Transducer system for continuous monitoring liquid levels in _storage tanks and the like

US RE31,089 E
Filed: 12/29/1980
Issued: 11/23/1982
Est. Priority Date: 11/25/1977
Status: Expired due to Term

First Claim

Patent Images

1. Transducer system for generating a digital code indicative of liquid level within a storage tank or the like, upon receipt of a square wave interrogation signal from a transmitter/receiver of a tank gauging system located at a central station remote from said storage tank but electrically connected to said transducer system through an INTERROGATION, a MARK and a SPACE line of said tank gauging system, comprising:

(a) means for providing a series of input signals representative of liquid level within said tank, said means including a digital volt meter (DVM) in circuit with a series of look-up read-only-memories (ROM'"'"'s);

(B) I/O network for receiving said interrogation signal and connected to said DVM for generating a reset signal therefrom in response to said interrogation signal;

(C) an oscillator/ripple counter formed essentially of MSI'"'"'s connected to said DVM and including at an input, a network for receiving said reset pulse from said DVM, said oscillator/ripple counter generating, in response to said reset pulse, sets of square wave pulses of differing repetition rates and pulse widths;

(D) a multiplexer and multi-segment decoder/driver means connected to each other and to (B) responding to selected sets of said square wave pulses to generate a synthetic digital code indicative of liquid level at microcircuit signal levels at an output means of said decoder/driver means;

(E) isolatordriver means having one or more inputs connected to said decoderdriver means of (D, and one or more output means connected to said MARK and SPACE lines controllable as a function of said synthetic digital code to drive said MARK and SPACE lines between tank gauging operating potentials for generating said digital code of interest at said central station whereby said liquid level condition within said storage tank can be indicated.

View all claims

0 Assignments

Timeline View

Assignment View

0 Petitions

Accused Products

Abstract

The liquid level within a storage tank network is continuously monitored by a transducer system of the present invention formed essentially of MSI'"'"'s (Medium Scale Integrated Chips) including a differential pressure (dp) cell in circuit with a digital volt meter (DVM) which, in turn, is connected to a series of look-up ROM'"'"'s (Read-Only Memories). In operation and as a function of dp cell output level, DVM is continuously applying BCD signals to the ROM'"'"'s, such signals being proportional to liquid level. The ROM'"'"'s retain, in memory, the Gray code translations of the BCD input. The ROM'"'"'s are then periodically accessed via an analog multiplexer controlled by an oscillator/ripple counter to provide corresponding microcircuit level signals at the output of a 7-segment decoder/driver. Thereafter, the microcircuit signals are regenerated--at levels compatible with conventional MARK-SPACE tank gauging systems--using an isolation/driver network in circuit with the 7-segment decoder/driver. The aforementioned system is initiated by a MARK-SPACE interrogation signal and has special utility in digitally monitoring product/source levels within source/product storage tank networks associated with an oil refinery and/or a chemical complex.

17 Citations

View as Search Results

13 Claims

1. Transducer system for generating a digital code indicative of liquid level within a storage tank or the like, upon receipt of a square wave interrogation signal from a transmitter/receiver of a tank gauging system located at a central station remote from said storage tank but electrically connected to said transducer system through an INTERROGATION, a MARK and a SPACE line of said tank gauging system, comprising:
- (a) means for providing a series of input signals representative of liquid level within said tank, said means including a digital volt meter (DVM) in circuit with a series of look-up read-only-memories (ROM'"'"'s);
  
  (B) I/O network for receiving said interrogation signal and connected to said DVM for generating a reset signal therefrom in response to said interrogation signal;
  
  (C) an oscillator/ripple counter formed essentially of MSI'"'"'s connected to said DVM and including at an input, a network for receiving said reset pulse from said DVM, said oscillator/ripple counter generating, in response to said reset pulse, sets of square wave pulses of differing repetition rates and pulse widths;
  
  (D) a multiplexer and multi-segment decoder/driver means connected to each other and to (B) responding to selected sets of said square wave pulses to generate a synthetic digital code indicative of liquid level at microcircuit signal levels at an output means of said decoder/driver means;
  
  (E) isolatordriver means having one or more inputs connected to said decoderdriver means of (D, and one or more output means connected to said MARK and SPACE lines controllable as a function of said synthetic digital code to drive said MARK and SPACE lines between tank gauging operating potentials for generating said digital code of interest at said central station whereby said liquid level condition within said storage tank can be indicated.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
- - 2. The transducer system of claim 1 in which an initial first generated set of square wave pulses by (C) is characterized by a repetition rate higher than those of subsequent sets of square wave pulses, for enabling an input of said multi-segment decoder/driver means of (D) at said same repetition rate, and generating said synthetic digital code at microcircuit signal levels.
  - 3. Transducer system of claim 2 in which said enabled input of said decoder/driver means of (D) is the BLANK-ing input of a 7-segment decoder/driver.
  - 4. The transducer system of claim 2 in which each subsequent set of generated sets of square wave pulses provide in combination a series of address commands at input means of said decoder/driver means of (D) whereby X-in-16 particular address command per interrogation cycle enables said decoder/driver means in circuit with MARK line through said switching transistor means, and Y-in-16 address commands per cycle enable said SPACE line where X and Y are whole numbers and X+Y=16, and whereby said synthetic code indicative of liquid level is generated.
  - 5. Transducer system of claim 4 in which said input means of said decoder/driver means of (D) is the 2°
    - bit input of a 7-segment decoder/driver.
  - 6. The transponder network of claim 4 in which each subsequent set of generated sets of square wave pulses provide in combination a series of multi-bit address commands for said multiplexer means of (D) whereby output lines thereof are placed in alternately circuit with said ROM'"'"'s to receive synthetic code of interest.
  - 7. Transponder system of claim 6 in which said logic output lines connect to a 2°
    - bit data input of a 7-segment decoder/driver.
  - 8. Transponder system of claim 7 in which 2¹ and 2² bit inputs of said 7-segment decoder/driver are continuously HI, and the 2³ bit input is continuously LOW whereby first and second outputs of said 7-segment decoder/driver oscillates between binary equivalents of a imaginary LED display of the number "6" or "7", depending on HI,LOW state of said 2°
    - bit input thereof.

9. Method of generating a digital code indicative of liquid level within a storage tank or the like upon receipt of a square wave interrogation signal from a transmitter receiver of a tank gauging system located at a central station remote from said storage tak under survey but electrically connected to said transponder network through an INTERROGATION, a MARK and a SPACE line of said tank gauging system, comprising the steps of:
- (A) encoding, as a updated, stored digital code, a series of input signals representative of liquid level within said storage tank in response to said interrogation signal;
  
  (B) generating a microcircuit rest signal after said encoded digital code has been generated and stored at a series of memory addresses;
  
  (C) generating in response to said reset pulse, sets of square wave pulses of differing repetition rates and pulse widths;
  
  (D) in response to selected sets of said square wave pulses of (C) logically scanning said series of memory addresses and forming a synthetic digital code at microcircuit signal levels directly equivalent to said encoded digital code of (A); and
  
  (E) as a function of said synthetic digital code, driving said MARK and SPACE lines to generate a MARK-SPACE digital code at said central station equivalent--in detail--to said encoded digital code of (A) whereby said liquid level condition within said storage tank can be indicated.
- View Dependent Claims (10, 11, 12, 13)
- - 10. Method of claim 9 in which said each subsequent generated set of square wave pulses of (C) is initiated in coincidence with a trailing edge of an initially generated pulse of said succeeding set of pulses, but all sets terinate in coincidence with termination of said interrogation signal.
  - 11. Method of claim 9 in which an initial first generated set of square wave pulses of (C) is characterized by a repetition rate higher than those of subsequent sets of square wave pulses for scanninng--in sequence--said memory address contaning said encoded digital code of (A) from which said synthetic digital code at microcircuit signal levels can be generated.
  - 12. Method of claim 11 in which each of said memory addresses is designated address 1, address 2, address 3 . . . or address N.
  - 13. Method of claim 12 with the additional substep of (C) being lastly generated a N+1 address pulse terminating all operations. .Iadd. 14. Transducer system for generating a digital code indicative of liquid level within a storage tank or the like, upon receipt of a square wave interrogation signal from a transmitter/receiver of a tank gauging system located at a central station remote from said storage tank but electrically connected to said transducer system through an INTERROGATION, a MARK and a SPACE line of said tank gauging system comprising:
    - (A) means for providing a series of input signals representative of liquid level within said tank, said means being in circuit with a series of look-up read-only-memories (ROM'"'"'s);
      
      (B) I/O network for receiving said interrogation signal and connected to (A) for generating a reset signal therefrom in response to said interrogation signal;
      
      (C) an oscillator/ripple counter formed essentially of MSI'"'"'s connected to (A) and including at an input a network for receiving said reset pulse from (A), said oscillator/ripple counter generating, in response to said reset pulse, sets of square wave pulses of differing repetition rates and pulse widths;
      
      (D) a multiplexer and multi-segment decoder/driver means connected to each other and to (B) responding to selected sets of said square wave pulses to generate a synthetic digital code indicative of liquid level at microcircuit signal levels at an output means of said decoder/driver means;
      
      (E) isolator/driver means having one or more inputs connected to said decoder/driver means of (D), and one or more output means connected to said MARK and SPACE lines controllable as a function of said synthetic digital code to drive said MARK and SPACE lines between tank gauging operating potentials for generating said digital code of interest at said central station whereby said liquid level condition within said storage tank can be indicated. .Iaddend. .Iadd. 15. The transducer system of claim 14 in which an initial first generated set of square wave pulses by (C) is characterized by a repetition rate higher than those of subsequent sets of square wave pulses, for enabling an input of said multi-segment decoder/driver means of (D) at said same repetition rate, and generating said synthetic digital code at microcircuit signal levels. .Iaddend..Iadd. 16. Transducer systems of claim 15 in which said enabled input of said decoder/driver means of (D) is the BLANK-ing input of a 7-segment decoder/driver. .Iaddend..Iadd. 17. The transducer system of claim 15 in which each subsequent set of generated sets of square wave pulses provide in combination a series of address commands at input means of said decoder/driver means of (D) whereby X-in-16 particular address command per interrogation cycle enables said decoder/driver means in circuit with said MARK line through said switching transistor means, and Y-in-16 address commands per cycle enable said SPACE line where X and Y are whole numbers and X+Y=16, and whereby said synthetic code indicative of liquid level is generated. .Iaddend..Iadd. 18. Transponder system of claim 17 in which said input means of said decoder/driver means of (D) is the 2⁰ bit input of a 7-segment decoder/driver. .Iaddend..Iadd. 19. The transponder network of claim 17 in which each subsequent set of generated sets of square wave pulses provide in combination a series of multi-bit address commands for said multiplexer means of (D) whereby output lines thereof are placed in alternate circuit with said ROM'"'"'s to receive said synthetic code of interest. .Iaddend..Iadd. 20. Transponder system of claim 19 in which said logic output lines connect to a 2⁰ bit data input of a 7-segment decoder/driver. .Iaddend..Iadd. 21. Transponder system of claim 20 in which 2¹ and 2² bit inputs of said 7-segment decoder/driver are continuously HI, and the 2³ bit input is continuously LOW whereby first and second outputs of said 7-segment decoder/driver oscillates between binary equivalents of an imaginary LED display of the number "6" or "7", depending on HI, LOW state of said 2⁰ bit input thereof. .Iaddend.

Specification

Resources

Litigation Campaign Assessment

Current Assignee
Chevron Research Company (Chevron Corp.)
Original Assignee
Chevron Research Company (Chevron Corp.)
Inventors
Adamson, John S.
Primary Examiner(s)
YUSKO, DONALD

Application Number

US06/220,626
Time in Patent Office

694 Days
Field of Search

340/870.19, 340/870.24, 340/152 T, 340/618
US Class Current

340/870.19
CPC Class Codes

G01F 23/18 Indicating, recording or al...

Transducer system for continuous monitoring liquid levels in _storage tanks and the like

First Claim

0 Assignments

0 Petitions

Accused Products

Abstract

17 Citations

13 Claims

Specification

Use Cases

Quick Links

Others

Transducer system for continuous monitoring liquid levels in _storage tanks and the like

First Claim

0 Assignments

Subscription Required

Subscription Required

0 Petitions

Subscription Required

Accused Products

Subscription Required

Abstract

17 Citations

13 Claims

Specification

Subscription Required

Use Cases

Quick Links

Others