US114694A - John p - Google Patents

John p Download PDF

Info

Publication number
US114694A
US114694A US114694DA US114694A US 114694 A US114694 A US 114694A US 114694D A US114694D A US 114694DA US 114694 A US114694 A US 114694A
Authority
US
United States
Prior art keywords
case
valve
water
ports
plug
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
Publication date
Application granted granted Critical
Publication of US114694A publication Critical patent/US114694A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • GPHYSICS
    • G01MEASURING; TESTING
    • G01FMEASURING VOLUME, VOLUME FLOW, MASS FLOW OR LIQUID LEVEL; METERING BY VOLUME
    • G01F3/00Measuring the volume flow of fluids or fluent solid material wherein the fluid passes through the meter in successive and more or less isolated quantities, the meter being driven by the flow
    • G01F3/02Measuring the volume flow of fluids or fluent solid material wherein the fluid passes through the meter in successive and more or less isolated quantities, the meter being driven by the flow with measuring chambers which expand or contract during measurement
    • G01F3/04Measuring the volume flow of fluids or fluent solid material wherein the fluid passes through the meter in successive and more or less isolated quantities, the meter being driven by the flow with measuring chambers which expand or contract during measurement having rigid movable walls
    • G01F3/06Measuring the volume flow of fluids or fluent solid material wherein the fluid passes through the meter in successive and more or less isolated quantities, the meter being driven by the flow with measuring chambers which expand or contract during measurement having rigid movable walls comprising members rotating in a fluid-tight or substantially fluid-tight manner in a housing
    • G01F3/08Rotary-piston or ring-piston meters

Definitions

  • FIG. 4 is an elevation of the front head of the case, showing the inner side.
  • Figs. 5 to l0 are illustrations in detail of the valve and-trigger, to be hereinafter referred to.
  • Fig. ll represents a modification in the construction of the valve.
  • Fig. l2 is an elevation, partly in section, showing a mod iication inthe construction ofthe meter.
  • Fig. 13 is an axial section of the meter, shown in elevation in Fig. l2.
  • the operative parts of the meter are inclosed in a short cylindrical case, A, closed by heads at each end, the front one of which is marked A1, and the rear one A2.
  • a solid diaphragm, B is formed in the rear end of the case, coming in contact with the rear head A2, as indicated in Fig. 2.
  • an oscillating disk, C is arranged, which is constructed with a circumferential flange, O1, of such width as to snugly it between the diaphragm and head of the case.
  • the diameter of this disk is considerably less than that of the bore of the case, so as to form an annular chamber, D, between the two.
  • This chamber is divided by a partition, A3, secured to the rim of the case, and an enlargement or wing, O2, on the oscillating disk.
  • a partition A3, secured to the rim of the case, and an enlargement or wing, O2, on the oscillating disk.
  • channels B1 and B2 one upon each side, which encircle the valve passing through the center, and pass thence outward, and communicate with the water chamber D, upon opposite sides of the partition A3, a port, b, being bored through the diaphragm to connect the channel B2 upon its rear side with the said chamber upon the opposite side.
  • the iow of the iuid passing through the meter is controlled by a valve, which passes through the center of the case and oscillating disk, forming the axis upon which the latter turns.
  • rIhe valve is composed of acylindrical hollow case, E, iitted with a tubular plug, F, which communicates at one end with the eductionpipe G, and ⁇ at the other end with the eduction-'pipe Vnot shown.
  • the tubular plug is constructed with a solid diagonal partition, F', and the end connecting with the pipe G has two induction-ports, f and j, cut through the shell, whilek upon the other ⁇ side of the partition are formed the eductionports gand g. Iheinduction and eduction ports are formed upon opposite sides ofthe plug.
  • Oorresponding induction-ports e and el and eduction-ports d and d are cut through the case E, which upon the outside communicate with the annular portion of the channels B1 and B2, respectively.
  • the arrangementof these ports in the plug and its case with reference to one another is such that when the induction-ports fe coincide so as to admit the iiuid into the channel B2, as shown in Fig. 2, the induction-ports l time the induction-ports d and g coincide to discharge the fluid from the channel B1, while communication between the eduction-ports d and g is shut oi'. In reversing the valve the ports assume the position shown in Fig.
  • rEhe valve E F turns during the greater portion of the stroke with the oscillating disk, to which it is, during that time, locked by means of a trigger, H, the enlargedV endh of which enters the recess c2 in the rim of the disk, and one or the other of corresponding recesses c2 and e3 in the weighted arm El of the valve-ease, while its reduced end h1 projects into a notch,
  • the trigger is constructed with aprojecting stud, h2, which plays in a groove, H', formed in the interior side of the head A1.
  • This groove is of the proper length to permit of the required oscillations of the disk C, and is for the greater portion concentric with the axis of the latter 5 but near each end it is turned outward, as best seen in Fig. 4, in order to slide the trigger outward until both the plug and its case are unlocked from the disk.
  • the meter being always arranged in the position substantially as shown in Fig.
  • the diaphragm in the case is dispensed with, and the channels B1 and B2 are formed in the oscillating disk, which is shown as constructed in the form of ra wheel with spokes, two of which are made hollow to constitute the water-passages.
  • the ports of the valve-case open into an annular groove formed either in the case itself, as shown, or in the hub of the wheel, so that the ports will always communicate with the channel Bl and B2.
  • the valve shown in Fig. 11 differs from that heretofore described, in having an annular chamber, E2, formed in the metal of the case, into which chamber the water is discharged instead of into the other end of the plug.
  • the water iows from the induction-pipe G, through the ports e and f of the valve and channel B2, into the water-chamber D, driving the oscillating disk in the direction of the arrows in Fig. I, so as to force the water upon the other side of the wing G2, through the channelB1 and ports d and g of the valve, into the exhaust end of the plug F.
  • the valve On arriving at the end of the stroke in this direction, the valve is reversed in the manner set forth, and the water then lows, through the ports f1 and el and channel B1, into the opposite end of the water-chamber D, driving the oscillating disk in the opposite direction to that indicated in Fig. I, and causing it to force out the water before its wing U2, through the channel B2 and ports d and g.
  • the waterchamber D must be made to hold a definite quantity of water, by weight or measure; and a suitable registering apparatus is to be connected with one of the moving parts of the meter to indicate the number of oscillations of the same, and the quantity of water passed through meter.
  • the valve composed of the hollow case E and tubular plug F divided by a partition, F1, and containing two sets of induction-ports, ef and e1 f1, and two sets of eduction-ports, d y and d g', to operate substantially as set forth.
  • the trigger H and camgroove H in the head Al of the case all arranged to operate substantially as set forth.

Landscapes

  • Physics & Mathematics (AREA)
  • Fluid Mechanics (AREA)
  • General Physics & Mathematics (AREA)
  • Measuring Volume Flow (AREA)

Description

' 2'sh Sh 1. JOHN P., LINDSAY. m e Improvement in Water-Meters. No. 114,694,
Paiented May 9,187I
' zsh JOHN-P'. UNDSM.v ee shew Improvement in Water-Meters. INo. 114,694.
Patented May 9,1871.
MM M JOHN P. LINDSAY, OF NEW YORK, N. Y.
IMPROVEMENT EN WATER-METERS.
Specification forming part of Letters Patent No. 14,694, dated May 9, 1871 application iled April 2o, 1871.
To all whom it may concer/n:
Be it known that I, J oHN P. LINDSAY, of the city, county, and State of New York, have invented certain Improvements in Tater-Meters; and I do hereby declare that the following is a full, clear, and exact description thereof, reference being had to the annexed drawing making a part of this specification, in which- Figure l represents a front elevation of the meter, portion of the front head being broken away to show the interior arrangement of the parts. Fig.v2 is an axial section, showing the valvel partly in elevation. Fig'. 3 is a rear ele-r vation, the rear head and the valve being removed to show the water-channels in the diaphra gm of the case. Fig. 4 is an elevation of the front head of the case, showing the inner side. Figs. 5 to l0 are illustrations in detail of the valve and-trigger, to be hereinafter referred to. Fig. ll represents a modification in the construction of the valve. Fig. l2 is an elevation, partly in section, showing a mod iication inthe construction ofthe meter. Fig. 13 is an axial section of the meter, shown in elevation in Fig. l2.
The same letters of reference are used in the different gures in the designation of identical parts.
This invention, relating to water-meters, consists in various novel features of construction, combination, and arrangement of parts, which will be generally described in the following description, and specifically pointed out in the claims.
The operative parts of the meter are inclosed in a short cylindrical case, A, closed by heads at each end, the front one of which is marked A1, and the rear one A2. A solid diaphragm, B, is formed in the rear end of the case, coming in contact with the rear head A2, as indicated in Fig. 2. In the space between this diaphragm and the front head A1 an oscillating disk, C, is arranged, which is constructed with a circumferential flange, O1, of such width as to snugly it between the diaphragm and head of the case. The diameter of this disk is considerably less than that of the bore of the case, so as to form an annular chamber, D, between the two. This chamber is divided by a partition, A3, secured to the rim of the case, and an enlargement or wing, O2, on the oscillating disk. In the diaphragm B are formed channels B1 and B2, one upon each side, which encircle the valve passing through the center, and pass thence outward, and communicate with the water chamber D, upon opposite sides of the partition A3, a port, b, being bored through the diaphragm to connect the channel B2 upon its rear side with the said chamber upon the opposite side. The iow of the iuid passing through the meter is controlled by a valve, which passes through the center of the case and oscillating disk, forming the axis upon which the latter turns. rIhe valve is composed of acylindrical hollow case, E, iitted with a tubular plug, F, which communicates at one end with the eductionpipe G, and `at the other end with the eduction-'pipe Vnot shown. The tubular plug is constructed with a solid diagonal partition, F', and the end connecting with the pipe G has two induction-ports, f and j, cut through the shell, whilek upon the other `side of the partition are formed the eductionports gand g. Iheinduction and eduction ports are formed upon opposite sides ofthe plug. Oorresponding induction-ports e and el and eduction-ports d and d are cut through the case E, which upon the outside communicate with the annular portion of the channels B1 and B2, respectively. The arrangementof these ports in the plug and its case with reference to one another is such that when the induction-ports fe coincide so as to admit the iiuid into the channel B2, as shown in Fig. 2, the induction-ports l time the induction-ports d and g coincide to discharge the fluid from the channel B1, while communication between the eduction-ports d and g is shut oi'. In reversing the valve the ports assume the position shown in Fig. 6, and water now iiows into the channel B1, and is discharged from the channel B2. rlhat portion of the case E of the valve which protrudes through the oscillating disk O is constructed with a weighted wing or arm, E1, by means of which the case is oscillated on the Ahollow plug, held stationary, for the time being, at the end of each stroke of the oscillating' disk to change the position of the ports, and, consequently, reverse the iiow of and el do not communicate 5 at the sameA the water through the meter. The extent of movement of the valve-case on the plug is controlled by studs c and 01 on the disk. rEhe valve E F turns during the greater portion of the stroke with the oscillating disk, to which it is, during that time, locked by means of a trigger, H, the enlargedV endh of which enters the recess c2 in the rim of the disk, and one or the other of corresponding recesses c2 and e3 in the weighted arm El of the valve-ease, while its reduced end h1 projects into a notch,
f2, cut in a collar of the plug F. The trigger is constructed with aprojecting stud, h2, which plays in a groove, H', formed in the interior side of the head A1. This groove is of the proper length to permit of the required oscillations of the disk C, and is for the greater portion concentric with the axis of the latter 5 but near each end it is turned outward, as best seen in Fig. 4, in order to slide the trigger outward until both the plug and its case are unlocked from the disk. The meter being always arranged in the position substantially as shown in Fig. l, the moment the valve-case is thus released from the oscillating disk its weighted arm E1 will cause it to turn on the plug to the extent permitted by one or the other of the studs c or c1, by which the farther movement of the arm is stopped. The valve having thus been reversed, the oscillating disk begins to move in the opposite direction, and the plug and valve-case are again locked to it, and travel with it to the end of the return stroke. A projection, a, on the head A1, extends into a groove, f3, in the plug F, as shown in Figs. 2, 7, and 8. The ends of this groove do not meet, it being only made of just sufficient length to permit the plug to travel with its inclosingcase up to the moment when it is released from the disk C. At that moment the projection c comes in contact with the metal between the ends of the groove f3, and holds the plug stationary 'while the case turns on it.
In the modification shown in Figs. 12 and 13 the diaphragm in the case is dispensed with, and the channels B1 and B2 are formed in the oscillating disk, which is shown as constructed in the form of ra wheel with spokes, two of which are made hollow to constitute the water-passages. In this case the ports of the valve-case open into an annular groove formed either in the case itself, as shown, or in the hub of the wheel, so that the ports will always communicate with the channel Bl and B2. These now open into the water-chamber D on opposite sides of the wing G2 of the oscillating disk C.
The valve shown in Fig. 11 differs from that heretofore described, in having an annular chamber, E2, formed in the metal of the case, into which chamber the water is discharged instead of into the other end of the plug. In the position of the parts shown in Fig. 2, the water iows from the induction-pipe G, through the ports e and f of the valve and channel B2, into the water-chamber D, driving the oscillating disk in the direction of the arrows in Fig. I, so as to force the water upon the other side of the wing G2, through the channelB1 and ports d and g of the valve, into the exhaust end of the plug F. On arriving at the end of the stroke in this direction, the valve is reversed in the manner set forth, and the water then lows, through the ports f1 and el and channel B1, into the opposite end of the water-chamber D, driving the oscillating disk in the opposite direction to that indicated in Fig. I, and causing it to force out the water before its wing U2, through the channel B2 and ports d and g. The waterchamber D must be made to hold a definite quantity of water, by weight or measure; and a suitable registering apparatus is to be connected with one of the moving parts of the meter to indicate the number of oscillations of the same, and the quantity of water passed through meter.
What I claim as my invention, and desire to secure by Letters Patent, is
I. A water-meter containing a circumferential measuring-chamber, D, formed between the case and an oscillating disk, U, into which chamber the water flows alternately on one side or the other of a partition, A3, to be discharged by the wing C2 of the oscillating disk at the opposite side of such partition, substantially as set forth.
2. A water-meter containing the circumferential divided water-chamber A A3, in which an oscillating wing, G1, operates, and a valve arranged centrally within the chamber D to induct the water from the center to the circumference, and discharge it from the circumference through the center of the meter, substantially in the manner set forth.
3. The valve, composed of the hollow case E and tubular plug F divided by a partition, F1, and containing two sets of induction-ports, ef and e1 f1, and two sets of eduction-ports, d y and d g', to operate substantially as set forth.
4. The combination of the oscillating disk C, valve-case E, and tubular-divided plug F F', arranged relatively to one another, as set forth, so that they will move conjointly during the greater portion of each stroke of the disk, and be released from one another near the end of each stroke, to permit the valve-case to turn on the plug held stationary for the time being to reverse the position of the stroke.
5. In combination with the notches e2 and e3 in the arm E1 of the valve-case E, and notch]02 in the plug F, the trigger H and camgroove H in the head Al of the case, all arranged to operate substantially as set forth.
6. The combination of the oscillating disk C, wing C2 thereon, and partition Al in the water-chamber D, substantially as set forth.
In testimony whereofI have signed my name to this specification in the presence of two subscribing witnesses.
Vitnesses: JOHN P. LINDSAY.
B. Enw. J. ErLs, C. N. GLAUsEN.
US114694D John p Expired - Lifetime US114694A (en)

Publications (1)

Publication Number Publication Date
US114694A true US114694A (en) 1871-05-09

Family

ID=2184155

Family Applications (1)

Application Number Title Priority Date Filing Date
US114694D Expired - Lifetime US114694A (en) John p

Country Status (1)

Country Link
US (1) US114694A (en)

Similar Documents

Publication Publication Date Title
US114694A (en) John p
US2453553A (en) Measuring valve mechanism
US211769A (en) Improvement in rotary water-meters
US211582A (en) Improvement in rotary water-meters
US643432A (en) Liquid-meter.
US111624A (en) Improvement in water-meters
US676656A (en) Liquid-measuring mechanism.
US215478A (en) Improvement in valves
US103990A (en) Improvement in liquid-meters
US127942A (en) Improvement in water-meters
US313860A (en) Liquid-meter
US723686A (en) Pump.
US353703A (en) Water meter with revolving non rotating piston
US199352A (en) Improvement in piston water-meters
US409275A (en) culmer
JP2019044767A (en) Fuel amount adjustment device of high-pressure injection system
US126626A (en) Improvement in fluid-meters
US457295A (en) Rotary fluid-meter
US119671A (en) Improvement in water-meters
US175659A (en) Improvement in water-meters
US121937A (en) Improvement in meters
US203984A (en) Improvement in piston water-meters
US131929A (en) Improvement in water-meters
US141982A (en) Improvement in rotary valves and cut-offs
US173024A (en) Improvement in fluid-meters