GB2422933A

GB2422933A - Counter adapted to mount within housing of a fluid flow meter

Info

Publication number: GB2422933A
Application number: GB0502351A
Authority: GB
Inventors: Ian Young; Ian Holmes-Higgin; Peter Davis
Original assignee: Elster Metering Ltd
Current assignee: Elster Metering Ltd
Priority date: 2005-02-04
Filing date: 2005-02-04
Publication date: 2006-08-09
Also published as: MY139081A; ZA200706423B; AU2006210740B2; ATE397256T1; DE602006001362D1; GB0502351D0; CN101185087B; EP1844430A1; AU2006210740A1; CN101185087A; EP1844430B1; WO2006082422A1

Abstract

A counter for a fluid flow meter comprises a count display device 30, a driving means 32 and mounting means 33 for mounting the driving means and count display device to a housing 16b of the fluid flow meter. The count display device 30 indicates a volume of fluid having passed through the meter and has a window 36 configured to seat sealingly in an aperture in the housing. The driving means 32 drives the count display device 30 and comprises a load-bearing frame 40a having a gear train mounted thereto. The mounting means is configured to bias the counter toward the aperture to seal the window 36 thereon, and to provide a biasing force to a portion of the load-bearing frame. The frame is configured such that the biasing force is prevented from affecting relative alignment of gears of the gear train.

Description

A COUNTER FOR A FLUID FLOW METER

The present invention relates to counters and is particularly applicable to counters for fluid flow meters especially water meters.

Flow meters are well known in the art. They typically employ a count display device which is operatively coupled to a rotary piston or other metering device and are enclosed in the flow meter's housing. The count display device usually comprises a series of gearedly connected wheels having indicia on respective external faces to indicate the volume of fluid which has passed through the flow meter.

Rotary motion of the rotary piston rotates a drive shaft which in turn drives a separate gear assembly gearedly connected to the count display wheels. The gear assembly is used to step down the rotational speed of the drive shaft to the counter wheels.

The count display device and gear assembly are mounted within the flow meter's housing, and thus are subject to the flow of fluid therethrough. The count display device has a window for viewing the indicia, the window being adapted to protrude through a complementary opening in the housing, and to seal therewith.

The flow rate of fluid and therefore pressure in the housing is variable. The design of the housing, window, seal and mounting of the count display device and gear assembly to the housing attempt to take the pressure changes into account.

However distortions in the housing due to variable fluid pressure during operation may result in leakage about the seal, and/or increased friction between gear wheels communicated from the housing via the mounting.

It is an object of the invention to overcome or ameliorate at least one of the deficiencies of the prior art, or at least to provide a suitable alternative thereto.

According to a first aspect of the invention there is provided a counter for a fluid flow meter, the counter adapted to mount within a housing of the meter, the counter comprising: a count display device for indicating a volume of fluid having passed through the meter, the count display device having a window configured to seat sealingly in an aperture in the housing; driving means for driving the count display device, the driving means comprising a load-bearing frame having a gear train mounted thereto; and mounting means configured to bias the counter toward the aperture to seal the window thereon, and to provide a biasing force to a portion of the load-bearing frame, the frame being configured such that the biasing force is prevented from affecting relative alignment of gears of the gear train.

Advantageously, since the biasing force is not applied to the gears of the gear train, the alignment of the gears is not affected by the biasing force which may otherwise detrimentally affect the operation of the counter. For example, undesired friction may otherwise be introduced to the gear train during operation.

Preferably the frame comprises first and second frame components supporting the gears of the gear train therebetween the frame portion being on the first frame component such that the biasing force is applied through the first frame component.

The frame portion is preferably a flat surface for mounting on a complementary flat surface of the mounting means. Preferably the biasing force is applied in a direction perpendicular to the axes of rotation of the gears.

Preferably each of the gears is on a respective axle and the axles are parallel, and preferably the first and second frame components are configured respectively to support respective ends of the axles.

Preferably the frame component comprises a supporting wall for supporting a respective one end of each of the axles, and the frame portion is on a mounting wall perpendicular to the axle supporting wall. Preferably the first frame component comprises a second supporting wall for supporting the count display device, the second supporting wall being perpendicular to the axle supporting wall. The axle and second supporting walls are preferably on parallel planes, and located at opposite ends of the mounting wall.

Preferably the second frame component is an axle supporting plate and lies on a plane parallel to the supporting wall of the first frame component.

Preferably the mounting means comprises two spaced apart blocks biased away from each other in a relative lateral direction. The blocks are preferably biased in a lateral direction with respect to the count display device.

Preferably each of the two blocks comprises a flat surface on one side, the complementary flat surface of the mounting means comprising the flat surfaces of the two blocks.

Preferably one of the gears of the gear train is directly driveable by a drive shaft which is rotatable in response to fluid flowing through the flow meter, and the axes of rotation of the gears are parallel to the drive shaft.

The fluid flow meter preferably comprises a rotor, rotation of which is related to the volume of fluid passing through the housing, the drive shaft being rotatable in response to rotation of the rotor.

Preferably the count display device comprises a worm gear, and one of the plurality of gears is adapted to drive a worm for driving the worm gear. The worm may be coaxial with the gear adapted to drive the worm.

The count display device preferably comprises a plurality of coaxial counting gears having indicia thereon for displaying a representation of the volume of fluid having passed through the flow meter, and the worm gear is preferably co-axial with or its rotational axis is parallel to the axes of the counting gears.

The count display device and driving means may comprise complementary male and female portions for mounting the count display device to the driving means. The second supporting wall of the first frame component may comprise the female portions.

According to another aspect of the invention there is provided fluid flow meter comprising a counter as described above in relation to the first aspect of the invention.

Preferred embodiments of the invention will now be described, by way of example only, with reference to the accompanying drawings in which: Figure 1 is a side elevation of an embodiment of a fluid flow meter according to an embodiment of the present invention; Figure 2 is a cross- sectional side elevation of the flow meter of Figure 1; Figure 3 illustrates a perspective view of a portion of the flow meter of Figure 1; Figure 4 illustrates a perspective view of a counter according to an embodiment of the present invention; Figure 5 is a detail view of Figure 2 illustrating an end elevation of the counter; Figure 6 is an exploded isometric view of the counter illustrated in Figure 5; and Figures 7 to 10 are various views of the gear assembly illustrated in Figures 2 to 6.

Referring to the Figures, a preferred embodiment of the invention comprises a fluid flow meter in the form of a rotary piston flow meter 10 employed as a utility meter, for example. As is known in the art, rotary piston flow meters comprise a rotary piston 12 which displaces fluid by moving eccentrically around the inside of a cylinder 14 in the meter's housing 16 between an inlet 18 and an outlet 20. The operation of rotary piston flow meters is described in our US Patent No. US-A-5567876, the description of which is incorporated herein by reference.

Referring to Figures 1 and 2, the housing comprises two threadedly engaged parts 16a, 16b. The first part 16a houses the cylinder 14 and the rotary piston 12. A post 22 on the piston 12 extends axially therefrom and is adapted to rotate a shaft 26 for driving a counter 28 housed in a second part 16b of the housing.

As illustrated in Figures 3 to 6, the counter comprises a count display device 30, a driving means in the form of a gear box 32 for driving the count display device 30 and a mounting means in the form of a ramp assembly 33 for mounting the counter 28 to the second housing part 16b.

The count display device 30 illustrated in the Figures is a liquid fillable count display device as described in our UK Patent Application No. 0328882.6, however as will be appreciated, any appropriate liquid fillable or non-liquid filled count display device may also be used. The count display device 30 indicates the volume of fluid having passed through the meter 10. As illustrated in Figure 1, to indicate the volume of fluid, the count display device has numerical indicia 34 which are visible through a window 36. The window 36, together with an 0-ring 37, is configured to seat sealingly in an aperture 38 of the second part 16b of the housing to prevent leakage of fluid through the aperture 38.

Figures 7 to 10 illustrate the gear box in more detail. The gear box comprises a load bearing frame 40 comprising a first and a second frame component 40a, 40b, which are mounted together by corresponding frictionfitted and/or snap-lockingly fitted male and female portions 42, to form the frame 40. A plurality of gears 44, 45, 46 of a gear train for driving the count display device 30 are rotatably mounted on parallel axles 48 between the first and second frame components 40a, 40b. Two gears 45 are provided with dual sets 45a, 45b of gear teeth of different pitch per set.

A portion of the frame, being the first frame component 40a, is of a loadbearing box- like construction. It comprises a supporting wall 50 for rotatably supporting an end 48a of each axle 48, a flat surfaced mounting wall 52 for mounting on a complementary flat surface 54 of the ramp assembly 33, and a second mounting wall 56 for supporting the count display device 30. The mounting wall 52 and the second mounting wall 56 lie on parallel planes and extend perpendicularly from opposite edges 58 of the axle supporting wall 50. The first frame component 40a includes structural ribs 60 between all three walls 50, 52, 56 to enhance the load-bearing ability of the first frame component 40a.

The second mounting wall 52 of the first frame component 40a and the count display device 30 comprise complementary male and female portions to assist in mounting the count display device 30 to the gear box 32. Referring to the embodiment illustrated in Figure 6, the male portions, in the form of posts 62, are located on the count display device 30 and the female portions, in the form of recesses 64, are located on the second supporting wall 56 of the gearbox 32. The posts 62 are configured to friction fit to the recesses 64.

The second frame component 40b is of a plate-like construction, having a supporting wall 68 for supporting another end 48b of each axle 48.

As described above, the gear train is assembled between the first and second frame components 40a, 40b. As illustrated in Figure 2, the shaft 26 is connected to the rotational axis of a primary gear 44 for the rotation thereof. Primary gear 44 is gearedly connected to three gears 45, 46. The gears' axles 48 are parallel to the rotational axis of the shaft 26.

On the gear 46 furthest from the primary gear 44 is a worm 70 coaxial with the furthest gear 46. The worm 70 is configured to drive a worm gear 72 on an outer end of the count display device 30. The rotational axis of the worm gear 72 is either coaxial with or parallel to the rotational axes of the gearedly connected counting wheels (not shown) in the count display device 30.

The configuration of the gears 44, 45, 46 of the gear box 32 with respect to the shaft 26 and count display device 30 requires only one worm 70 and one worm gear 72, compared to the need for at least two worms and worm gears in prior art gear boxes.

This has been achieved by changing the planar orientation of the gears such that they lie on rotational axes parallel to the rotational axis of the shaft 26. Since a relatively high amount of friction is caused between worms and worm gears when compared to standard gears, the reduction of the number of worms and worm gears in the present embodiment reduces the overall friction of the gear box.

The gears, 44, 45, 46 convey the rotation of the piston 12 to the count display device 30, as well as translate the rotational input of the shaft 26 laterally from the primary gear 44 to the worm gear 72. As will be understood, different gear ratios may be used depending on the size of the chamber, or the units of measurement displayed by the count display device 30. The gear ratios may serve to increase, decrease or retain the speed of rotation of the shaft 26 through the gear train. Furthermore, whereas the gear box 32 of the preferred embodiment employs four gears 44, 45, 46, alternative embodiments may use more or fewer gears.

The ramp assembly 33 comprises two spaced apart blocks 74a, 74b, each comprising coplanar flat surfaces 54a, 54b on one side thereof and ramp surfaces 78a, 78b on an opposite side thereof. The flat surfaces 54a, 54b, together forming the complementary flat surface 54 referred to above, are configured to support the gear box 32 on the mounting wall 52 of the first frame component 40a. Due to the flat nature of the mounting wall 52 and the coplanar flat surfaces 54a, 54b of the ramp assembly 33, the flat surfaces 54a, 54b are laterally slidable upon the flat side 40a of the first frame component. However, stop means in the form of two upstanding ridges 80 are provided along one edge 82 of the mounting wall 52 to prevent the ramp assembly sliding off the mounting waIl 52 and into the gears 44, 45, 46.

The two blocks 74a, 74b each comprise a respective coaxial bore 84a, 84b with a support rod 86 therein. The blocks 74a, 74b are slidable on the rod 86. A helical spring 88 is located on the rod 86 between the spaced apart blocks 74a, 74b biasing the two blocks 74a, 74b apart. When the counter 28 is assembled, the biasing direction of the two spaced apart blocks 74a, 74b is a parallel direction with respect to the mounting wall 52 surface.

The ramp surfaces 78a, 78b of the ramp assembly 33 are slidable upon slide surfaces in the form of ribs 90 projecting from a wall 92 of the second housing part 16b. Opposed ends of the ramp surfaces 78a, 78b comprise respective flanges 94a, 94b which abut the ribs 90 when the spaced apart blocks 74a, 74b are biased from each other to a predetermined maximum extent. The flanges 94a, 94b ensure the spaced apart blocks 74a, 74b do not move away from each other beyond a maximum allowable distance.

As illustrated in Figures 2 and 3, the counter is assembled in the second housing part 1 6b, by locating the ramp surfaces on the ribs 90, the first frame component of the gear box 32 on the flat surface 54, and the count display device 30 on the gear box 32, as described above. Once assembled therefore, the biasing of the spaced apart blocks 74a, 74b away from each other provides a net bias force through the load- bearing first frame component 40a only to the count display device 30 to bias the window 36 into a sealed position against the aperture 38. Second frame component 40b is carried solely from first frame component 40a via fitted male and female portions 42. Biasing forces go only through first frame component 40a which is a robust internally braced box section which does not distort. The relative alignment of the gears 44, 45, 46 is therefore not affected by the biasing force.

Furthermore, in use, the counter 28 is in the path of the fluid flowing through the flow meter 10. The flow rate of the fluid through the meter 10 is variable depending for example on quality of fluid supply and use patterns of the user. This means the pressure exerted by the fluid within and to the flow meter 10 is also variable. This variability may distort the shape of the flow meter 10 or impact the position of the components of the counter 28 within the housing 16. For example, the meter 10 may be susceptible to water hammer at certain fluid flow rates which may distort the shape of the housing. Therefore, the ramp assembly is also configured to be adjustable to adapt to the changes in fluid pressure and ensure the window 36 remains sealingly seated in the aperture 38.

If the biasing force of the ramp assembly 33 were to be provided to both the first and second frame components 40a, 40b, changes in internal pressure of the meter 10 may mean different biasing forces are provided to the first and second frame components 40a, 40b. Since the axles 48 are mounted on the first and second frame components, if different biasing forces are provided thereto, the axles will become misaligned causing undesired friction between the gears 44, 45, 46.

However, in the present embodiment the gear box 32 bears the load of the biasing force through only the first frame component 40a and not through the second frame component 40b.

As will be appreciated, the above described configuration of the gear box frame has allowed for the gears 44, 45, 46 to be rearranged wherein their rotational axes are parallel to the rotational axis of the shaft 26. This has in turn allowed for the reduction in the number of worms and worm gears, as described above, reducing the overall internal friction of the counter to improve its operation.

While the invention has been described in reference to its preferred embodiments, it is to be understood that the words which have been used are words of description rather than limitation and that changes may be made to the invention without departing from its scope as defined by the appended claims. For instance, the invention is not limited to the application of metering of water, but may be used in other metering applications such as, for example, for beverages or petrol (gasoline), or in a gas meters. Furthermore, as will be appreciated by the skilled addressee, while the invention has been described with reference to a single piston fluid flow meter, it may be adapted for use with a dual piston fluid flow meter, or in other displacement flow meters, such as, but not being limited to, nutating disc meters. In further alternative embodiments, the counter may be adapted for use in inferential flow meters, such as, but not being limited to, single-jet flow meters, multijet flow meters, bi-rotor flow meters, or helical-rotor meters such as that sold under our registered trademark HELIX.

The text of the abstract filed herewith is repeated here as part of the specification.

A counter for a fluid flow meter comprises a count display device, a driving means and mounting means for mounting the driving means and count display device to a housing of the fluid flow meter. The count display device indicates a volume of fluid having passed through the meter and has a window configured to seat sealingly in an aperture in the housing. The driving means drives the count display device and comprises a loadbearing frame having a gear train mounted thereto. The mounting means is configured to bias the counter toward the aperture to seal the window thereon, and to provide a biasing force to a portion of the load-bearing frame. The - 10- frame is configured such that the biasing force is prevented from affecting relative alignment of gears of the gear train.

Claims

CLAIMS: 1. A counter for a fluid flow meter, the counter being adapted to

mount within a housing of the meter, the counter comprising: a count display device for indicating a volume of fluid having passed through the meter, the count display device having a window configured to seat sealingly in an aperture in the housing; driving means for driving the count display device, the driving means comprising a load-bearing frame having a gear train mounted thereto; and mounting means configured to bias the counter toward the aperture to seal the window thereon, and to provide a biasing force to a portion of the load-bearing frame, the frame being configured such that the biasing force is prevented from affecting relative alignment of gears of the gear train.
2. The counter according to claim 1 wherein the frame comprises first and second frame components supporting the gears of the gear train therebetween, the frame portion being on the first frame component such that the biasing force is applied only through the first frame component.
3. The counter according to claim 1 or 2 wherein the biasing force is applied in a direction perpendicular to the axes of rotation of the gears.
4. The counter according to any preceding claim wherein the frame portion is a flat surface for mounting on a complementary flat surface of the mounting means.
5. The counter according to any of claims 2 to 4 wherein each of the gears is on a respective axle and the axles are parallel, and wherein the first and second frame components are configured respectively to support respective ends of the axles.
6. The counter according to claim 5 wherein the first frame component comprises a supporting wall for supporting a respective one end of each of the axles, and wherein the frame portion is on a mounting wall perpendicular to the axle supporting wall - 12-
7. The counter according to claim 6 wherein the first frame component comprises a second supporting wall for supporting the count display device, the second supporting wall being perpendicular to the axle supporting wall.
8. The counter according to any of claims 2 to 7 wherein the second frame component is an axle supporting plate and lies on a plane parallel to the supporting wall of the first frame component.
9. The counter according to any of claims 6 to 8 wherein the axle and second supporting walls are on parallel planes, and located at opposite ends of the mounting wall.
10. The counter according to any preceding claim wherein the mounting means comprises two spaced apart blocks biased away from each other in a relative lateral direction.
11. The counter according to claim 10 wherein the blocks are biased in a lateral direction with respect to the count display device.
12. The counter according to claim 10 or 11 wherein each of the two blocks comprises a flat surface on one side, the complementary flat surface of the mounting means comprising the flat surfaces of the two blocks.
13. The counter according to any preceding claim wherein one of the gears of the gear train is directly driveable by a drive shaft which is rotatable in response to fluid flowing through the flow meter, and wherein the axes of rotation of the gears are parallel to the drive shaft.
14. The counter according to claim 13 wherein the fluid flow meter comprises a rotor, rotation of the rotor being related to the volume of fluid passing through the housing, and wherein the drive shaft is rotatable in response to rotation of the rotor. - 13-
1 5. The counter according to any preceding claim wherein the count display device comprises a worm gear, and one of the gears of the gear train is adapted to drive a worm for driving the worm gear.
16. The counter according to claim 15 wherein the worm is coaxial with the gear adapted to drive the worm.
17. The counter according to claim 15 or 16 wherein the count display device comprises a plurality of coaxial counting gears having indicia thereon for displaying a representation of the volume of fluid having passed through the flow meter, and wherein the worm gear is co-axial with or its rotational axis is parallel to the axes of the counting gears.
18. The counter according to any preceding claim wherein the count display device and driving means comprise complementary male and female portions for mounting the count display device to the driving means.
19. The counter according to any of claims 7 to 18 wherein the second supporting wall of the first frame component comprises the female portions.
20. A fluid flow meter comprising a counter according to any of the preceding claims.
21. A counter for a fluid flow meter substantially as herein described with reference to the accompanying drawings.