US1205787A - Flow-meter. - Google Patents

Flow-meter. Download PDF

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US1205787A
US1205787A US6070315A US6070315A US1205787A US 1205787 A US1205787 A US 1205787A US 6070315 A US6070315 A US 6070315A US 6070315 A US6070315 A US 6070315A US 1205787 A US1205787 A US 1205787A
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flow
compartments
tube
orifice
meter
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US6070315A
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Fay Harry Rosencrants
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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01FMEASURING VOLUME, VOLUME FLOW, MASS FLOW OR LIQUID LEVEL; METERING BY VOLUME
    • G01F1/00Measuring the volume flow or mass flow of fluid or fluent solid material wherein the fluid passes through a meter in a continuous flow
    • G01F1/05Measuring the volume flow or mass flow of fluid or fluent solid material wherein the fluid passes through a meter in a continuous flow by using mechanical effects
    • G01F1/20Measuring the volume flow or mass flow of fluid or fluent solid material wherein the fluid passes through a meter in a continuous flow by using mechanical effects by detection of dynamic effects of the flow
    • G01F1/22Measuring the volume flow or mass flow of fluid or fluent solid material wherein the fluid passes through a meter in a continuous flow by using mechanical effects by detection of dynamic effects of the flow by variable-area meters, e.g. rotameters

Definitions

  • My invention relates to meters for indicating the rate of flow of either opaque or transparent liquids through a pipe line, and is primarily intended for use in indicating the rate of flow of oil to the burners of oil burning boilers, although it may be used in a variety of places, such as in the feed-water lines of individual boilers, in the cooling water lines to transformers, gas engines, and almost any place where a small rate of flow ispto be indicated.
  • My invention is fully described in the following specification, of which the accompanying drawings form a part, in which like characters refer to like parts in each of the views, and in which :M
  • Figure 1 is a central vertical sectional view through a meter constructed in accordance with my invention
  • Fig. 2 is a section taken on the line 2-2 of Fig. 1
  • Fig. 3 is a section taken on the line 3 3 of Fig. 1.
  • a spindle 12 Inciding with the axis of the casing is a spindle 12 supported in suitable guides 13 and carrying a brass button 14 rigidly secured thereto of slightly less diameter than the smallest diameter of the orifice 11.
  • rIhe normal Zero fiow position of the button 14C is in the smallest section of the perennial 11 and it is held there by means of a conical spring 15 the large end of which bears on the partition 9 and the small end of which bears on a disk 16 mounted rigidly on .the spindle 12.
  • the orifice button 14 is forced in the direction of flow against the force of the spring 15, the flow being from the small end of the orifice 11 toward the large end thereof.
  • the annular space around the button increases, and there is a definite difference of pressure between the two sides of the orifice 11 for each rate'of flow.
  • a pipe 25 Threaded into the casing 17 to enter the compartment 19 is a pipe 25 on the upper end of which is threaded a casing 26 having two compartments 27 and 28 formed by a partition 29 provided with a port 30 at the top thereof, the pipe 25 connecting with the compartment 28, and said pipe carries a plate 31 provided with the graduations of a scale.
  • the compartment 27 is connected with the compartment 18 by means of a glass tube 32 which extends nearly to the bottom ofthe compartment 18 and isvprovided with a hard wood plug 33 having a small bore 34 therethrough, the lower end of the tube 32 be ing submerged in mercury shown at 35.
  • I provide a iioat 36 within the glass tube of a suitable length whereby the upper end thereof registers with the zero graduation on the scale plate 31 when the normal flow is at Zero.
  • the pipe 25, and the tube 32 are filled with water or oil,l or whatever the liquid passing through my meter, with the exception of' the space occupied by the mercury and by the iioat, the latter being preferably made 'of hard rubber and designed to always rest upon the surface of the mercury within the tube 32. I prefer, however, to
  • the pressure in compartment 7 is commur the glass tube 32 to rise until the column of mercury measured from the mercury surface outside to the mercury surface inside the glass tube 32 is equivalent to the difference of pressure in 7 and 8.
  • the spring resisted button 14 performs the function of makin@r it possible to use a much larger oriiice which as a consequence will not become easily stopped up), than the corresponding unobstructed orifice for equal scale readings would allow.
  • a flow meter comprising a casing arranged in a pipe line, a partition dividing said casing into compartments and provided with a relatively small orifice diverging in the direction of flow, a movable button substantially closing the smallest portion of said orifice at Zero rate of flow and the position of which is controlled by the difference of the pressures in the two compartments, means for yieldingly resisting the movei ,2053er ment of said button, a vertical pipe connected with one yof said compartments, a
  • mercury tube connected with the other of said compartments, a scale arranged alongside of said mercury tube, and a supplemental casing joining the tops of said pipe and tube.
  • a iow meter comprising a casing arranged in a pipe line, a partition dividing said casing into compartments and provided with a relatively small orifice diverging in thedirection of flow, a movable button substantially closing the smallest portion of said orifice at Zero rate of flow and the position of which is controlled by the difference of the pressures in the two compartments, means for yieldingly resisting the movement of said button, a tube connected with one of said compartments, a mercury Well at the bottom of said tube, a wate reservoir connected with the upper end oi said tube, and means for leading the liquid being measured to said mercury well and to the surface of the water in said reservoir to raise or lower the ⁇ mercury in said tube as the dili'erenceof pressures in said compartments varies.
  • a flow meter comprising al casing arranged in a pipe line,l a partition dividing said casing into compartments and provided with a relatively small orifice diverging in the direction of flow, a movable button substantially closing the smallest portion of said orifice at Zero rate of flow and the position of which is controlled by the diiference in the pressures in the two compartments, means for yieldingly resisting the movement of said button, a vertical pipe connected with one of said compartments, means for controlling the flow to said pipe, a mercury tube connected with the other of said compartments, and a supplemental casing joining the tops of said pipe and tube.
  • a flow meter comprising a casing arranged in a pipe line, a partition dividing said casing into compartments and provided with a relatively small orifice diverging in the direction of flow, a movable button substantially closing the smallest portion of said orifice at Zero rate of flow and the position of which is controlled by the difference in the pressures in the two compartments, means for yieldingly resisting the movement of said button, a vertical pipe connected with one of said compartments, a mercury tube connected with the other of said compartments, means for controlling the flow to said tube, and a supplemental caing joining the tops of said pipe'and tu e.
  • a How meter comprising a casing arranged in a pipe line, a partition dividing said casing into compartments and provided with a relatively small orifice diverging in the direction of flow, a slidably mounted rod projected through said orifice, a button car- Iied by saidrod, means for normally maintaining said button :it the smallest portion of said orifice in a yielding manner, a vertical pipe connected with one of said compartments, a mercul)v tube connected with the othenof said compartments, and a supplemental casing joining the tops of saidpipe and tube,' the position of said button with respect to said orifice being controlled

Description

F. H. ROSENCRANTS.
FLOW METER.
APPLICATION mw Nov 1o. |915.
1 S205;?7.. Panted Nov., 21, 1916.
vi srs aas-rr orrrp- FAY HARRY ROSENCRANTS, 0F CORVALLIS, OREGON.
FLOW-METER.
Application filed November 10, 1915.
To o/,ZZ whom t may concern:
Be it known that I, Fair H. RosnNcnANTs, a citizen of the United States, and a resident of Corvallis, in the county of Benton and State of Oregon, have invented certain new and useful Improvements in Flow-Meters, of which the following is a specification.
My invention relates to meters for indicating the rate of flow of either opaque or transparent liquids through a pipe line, and is primarily intended for use in indicating the rate of flow of oil to the burners of oil burning boilers, although it may be used in a variety of places, such as in the feed-water lines of individual boilers, in the cooling water lines to transformers, gas engines, and almost any place where a small rate of flow ispto be indicated. My invention is fully described in the following specification, of which the accompanying drawings form a part, in which like characters refer to like parts in each of the views, and in which :M
Figure 1 is a central vertical sectional view through a meter constructed in accordance with my invention; Fig. 2 is a section taken on the line 2-2 of Fig. 1; and Fig. 3 is a section taken on the line 3 3 of Fig. 1.
In the drawings forming a part of this application I have shown a casing 4 screw threaded internally at each end to receive inlet and outlet pipes 5 and 6 and divided into two compartments 7 and 8 by means of a partition 9, which partition is drilled and threaded to receive a nipple 10 having a diver-ging orifice 11 therethrough.
Coinciding with the axis of the casing is a spindle 12 supported in suitable guides 13 and carrying a brass button 14 rigidly secured thereto of slightly less diameter than the smallest diameter of the orifice 11. rIhe normal Zero fiow position of the button 14C is in the smallest section of the orice 11 and it is held there by means of a conical spring 15 the large end of which bears on the partition 9 and the small end of which bears on a disk 16 mounted rigidly on .the spindle 12. As fiow takes place, the orifice button 14 is forced in the direction of flow against the force of the spring 15, the flow being from the small end of the orifice 11 toward the large end thereof. As the button 14 is moved by the flow the annular space around the button increases, and there is a definite difference of pressure between the two sides of the orifice 11 for each rate'of flow.
Specification of Letters Patent.
Patented Nov. 211, illvllti.
ySerial No. 60,703.
-tion 24.
Threaded into the casing 17 to enter the compartment 19 is a pipe 25 on the upper end of which is threaded a casing 26 having two compartments 27 and 28 formed by a partition 29 provided with a port 30 at the top thereof, the pipe 25 connecting with the compartment 28, and said pipe carries a plate 31 provided with the graduations of a scale.
Through suitable stuffing-boxes, the compartment 27 is connected with the compartment 18 by means of a glass tube 32 which extends nearly to the bottom ofthe compartment 18 and isvprovided with a hard wood plug 33 having a small bore 34 therethrough, the lower end of the tube 32 be ing submerged in mercury shown at 35. I provide a iioat 36 within the glass tube of a suitable length whereby the upper end thereof registers with the zero graduation on the scale plate 31 when the normal flow is at Zero.
When iiow occurs the several compartments, the pipe 25, and the tube 32 are filled with water or oil,l or whatever the liquid passing through my meter, with the exception of' the space occupied by the mercury and by the iioat, the latter being preferably made 'of hard rubber and designed to always rest upon the surface of the mercury within the tube 32. I prefer, however, to
fill the glass tube 32 and the compartment' 27 with water even though oil is the liquid being measured, in order that the tube 32 will be transparent at all times. The oil,
.being lighter than the water, floats on top and, as the mercury rises or falls in the lass tube 32, the compartment 27 accommo,
' fore the meter is put into operation.
The pressure in compartment 7 is commur the glass tube 32 to rise until the column of mercury measured from the mercury surface outside to the mercury surface inside the glass tube 32 is equivalent to the difference of pressure in 7 and 8. As the flow from 7 to 8 through orifice 11 increases this difference of pressure increases and causes the mercury to rise correspondingly higher in glass tube 32, thus indicating the flow on scale 31. The spring resisted button 14; performs the function of makin@r it possible to use a much larger oriiice which as a consequence will not become easily stopped up), than the corresponding unobstructed orifice for equal scale readings would allow. llt also performs the function of increasing the effective areal of the orice 11 with increasing flow resulting in a scale the graduations of which are much more desirable than can be obtained with a plain orilice meter inasmuch as a given increase of flow at low rates of flow gives nearly the same increase in the height of the mercury column as would the same, increase of flow at high rates of flow.
The construction and arrangement of parts drawn adapts itself to flow from right to left in a horizontal pipe only, but it will Y be obvious that 1' do not desire to restrict myself to this construction, as the same principles may be incorporated in meters so constructed as to adapt them to existing conditions such as flowA in vertical pipes either up or down or from left to right in a horizontal pipe. Neither do l desire to restrict myself to a liXed and unalterable arrangement of parts in a meter for any given conditions, as Avarious modifications may suggest themselves or become desirable, and 1 reserve the right to all such changes as come within the spirit of my invention and Awithin the scope of the appended claims.
Having fully described my invention, what I claim as new, and desire to secure byLetters Patent, is
1. A flow meter, comprising a casing arranged in a pipe line, a partition dividing said casing into compartments and provided with a relatively small orifice diverging in the direction of flow, a movable button substantially closing the smallest portion of said orifice at Zero rate of flow and the position of which is controlled by the difference of the pressures in the two compartments, means for yieldingly resisting the movei ,2053er ment of said button, a vertical pipe connected with one yof said compartments, a
mercury tube connected with the other of said compartments, a scale arranged alongside of said mercury tube, and a supplemental casing joining the tops of said pipe and tube.
2. A iow meter, comprising a casing arranged in a pipe line, a partition dividing said casing into compartments and provided with a relatively small orifice diverging in thedirection of flow, a movable button substantially closing the smallest portion of said orifice at Zero rate of flow and the position of which is controlled by the difference of the pressures in the two compartments, means for yieldingly resisting the movement of said button, a tube connected with one of said compartments, a mercury Well at the bottom of said tube, a wate reservoir connected with the upper end oi said tube, and means for leading the liquid being measured to said mercury well and to the surface of the water in said reservoir to raise or lower the `mercury in said tube as the dili'erenceof pressures in said compartments varies.
3. A flow meter, comprising al casing arranged in a pipe line,l a partition dividing said casing into compartments and provided with a relatively small orifice diverging in the direction of flow, a movable button substantially closing the smallest portion of said orifice at Zero rate of flow and the position of which is controlled by the diiference in the pressures in the two compartments, means for yieldingly resisting the movement of said button, a vertical pipe connected with one of said compartments, means for controlling the flow to said pipe, a mercury tube connected with the other of said compartments, and a supplemental casing joining the tops of said pipe and tube.
11. A flow meter, comprising a casing arranged in a pipe line, a partition dividing said casing into compartments and provided with a relatively small orifice diverging in the direction of flow, a movable button substantially closing the smallest portion of said orifice at Zero rate of flow and the position of which is controlled by the difference in the pressures in the two compartments, means for yieldingly resisting the movement of said button, a vertical pipe connected with one of said compartments, a mercury tube connected with the other of said compartments, means for controlling the flow to said tube, and a supplemental caing joining the tops of said pipe'and tu e.
5. A How meter, comprising a casing arranged in a pipe line, a partition dividing said casing into compartments and provided with a relatively small orifice diverging in the direction of flow, a slidably mounted rod projected through said orifice, a button car- Iied by saidrod, means for normally maintaining said button :it the smallest portion of said orifice in a yielding manner, a vertical pipe connected with one of said compartments, a mercul)v tube connected with the othenof said compartments, and a supplemental casing joining the tops of saidpipe and tube,' the position of said button with respect to said orifice being controlled
US6070315A 1915-11-10 1915-11-10 Flow-meter. Expired - Lifetime US1205787A (en)

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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2755664A (en) * 1952-12-27 1956-07-24 William P Chapman Fluid flow meter
US2775890A (en) * 1954-01-20 1957-01-01 Cloyd D Waldron Fluid flowmeter
US2826216A (en) * 1951-09-14 1958-03-11 William Waterman Fluid metering valve
US6619138B2 (en) * 1999-07-07 2003-09-16 Westinghouse Air Brake Technologies Corporation Apparatus for dynamically adjusting size of an orifice to increase accuracy in measuring the rate of air flow

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2826216A (en) * 1951-09-14 1958-03-11 William Waterman Fluid metering valve
US2755664A (en) * 1952-12-27 1956-07-24 William P Chapman Fluid flow meter
US2775890A (en) * 1954-01-20 1957-01-01 Cloyd D Waldron Fluid flowmeter
US6619138B2 (en) * 1999-07-07 2003-09-16 Westinghouse Air Brake Technologies Corporation Apparatus for dynamically adjusting size of an orifice to increase accuracy in measuring the rate of air flow

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