US3292733A

US3292733A - Fluid silencing improvements for pumps

Info

Publication number: US3292733A
Authority: US
Inventors: Wilhelm S Everett; John F Richards
Original assignee: Individual
Current assignee: Individual
Priority date: 1964-07-08
Filing date: 1964-07-08
Publication date: 1966-12-20
Anticipated expiration: 1983-12-20

Description

United States Patent 3,292,733 FLUID SHLENCING IMPROVEMENTS FOR PUMPS Wilhelm S. Everett, 126 W. Santa Barbara St., Santa Paula, Calif. 93060, and John F. Richards, Santa Paula, Calif; said Richards assignor to said Everett Filed July 8, 1964, Ser. No. 381,058 4 Claims. (Cl. 181-57) This invention generally relates to fluid silencing devices which may advantageously be employed for coupling to various types of pumps. More particularly, the invention relates to an improved silencing device or acoustic filter especially adapted foni n-line use with the suction side of a centrifugal, turbinefor jio sitiv'e"displacement pump todampen out noises and pressure pulsations caused thereby, but which may also have application in any tynshoifiuid"systemawhgpemnpressure pulsations characterize the movement of the fluidl1lh thatfllndesirable noise or sound is produced.

Centrifugal pumps or turbine pumps, for example usually create undesirable noise levels in view of their inherent pulsating type action. As well as causing vibrations and valve chatter in the pipe line systems, interfering with pressure-sensitive meters and the like, such pulsations cause direct noises which may be bothersome to human comfort, particularly in confined areas. Furthermore, such noises may result in the detection of desirably silent apparatus.

With these thoughts in mind, it is an object of the present invention to provide an improved acoustic filter of compact construction for use in-line on the suction side of centrifugal or turbine pumps or with other equivalent apparatus.

Another object of the present invention is to provide an improved acoustic filter which is simple in its construction, embodies a limited number of movable parts, and which may readily be repaired or replaced through convenient disassembly and assembly procedures.

Still another object of the present invention is to provide an improved suction type acoustic filter, particularly of a type which may be advantageously employed with pumps and compressors and which may be readily fabricated without the need of special tooling and without the need of extra-precise tolerances being maintained.

Still another object of the present invention is to provide an improved pump and acoustic filter combination, in which the pump pulsations and the noises resulting therefrom may be substantially eliminated or sufficiently dampened such that they are not appreciably detectable, annoying to the human ear, and will not cause vibration or chatter in the pipeline systems.

These and other objects and advantages of the present invention are generally achieved by providing an acoustic filter for use on the upstream or suction side of a centrifugal pump or equivalent apparatus, including a cylindrical casing with means defining an inlet circumferential opening proximate to one end thereof.

Tubular wall means are disposed within the casing to define a passage extending axially from the other end of the casing to a point near the one end embodying the inlet opening. Other wall means are disposed within the casing to define an annular passage of gradually decreasing radius communicating from the circumferential opening to the point where the axial passage terminates within the casing.

In accordance with a feature of the present invention, an. annular chamber is defined within the casing, radially exte-riorly of the axial passage. The chamber communicates with the axial passage near the point that the annular passage connects with same, the axial passage forming a venturi throat section with respect to the chamber "ice at said point, whereby fluid is drawn from the chamber into the axial passage as it flows therethrough.

Preferably, a second volume or chamber communicates with the axial passage also near the throat section of the venturi; such second volume or chamber is in series with the first volume or chamber so that increased attenuation or dampening of the pulsations characterizing the fluid will be accomplished in a manner that will become clearer as the specification proceeds.

A better understanding of the present invention will be had by reference to the drawing, showing a partially schematic sectional view of the improved suction acoustic filtering device according to the present invention embodied in an application wherein it is coupled to a cen trifugal pump. (It will be understood that the term centrifugal pump is used illustratively since the present invention is also applicable to turbine and positive displacement pumps or equivalent apparatus as heretofore mentioned.)

Referring now to the drawings, there is shown therein a group of components including an electric motor 10 having connected thereto a shaft 11 which extends axially through a discharge acoustic filter 12 into a centrifugal pump 13. Such components are well known and thus have been shown schematically.

As heretofore mentioned, the present invention however, is primarily directed towards the suction side of the centrifugal pump 13. Towards this end, there is provided a suction acoustic filter 14 which embodies a lower cover 15 covering the bottom end of a lower flow guide 16. The flow guide 16 is coupled with spacers 17 and bolts 18 to an upper flow guide 19. Thus, the spacers 17 maintain the lower flow guide 16 in a given spaced relationship to the upper flow guide 19. With such a construction, it will be appreciated that fluid may enter circumferentially into the annular passage defined between the lower flow guide 16 and upper flow guide 19 without any appreciable turbulence.

Under normal operating conditions, the acoustic filter 14 would normally be submerged in the particular fluid being pumped through the centrifugal pump 13. Although the fluid line is indicated as somewhat higher than the pump, it may vary and in many applications would merely be to a level extending anywhere from a point above the circumferential inlet opening to a point near the height of the centrifugal pump or at the height of the discharge acoustic filter.

A conical-shaped structure 20 co-functions with the upper surface of the upper flow guide 19 to define a passage which communicates with a volume or chamber 21 having disposed therein a float 22. The float 22 is connected to a normally open valve 23 disposed in a line 24 leading to atmosphere or to a vapor supply 25 as indicated.

The conical-shaped structure 20 forms the end portion of a tubular member 26 or axial passage which defines a venturi throat section adjacent structure 20 and communicates at its upper end with the inlet (not shown) to the centrifugal pump 13. The operation of the float 22 and coupled valve 23, as well as the function of the chamber 21, will be described further as the specification proceeds.

A second volume or chamber is defined partially by an end wall 27 closing off the first chamber 21. Assuming the first chamber and second chamber are formed from separate structural components, a ring member 28 may be provided for studs or bolts interconnecting the units. The second annular chamber will in turn be defined end wall 30 has provided therein a stud circle 31 for coupling the acoustic filter 14 to the centrifugal pump 13. The second chamber is indicated by the numeral 32.

Thus, the chamber 32 includes

end walls

27, 30, and the sidewalls 29, :as well as the upper portion of tubular member 26. The second chamber or volume similarly has disposed therein a float 33 designed to operate a. valve 34 connected in a line 35 extending to the vapor supply 25 as heretofore indicated. The second chamber 32 communicates through the opening 32 with the passage 26.

The present inventon may perhaps be more clearly understood by a description of its operation in the present application.

As heretofore mentioned, normally the acoustic filter portion 14 of the apparatus shown will be disposed in a sump or below the fluid level such that fluid will normally be disposed in the

chambers

21 and 32. As a consequence, as soon as the electric motor is started to drive the shaft 11 and the centrifugal pump 13, fluid will be drawn into the circumferential inlet opening in a manner as indicated by the arrows and thereafter up into the tubular axial passage 26. It will be appreciated that the fluid smoothly flows into the annular passage around the flow guide 16 with a gradually decreasing radius such that minimum turbulence occurs. Furthermore, by providing the cover 15, the noises caused by the centrifugal pump with its pulsing action will be cushioned since the greater noise level directed in the axial direction is blocked.

As the fluid flows into the passage 26 and the venturi section embodied therein, its increased velocity and accompanying dynamic head will tend to decrease the static pressure and in turn cause fluid from the

chambers

21 and 32 to be drawn into its flow path leading to the centrifugal pump. Thus, the fluid in the chamber 21 will gradually decrease in level with the result that vapor from the vapor supply 25 will be drawn through the normally open valve 23 in the line 24 into the chamber 21; at a certain point as the fluid decreases in level, the float valve 22 will operate to close off the valve 23 and prevent further vapor from entering into the chamber 21.

With proper design considerations, the fluid level in the chamber 21 and the vapor therein will collectively provide a degree of compressibility in that chamber which will tend to dampen out most pulsations on the downstream side of the centrifugal pump. Of course, the impedance action or characteristic of the passage 26 will also be co-functioning with the chamber 21 towards this end. Similarly, the chamber 32, which also communicates through the opening 32' with the venturi throat section of the passage 26 will co-function therewith as part of a filter network to dampen out the fluid pulsations created by the centrifugal pump. The chamber 32 and its related valve 34 operate in the same manner as the chamber 21 and valve 23.

Of course, the vapor supply may actually consist of atmospheric air depending upon the fluid being pumped. If air does not mix with the particular fluid being pumped and does not tend to become significantly entrained therein or to cause other harmful eflects, the

tubes

24 and 35 may merely extend to a point such that they communi- Gate with air. In the alternative, when explosive fluids are being pumped, for example, it is desirable to use a vapor supply in an enclosed vessel (which may be the vapor area above the liquid level in the tank in which the device is mounted) at a low pressure such that it will function in an equivalent manner to atmospheric air without the possibility of undesirable intermixture of fluids.

Under certain pressure conditions, the bulk modulus of elasticity of the fluid, taking into consideration the volume of the chamber, and the drop in pressure caused by the venturi, may eliminate the necessity of a separate vapor supply. Thus, under low pressure conditions, the bulk modulus of elasticity of some fluids decreases s'ufficiently to give the fluid itself a spongy characteristic, assuming a suflicient volume.

Where compact conditions require the

chambers

21 and 32 to be relatively small in size, however, it is usual- 4 ly desirable to include the flow control valves and vapor supply as indicated.

Although a centrifugal pump has been indicated, it: will be appreciated, as hereinbefore mentioned, that thesuction acoustic filter may be used with other types of.- pumps, for example, a turbine unit, or the like. Further more, although it is desirable that the suction acoustic: filter be mounted as close to the centrifugal pump as; possible, it is possible to have it mounted at a somewhat. different location on the upstream side of the centrifugal pump. However, the effectiveness is somewhat decreased.

It will be appreciated that the construction for thesuction acoustic filter is particularly adaptable for and advantageously employed with the in-line series of com ponents as indicated in the illustrative application. It; will also be evident that these components may be: readily dissassembled for cleaning and maintenance pur poses. Thus, the present invention conforms with the: objects as herein stated. Of course, many minor changes. and variations may be made in the structural details with-- out departing from the spirit and scope of the invention; as set forth in the following claims.

What is claimed is:

1. An acoustic filter comprising: a cylindrical casing; means defining a circumferential inlet opening proximate: one end of said casing; first tubular wall means within said casing defining a passage extending axially from the. other end of said casing towards a point near said one: end; second wall means within said casing defining an annular passage of gradually decreasing radius com-- municating from said circumferential opening to said. point; and, an annular chamber within said casing defined in part by said first wall means and positioned radially exteriorly of said first wall means, said annular chamber communicating with said first wall means near said point, said first wall means forming a venturi section with respect to said chamber at said point, whereby fluid is.

drawn from said chamber into said first wall 'means, and wherein said chamber functions to absorb pulsations that may characterize said fluid.

2. An acoustic filter, according to claim 1, and float valve means communicating with a source of low pres sure gas mounted in said chamber, said float valve means operating to close off said chamber to said gas supply upon the fluid level therein reaching a certain given point.

3. An acoustic filter comprising: a cylindrical casing; means defining a circumferential fluid inlet opening proximate one end of said casing; first tubular wall means within said casing defining a passage extending axially from the other end of said casing to a point near said one end, said first wall means embodying a venturi sectron; second wall means within said casing defining an annular passage of gradually decreasing radius communicating from said circumferential opening to said point; a first annular chamber within said casing formed radially exteriorly of said first wall means and communicating therewith near said point and with said venturi section; a second annular chamber within said casing at a different axial location therein and communicating with the venturi section of said axial passage, said venturi section of said first tubular wall means functionmg to draw fluid from said annular chambers therein, whereby said chambers function as means of absorbing pulsations which may characterize the fluid flowing through said filter.

4. An acoustic filter, according to claim 2, and float valve means in both of said annular chambers, said float valve means communicating with a source of low pressure gas, said float valve means being designed to shut off communication between said chambers and said source of low pressure gas upon the fluid level therein reaching a certain point.

(References on following page) 5 6 References Cited by the Examiner 3,137,316 6/ 1964 Everett et a1. 138-30 X Jones 8/1866 Van der Weyde. FOREIGN PATENTS 8/1901 Labradie 103-276 5 463,034 2/1950 Canada. 9 1920 Ehrhart 103 27 397,715 8/1933 Great Britain. 12/1933 RICHARD B. WILKINSON, Primary Examiner.

7/1952 Nlttka 103-261 7 1961 Everett 18x1 53 LEO SMILOW, Examine!- 11/1962 Jacuzzi I 103263 X 10 ROBERT S. WARD,Assislant Examiner.

Claims

1. AN ACOUSTIC FILTER COMPRISING: A CYLINDRICAL CASING; MEANS DEFINING A CIRCUMFERENTIAL INLET OPENING PROXIMATE ONE END OF SAID CASING; FIRST TUBULAR WALL MEANS WITHIN SAID CASING DEFINING A PASSAGE EXTENDING AXIALLY FROM THE OTHER END OF SAID CASING TOWARDS A POINT NEAR SAID ONE END; SECOND WALL MEANS WITHIN SAID CASING DEFINING AN ANNULAR PASSAGE OF GRADUALLY DECREASING RADIUS COMMUNICATING FROM SAID CIRCUMFERENTIAL OPENING TO SAID POINT; AND, AN ANNULAR CHAMBER WITHIN SAID CASING DEFINED IN PART BY SAID FIRST WALL MEANS AND POSITIONED RADIALLY EXTERIORLY OF SAID FIRST WALL MEANS, SAID ANNULAR CHAMBER COMMUNICATING WITH SAID FIRST WALL MEANS NEAR SAID POINT, SAID FIRST WALL MEANS FORMING A VENTURI SECTION WITH RESPECT TO SAID CHAMBER AT SAID POINT, WHEREBY FLUID IS DRAWN FROM SAID CHAMBER INTO SAID FIRST WALL MEANS, AND WHEREIN SAID CHAMBER FUNCTIONS TO ABSORB PULSATIONS THAT MAY CHARACTERIZE SAID FLUID.