pat. No. 4,862,163
patented Aug. 29, 1989; J. R. Fisher U.S. Pat. No. 5,115,109 patented May
19, 1992; J. L. Banke Canadian Patent No. 727,292 patented Feb. 1, 1966;
H. C. Kendall et al. Canadian Patent No. 749,552 patented Dec. 27, 1960;
S. Iwamoto et al Canadian Patent No. 902,208 patented Jun. | | |
