|Publication number||US2695122 A|
|Publication date||Nov 23, 1954|
|Filing date||Aug 25, 1952|
|Priority date||Aug 25, 1952|
|Publication number||US 2695122 A, US 2695122A, US-A-2695122, US2695122 A, US2695122A|
|Inventors||Learman Frank E|
|Original Assignee||Studebaker Corp|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (2), Referenced by (16), Classifications (9)|
|External Links: USPTO, USPTO Assignment, Espacenet|
23, 1954 F. E. LEARMAN FLUID DISPENSING APPARATUS Filed Aug. 25, 1952 m 2 ME IMQ W N m @M B I LIP w V A P R V. R L
3 I @m .a w vw N A TTORNEYS.
United States Patent FLUID DISPENSING APPARATUS Frank E. Learman, Mishawaka, Ind., assignor to Studebaker Corporation, South Bend, Ind., a corporation of Delaware Application August 25, 1952, Serial No. 306,188
4 Claims. (Cl. 22620.6)
My present invention concerns fluid dispensing apparatus having particular utility for filling cylinders with fluid under pressure.
The apparatus of my present invention is designed and constructed for connection to any suitable source of fluid under pressure, for example compressed air, and includes shut-off valve means operable to close connection between the supply source and a container being charged with such fluid. Additionally, filling control and pressure regulating control valve means respectively separate the container from the supply source and pressure measuring and regulating means in such a manner that at the completion of charging of the container, the fluid therein will be at a desired pressure. Further, associated with the valving system of my present apparatus I have embodied an electronic timing device capable of automatically opening and closing the control valves of the filling and control sections of my apparatus.
The apparatus as disclosed herein, finds particular utility in charging air cylinders used in storing airplane jet engines, but may be used with like facility for the charging of pneumatic tires, balloons or other similar containers. In any event, the utilization of an apparatus of the character herein disclosed readily adapts itself to production line setups wherein continuous manufacturing processes are carried 'forth and provides a convenient medium for automatically charging a container to a designated pressure level.
The main object of my present invention is to provide a new and improved automatic fluid dispensing apparatus useful for the charging of containers to predetermined pressure levels.
A further object of my present invention is to provide a new and improved fluid dispensing apparatus having associated therewith electronic timing means capable of automatically actuating suitable valving arrangements whereby containers to be charged with fluid may be filled to a predetermined and desired pressure.
A still further object of my present invention is to include means, associated with the fluid dispensing apparatus of my invention, which will overcome the automatic electronic timing means utilized to control and eflect the filling operation of a container from a designated source of pressurized fluid so that my apparatus may be operated without respect to the electronic timing means associated therewith.
The above and further objects, features and advantages of my present invention will appear to one familiar with the art from the following detailed description and specification therefor and with reference to the accompanying drawings.
In the drawings:
The single figure is a schematic representation of a device embodying the features of my present invention and showing in diagrammatic setup the functional interrelation between the electronic timing means, the valving means controlling the connection of a container to be filled with a suitable supply source of pressurized fluid and the control means associated therewith for insuring the filling of such a container to a designated pressure.
Referring now to the drawing, it will be recognized that a conventional compressor and storage tank system is arranged to supply pressurized fluid, such as air, at pressures, for example, in the neighborhood of 100 pounds per square inch. A supply line 11 leads from the storage tank system 10 and is fitted with a line control shut-off valve indicated schematically at12. Con- H 2,695,122 Patented Nov. 23, 1954 nected to control valve 12 is a filling chamber 13 consisting of a suitable piping arrangement fitted with a flexible filling hose 15 having a filling connection valve 16 of conventional variety at its outer end for connection with a container to be charged. Disposed at one end of chamber 13 intermediate the filling hose 15 and the shut-off valve 12, is a first solenoid controlled filling valve 20, electrically operable in response to energization and deenergization of a solenoid, indicated generally at 21. At the opposite end of chamber 13 is positioned a second solenoid actuated pressure control valve 22 responsive to the electrical control of solenoid 23 associated therewith. Opening and closing movement of valve 22 controls communication of chamber 13 with a delayed pressure chamber 25 comprising an elongated pipe section closed at its outer end. When the second solenoid valve 22 is positioned in an open condition as illustrated, air from chamber 13 flows into the delayed pressure chamber 25 via a small diametered elongated tubular member 26 having a reduced internal cross section. The sole function of the second solenoid actuated valve 22 is to control the admission of air from the filling chamber 13 to the delayed pressure chamber 25. Chamber 25 is fitted with a pressure gauge 28, safety valve 29, and a normally closed pressure responsive electrical switch of a known or preferred variety indicated generally at 30. Also leading from the delayed pressure chamber 25 is a small vent tube 31. The sole func ion of the first named solenoid actuated shut-off valve 20 is to control the admission of pressurized fluid from the; compressor and storage tank 10 to the filling hose 1:; and the filling connection valve 16.
In order to control the automatic and time sequential operation of the two solenoid actuated valves 20 and 22 and thus the admission and control of the pressurized fluid to the container being filled, I have found it desirable to employ a pulse timing electronic circuit, as shown, of known design which is disclosed and described in Handbook of Industrial Electronic Circuits by Markus and Veluff, published by McGraw-Hill Publishers, First Edition-1948, page 241, and also in Industrial Chem-. istry and Engineering (Analytical Edition) for January 1946, volume 18, page 79. In general the timer circuit as illustrated in the drawings and described in the above named references is designed to control the electrical energization of the two solenoids 21 and 23 so that the valves 20 and 22 associated respectively therewith will be alternately opened and shut in response to the timing impulses generated by the electronic circuit.
Briefly, the timer circuit is to be fed off of a to volt, 60 cycle A. C. supply, such as a normal household supply source, by means of wall plug 35. A line control switch 32 is used to selectively control the supply of the energy to a transformer 33. The energization of the electronic circuit is controlled generally by the operation of a 2050 gas tetrode electronic tube indicated generally at 34. The tetrode tube 34 includes five elements, namely, a filament 36, cathode 37, control grid 38, shield grid 39 and plate 40. Since the shield grid 39 requires no voltage in relation to the cathode, such is interconnected with the cathode. The cathode grid circuit includes a potentiometer 41, a resistance 42, a second resistance 43 and a condenser 44. In circuit with the plate is resistance 45, shown herein as a light bulb which serves additionally to indicate to the operator that the timing circuit is energized. Operation of the two solenoids 21 and 23 by the timer circuit is not effected directly but through a normally open electro-magnetic relay 50 having a first movable contact arm 51 associated with a single contact 52 of the timer circuit which cooperates to connect and disconnect one side of the supply line with the grid supply circuit for tube 34 over a resistance 57. A second movable contact arm 53 operates between contacts 54 and 55 respectively teamed with the valve actuating solenoids 21 and 23. A plate circuit capacitor 56 is also in circuit with the relay 50 which serves to maintain the relay energized after deenergization of the 2050 tube 34, as will be explained hereinafter. Additionally a pair of resistances 58, 58, coupled in parallel relation, are connected in circuit between the relay 50, and one side of the supply line.
3 Operation In operating a device of the character described hereinabove, closure of line switch 32 serves to energize transformer 33' of the electronic timer circuit from the 110 to 115 volt, 60 cycle, A. C. supply source tapped by means of wall plug 35. Filament 36 of tube 34 will then be warmed in approximately seconds at voltages of substantially 6.3 volts and currents of .6 ampere. Plate current is supplied over resistance 45 which limits the plate current and the charging current of capacitor 44 to less than the tubes rated maximum of 1 ampere.
Resistance 43 of one megohm. is coupled with the grid 38 of the tube and this resistance serves to limit the grid current while the setting of rheostat 41 in circuit with the cathode and control grid determines the pulse rate of the tube. The range of the tubes pulse rate is determined by the values of rheostat 41, resistance 42 and capacitor 44. Rheostat 41 also acts to reduce arcing between relay contact arm 51, and contact 52 and between relay contact arm 53, and contacts 54 and 55 on inductive loading of the relay. In operation negative bias on the tube grid leaks off as determined by the RC combination in the grid circuit so that when suificient bias voltage is lost from the grid, the 2050 tube 34 conducts, closing relay contact arm 51 with contact 52 and contact arm 53 with, contact 54; the circuit being completed to the other side of the supply line through the relay 50 and the normally closed pressure responsive switch 30.
Closure of relay contact arm 51 with contact 52 and arm 53 with contact 54 when relay 50 is energized is also accompanied by charging of capacitor 44 and capacitor 56 until the plate voltage of the tube becomes too low for conduction to continue. At that point the tube stops conducting and the period of non-conduction is determined or controlled through the setting of the potentiometer 41 and the value of resistance 42 in ratio to the ability of the condenser 44 to absorb charge and retain it. While condenser 44 is being degenerated through resistance 42 and potentiometer 41, the plate circuit capacitor 56, which was also charged during the conduction period of the tube, continues to discharge to relay 50 thereby energizing the same for an additional period of time after tube 34 has stopped conducting.
As relay 50 is energized, closure of contacts 52 by relay contact arm 51 serves to replace the negative charge on the grid of the gas tetrode rectifier tube 34.
Closure of contact 54 with arm 53 as relay 50 is energized, serves to energize solenoid 21 associated with the filling control valve 20. Such action permits valve 29 to open allowing high pressure air (100 p. s. i.) to enter chamber 13 for charging a container attached to the filling hose 15 by means of connector 16.
When relay 50 is deenergized, the circuit to solenoid 21 is interrupted and contact arm 53 falls to make closed circuit connection with contact 55 associated with the second solenoid 23. This action places solenoid 23 across the line to open valve 22. Opening of valve 22 allows the air or fluid in chamber 13 to seep gradually into the delay pressure chamber 25 via the small inlet tube 26. The pressure in chamber 13, the container being filled, and the chamber 25 is thus registered on pressure gauge 28.
When tube 34 again conducts, relay 50 is energized to break the circuit to solenoid 23, thus closing valve 22 and energizing solenoid 21 to open valve 20. This cyclic operation of the two valves and 22 is continued according to the pulse rating of the electronic timer circuit until the container being charged has been filled to a desired level.
During the time that valve 22 is open and when the same is closed the air in chamber is permitted to gradually escape to atmosphere via the small diametered vent tube 31.
It should also be noted that if pressure in chamber 25 at any time exceeds a designated limit, the safety valve 29 therein will lift to rapidly vent oflf the air in both chambers 13 and 25 as well as the container being filled. At the same time the pressure responsive switch 30, which is likewise set to open at a designated pressure level, will open. to cut out the electronic timing circuit and place solenoid 23 directly across the line thereby maintaining valve 22 open until the pressure in chamber 13 and the container being filled is vented off to the desired pressure level.
In the particular use for which my present device is designed, I desire to charge huge air flasks, such as jet engine housings, to a designated pressure level of approximately 5 p. s. i. I, therefore, set the pressure responsive switch 30 to lift at 5 p. s. i. and the safety valve 29 to lift at a somewhat higher pressure. Thus, charging of the container takes place automatically according to the pulsating cyclic operation of the timer circuit, the filling valve 20 and the delayed pressure control valve 22, until the desired 5 p. s. i. pressure is arrived at in the flask being charged. Normally the operator watches gauge 28 near the last part of the charging operation so that as the desired pressure is approached he may open line switch 32 or disconnect the filling hose 15 from the flask being charged to stop the operation. However, if the operator does not happen to be on hand to shut off the charging, no great damage will be done to the container since at pressures greater than the 5 pound level, switch 30 will open to lift valve 22 and vent off the excess pressure to atmosphere via vent tube 31. If the charging operation is not stopped after such an occurrence the pressure responsive switch will close again when the 5 pound level is reached thereby to cut in the charging operation efiected by the electronic timing circuit. Valve 20 will subsequently opcn according to the energization of relay 50, charging the container in excess of the 5 p. s. i. desired. When valve 22 is again opened at deenergization of relay 50, the excessive pressure in the container will again open switch 30 until the pressure in excess of 5 p. s. i. is vented off via tube 31, etc.
Thus it will be recognized that I have provided a new and improved fluid dispensing device or apparatus particuiarly adapted for the automatic charging of containers, flasks, etc., to designated pressure levels with the charging time being automatically controlled by an electronic circuit means as described.
The advantages of such an apparatus will be readily apparent to those familiar with the art and although various changes, modifications and substitutions of equivalents may be made in my device as disclosed and described, it is not contemplated that such will depart from the spirit and scope of my invention. I, therefore, do not wish to be limited to the specific embodiment of my invention herein illustrated and described except as may appear in the following appended claims.
1. In a fluid dispensing apparatus of the class described for filling a container from a source of pressurized fluid, a filling chamber, filling valve means controlling the admission of pressurized fluid to said chamber, filling connection means in said chamber arranged for attachment with the container to be filled, a delayed pressure chamber communicating with said filling chamber, pressure control valve means between the two chambers, timing means adapted to open and close said filling and pressure control valves alternately according to a preselected time sequence, pressure measuring means in said delayed pressure chamber for measuring the pressure in the container when said pressure control valve means is open, vent means in said pressure chamber for venting the pressure therein to atmosphere, and switch means arranged to open said pressure valve at a predetermined pressure irrespective of the operation of the timing geals thereby to vent pressure off of the container being 2. A fluid dispensing apparatus of the class described comprising, a filling chamber having means for connection with a container to be filled with pressurized fluid, means connecting said filling chamber with a source of pressurized fluid, a filling control valve means operable to selectively isolate said filling chamber from said source of fluid, a delayed pressure chamber communicating with said filling chamber, a pressure control valve means operable to isolate said filling chamber from said pressure chamber, pressure measuring means communicating with said pressure chamber, a vent means opening to atmosphere from said pressure chamber, electronic timing means arranged to' alternately open and close said filling and pressure control valve means, and a pressure responsive switch means in said pressure chamber constructed and arranged to deenergize said electronic timing means and open said pressure control valve means at pressures in excess of a predetermined value.
3. In a fluid dispensing apparatus of the class described for filling a container from a source of pressurized fluid, a filling chamber, a first solenoid, a filling valve means controlling the admission of fluid to said filling chamber from the source of pressurized fluid and operable in response to actuation of said first solenoid, a delayed pres-- sure chamber adjacent said filling chamber and interconnected therewith, a second solenoid, a pressure control valve means disposed intermediate said two chambers for controlling the flow of fluid therebetween in response to operation of said second solenoid, timing means arranged to control the alternate energization and deenergization of said two solenoids thereby to effect alternate opening and closing of said filling and pressure control valve means, pressure measuring means in said delayed pressure chamber for measuring the pressure in said two chambers and the container to be filled, vent means communicating with said pressure chamber for venting the same to atmosphere, and pressure responsive switch means arranged to disconnect said timer means at a preselected pressure and energize said second solenoid thereby to open the said pressure control valve means and vent ofl pressures in the container in excess of the preselected pressure at which said switch means is set to respond.
4. A fluid dispensing apparatus of the class described for filling a container with pressurized fluid, comprising,
a filling chamber having connection with a source of pressurized fluid, a solenoid actuated filling control valve operable to selectively emit pressurized fluid into the filling chamber, means associated with said filling chamber for connecting the same with the container to be filled, a delayed pressure chamber communicating with said filling chamber, solenoid actuated pressure control valve means operable to selectively control the emission of fluid from the filling chamber to said pressure chamber, pressure measuring means in said pressure chamber, vent means in said pressure chamber for venting the same to atmosphere, timing means for automatically and alternately operating the said two named solenoid actuated valve means, and pressure responsive switch means in said pressure chamber for disrupting the sequential energization of the solenoid operated valve means by the said timer means at a predetermined pressure; said switch means additionally opening said pressure control valve means until the pressure in the container is vented off to the said predetermined pressure via said vent means.
References Cited in the file of this patent UNITED STATES PATENTS Number Name Date 1,763,107 Spencer June 10, 1930 2,145,830 Espersen Ian. 31, 1939
|Cited Patent||Filing date||Publication date||Applicant||Title|
|US1763107 *||Mar 31, 1928||Jun 10, 1930||Raytheon Inc||Regulating system|
|US2145830 *||Oct 19, 1937||Jan 31, 1939||Hygrade Sylvania Corp||Method and apparatus for manufacturing gas-filled discharge tubes|
|Citing Patent||Filing date||Publication date||Applicant||Title|
|US3026916 *||Dec 21, 1959||Mar 27, 1962||Keith Kennedy||Mechanism to control inflation of tires|
|US3799218 *||Mar 27, 1972||Mar 26, 1974||Douglass M||Apparatus for dispensing compressed gas at programmed pressure and volume|
|US4506708 *||Dec 3, 1982||Mar 26, 1985||Toyota Jidosha Kabushiki Kaisha||Air pressure filling system for tires|
|US4537212 *||Dec 12, 1983||Aug 27, 1985||Shell Oil Company||Method and system for tank overfill protection|
|US6561017||Dec 4, 2001||May 13, 2003||Dana Corporation||Tire inflation method|
|US6604414||Dec 4, 2001||Aug 12, 2003||Dana Corporation||Supply and tire pressure sensing apparatus and method|
|US6666078||Dec 4, 2001||Dec 23, 2003||Dana Corporation||Target tire pressure learning method|
|US6865930||Mar 31, 2003||Mar 15, 2005||Dana Corporation||Tire inflation method|
|US6868719||Dec 4, 2001||Mar 22, 2005||Dana Corporation||Tire pressure monitoring method|
|US6894607||Dec 3, 2001||May 17, 2005||Dana Corporation||Tire pressure management system valve integrity verification method|
|US7051585||Mar 31, 2003||May 30, 2006||Dana Corporation||Supply and tire pressure sensing apparatus and method|
|US7265659||Mar 15, 2005||Sep 4, 2007||Dana Corporation||Tire pressure management system valve integrity verification method|
|US7538661||Aug 15, 2007||May 26, 2009||Dana Heavy Vehicle Systems Group, Llc||Tire pressure management system valve integrity verification method|
|US20060007007 *||Mar 15, 2005||Jan 12, 2006||Claussen Stephen P||Tire pressure management system valve integrity verification method|
|US20070290826 *||Aug 15, 2007||Dec 20, 2007||Claussen Stephen P||Tire pressure management system valve integrity verification method|
|USRE41756||Mar 22, 2007||Sep 28, 2010||Dana Heavy Vehicle Systems Group, Llc||Tire pressure monitoring method|
|U.S. Classification||141/115, 137/225, 137/624.13, 141/197, 222/3|
|International Classification||F17C13/02, F17C13/00|