DE1473173B2 - Displacement flow meters - Google Patents

Description

The invention relates to a displacement flow meter with a measuring housing Inlet and outlet ports communicating with an inner chamber and two with each other complementary rotating elements, which are exclusively closed with stationary sealing surfaces of the fluid passage area in the chamber between the elements and the chamber wall work together in all operating positions of the elements, with one of the elements at its Rotation by the fluid flow od a counter. Like. Drives and with the other element is in a drive connection.

In a known positive displacement flow meter of this type the two elements are two interlocking rotors alternating from the Fluid flow are driven. Each of the rotors has two diametrically opposed Equipped with wings against which the pressure of the fluid acts. Grab at their turn the two rotors into each other in such a way that a wing of a rotor always in a gap between the two The wings of the other rotor come to rest. For sealing the fluid passage area In the chamber of the known flow meter, the blades of the rotors form sealing surfaces on the one hand on the chamber wall and on the other hand on a stationary hub of the other rotor.

When such a flow meter is in operation, the flow rate of each rotor increases from zero to the maximum, and then it goes back to the value zero. The entire flow thus shows four cyclical fluctuations with each rotor rotation, up to 10% of the average Can be delivery rate. This behavior is a typical property of all flow meters which, like the well-known flow meter, commonly called

3 4

Roots rotary piston knives are called. Numerous disadvantages result from Fig. 1, a section through a displacement of this property. Flow meter according to the invention,
These fluctuations in the promotion of the flow F i g. 2 to 5 the section of FIG. 1 similar means call up pressure surges in the discharge line - sectional views of the flow meter, in which those are shown that are particularly damaging when an operating position to be supplied with 5 rotor and the rotary stop in successive constant fluid pressure are shown,
Device at a short distance after the flow F i g. 6 is a perspective view of one connected to the knife. inventive flow meter used Ro-

Furthermore, the pressure surges cause vibrations in the rotors,

gate shafts, which at certain rotor speeds io F i g. 7 is a perspective sectional view in which

can lead to measurement errors. The pressure surges and the surface seal between a wing, the

the vibration is brought about by relatively noisy operating measuring housings and a fixed counter bearing

noise of the flow meter with it. is shown

The alternating driving of the two rotors F i g. 8 is a perspective view of the effect achieved in FIG an intermittent loading of the GeRotors used with the 15 inventive flow meters connected timing gear. This blinding rotor,

tion calls together with the fluctuations mentioned. 9 shows a section through the inventive

a cyclical flow meter, in which the drive connection is also

load on the gearbox, which can be seen with the counter after prolonged use, and

operating life inevitably uneven wear 20 FIG. 10 shows a section through the bearing arrangement

of the transmission brings with it. a shaft that carries one of the elements.

The invention is based on the object of the in F i g. 1 has the flow meter shown Displacement flow meter of the initially attached body 16 with an inlet opening 18 and To create given type, with a simple construction of an outlet opening 20 substantially uniform conveyance of the 25 denier flanges 21, which are fixed to the openings ver-fluid results. ;. bound and for fastening in a pipeline

According to the invention, this task will be suitable. Within the body 16, between the

solves that the element driving the counter as the inlet opening 18 and the outlet opening 20 are a

Fluid-driven rotor with from the Strö rotor 22 and a rotating rotary stop 24 to-

means acted upon wings is formed 30 ordered, which rotates in the opposite direction,

and that the other of the elements is a wingless one inside the rotor 22 and adjacent to the rotating one

Rotary stop forms the fluid flow rotary stop 24 is a fixed, the

occurs between one side of the rotor and the counter-body supporting 'counter-bearing 26. The flow medium

overlying chamber wall blocked so that the gel that enters through the inlet opening 18 hits

All of the fluid 35 entering the chamber is non-radial vanes 28 and rotates the rotor 22 counter-clockwise

acts only on the hills of the rotor and drives it. clockwise around shaft 29. This way

In a flow meter of this type, the vanes 28 only separate, during their rotation, a quantity of the fluid which can be driven by the fluid at the inlet valve. The other element is not in any operating opening, transporting this amount between the phase acted upon by the pressure of the fluid, the measuring housing and the fixed counter bearing 26, so that it does not drive the connected and push it through the outlet opening the end. A separate counter contributes. There is therefore no contact with the ends of the shafts 29 and 30 of the rotor and there is no change in drive between the two rotating elements of the control gear attached to the rotary stop. The one attached to one element works the rotation of the rotary stop 24 clockwise! The th wing transports the fluid in the same direction .45 The rotation of the rotor 22 and the rotational speed from the inlet opening to the outlet opening, so stop 24 is timed so that there are essentially no pressure surges. That the wings 28 at a certain distance from uniform promotion of the fluid has arc-shaped recesses 32 added werauch a uniform load to drive the, wherein a contact between the wall and the counter 5 ° wings drive devices used is prevented. = ■. . ^: >:: ■ - ::,:; - to: the consequence, so that the wear and tear is greatly reduced by the shaft 30 of the rotary stop 24 is over. This leads to a considerable lengthening of separate devices, a counter of the usual Bauder service life of the flow mode according to the invention, which drives precisely the measured volumetric meter. - The amount flowing through the flow meter; · ■ - According to a further development, the blades are registered as a medium. The entire flow meter has parallel, flat surfaces which can be dismantled in the direction of the flow for maintenance reasons and reassembled against the radial and reassembled without the rotor being inclined in the direction of the internal being impaired in its calibration. ;
Edge of each wing in the direction of rotation of the rotor in front of the Fig. 2 to 5 show the consecutive the outer edge. * - \; :;: 6b Working positions of the preferred embodiment

Such an inclination of the wings against the Ra-. of the measuring device, the successive

dial direction of the rotor improves the flow positions are shifted by about 45 °,

conditions of the fluid, since a vertical rotor 22, which in its preferred embodiment

Impingement of the fluid on the blades is shown in FIG. 6 is shown, in addition to

is avoided, as in the case of radially protruding blades 65, shaft 29, four essential, one-piece

would be the case. running parts on. These are: A hollow shaft

One embodiment of the invention is in the retaining housing 102 which holds reinforcements 104

Drawing shown. It shows - can sit, a disc-shaped rotor hub face-

5 6

plate 106, the longitudinally extending, Fig. 8 is shown, from a single component; he

flat wing 28 and an annular face plate has two arcuate shells 120 and 122 ,

108. those at their middle parts with two with each other

It has been found through experiments that the connected, fork-shaped ribs 124 and 126

5 occurring in the present flow meter are connected which have any desired transverse

Pressure loss can partially cut through to the nominal value, with all parts through

can be reduced that the thin wings 28, the hub 128 are firmly connected to the shaft 30,

are used that refer to wave 2? This design makes a large one from one

do not run radially, so that chamber 114 existing in the ordinary space gained that too

Direction of rotation the inner edges of the blades in front of the iq to reduce compression and expansion

outer edges. The inclination of the wing is in sicm the compressed fluid is used,

Fig. 1 by the angle, 4 shown. if the wings are in

It has been found that the optimal angle A move this chamber in and out of it, when measuring gas 16 ° against the radial position. This has a lower pressure loss, which is supposed to be reduced. The optimum angle varies, however, with a slight pressure fluctuation and a lower level of operation depending on the type of noise to be measured in the device. In this way, the flow meter and the interaction and the flow meter at all operating speed dimensions of the components of the flow meter, run relatively smoothly, and it has over the whole, in particular the size of the recesses 32. The area of the flow speed is a bevel the vane 28 causes, as shown in FIG. 3 ap sentliphen uniform high measurement accuracy, can be seen, a more gradual onset of wing a contact between the rotation stopper and into the recess 32 of the rotary stopper 24 so that the rotor does not take place, because the exact Winkelr A pressure loss influencing the performance is maintained as a setting between these parts due to the control sequence of the impact of the blades on the flow gearbox, the timing medium is avoided. However, λ * 5 does not need to be exact, as long as the time-

By reducing the thickness of the wings 28 , the lending tuning will not become significantly out of phase

the pressure loss in the flow meter is further reduced, so that the blades against the edges of the

modifies, but reducing the thickness is both shell edges of the rotary stop butt, the

not limited by the required flexural rigidity as well as the operability of the flow meter to the dimension required to be effective. The leading edge 130 (Fig. 2) of the wing

Kungsvolle sealing surfaces between the wings 28 28 must therefore on the edge 132 of the shell 120, and

and the main housing 38 and wings 28 and the exposed edge J34 of the wing 28 (Fig. 2)

to create the fixed abutment 26 and to run past the edge 136 of the shell 122

by the escape of not from the flow measurement, _T

to prevent this measured fluid. As can be seen from FIG. 8, the surfaces are 138

Thickness of the wings 28 can be offset in a measuring device with and 140 of the shells 120 and 122 at 142,

a conveying volume of about 10 m ³ per hour with which on each tray on the two edges

a fluid with a specific raised back surfaces 144 and in the middle a back

weight of approximately 0.6 be about 5 mm. To kenfläche 146 arise. This construction serves to avoid excessive possible bending of the thin 40 against the main housing 38 and the fixed structure.

To prevent wing 28 , the escape of the opposite bearing 26 to create surface seals, the travel

measured fluid, the drag of the fluid must be reduced

stiffening, annular face plate 108 opposite and to cause the flow meter in the

the end plate 106 inextricably cleans itself with the ends of the wings, especially when dirty

gel 28 connected. 45 fluids, such as natural gas, extracted from oil wells

The edges of the wings 28 are to be measured as surface sealing. In these cases the

Gen 110 and 112 formed, as in F1 g, 7 ge dirt and the foreign particles through the recess

shows is. The edges of the wings 28 are worked in such a way that 142 from the flow meter inlet to the outlet

that they funneled exactly between the main housing 38 and gang. ._,. .- '..'

the fixed abutment 26 fit and the 50. The back surfaces 144 and 146 work with the

Fluid has a high resistance to main housing 38 and the fixed counter bearing

set. This resistance is so large / that it prevents 26 together so that, as shown in Fig. 1, in

prevents unmeasured fluid along any position during all operating conditions.

these edges, precisely where the running clearance roughly thirdly forms a joint surface seal, the

times as large as the smallest clearance of the roots-turning 55 distance between the edges 132 and 136 is greater

piston knife is escaping. When using ßer than the distances between edges 142 and

Surface seals can be the running play of the described 144 of the fixed counter bearing 26, between the

benen flow meter depending on the edge 142 of the fixed counter bearing 26 and the

Device size be about 0.15 mm or more, ■ ;;.: Edge 146 of the main housing 38 and between the

The rotary stop 24 is adapted to an arcuate cutout 60 edge 144 of the stationary counter bearing 26 and the recess in the main housing 38 and is so edge 148 of the main housing 38 , that the impact of the fluid is on the chamber 114 between the shells 120 the vanes 28 is further reduced on entry, since and 122 never open a single, open, rotatable chamber 114 bil- the outlet opening of the flow meter simultaneously to the inlet and the flow meter, which reduces the ease of fluid displacement 65 by the escape of unmeasured Distortion increases and pressure changes in the chamber and medium is prevented by the rotary stop, the pressure loss of the flow meter is reduced. On the main housing 38 of the body 16 is located

The rotary stop 24 preferably consists, as in a gear housing 160 (Fig. 9), which is

7 8

Screws 161 attached to an end hood 36 is main bearing 44 for the shafts 29 and 30 carry, from and enclosing the device which separates a counter from the main housing body. The flange of the 162, which registers the flow, drives the end caps 34 and 36 and the side plates 40 as a function of the rotation of the shaft 30. The counting and 42 are against the leakage of the lubricant plant 162, which seals on a display plate 163 in any 5 and the flow medium by O-rings 46 in any position, including the horizontal. With the lubricant chamber 50 and control and vertical position located, any drive assembly 52 may be external to the plate 40 on a conventional meter. The counter 162 is ordered and are closed by the end cap 34 better than by the shaft 30 of the rotary stop. .
driven by the shaft 29 of the rotor. The control gear arrangement 52 consists of a then the load on the control gear with driving control gear 54 with a coarse toothed gears 54 and 56 during operation approximately division without particular accuracy and thus kept constant. This reduces the on-going driven gear 56 that occurs from kickback between the gears 54 carried by the ends of the shafts 29 and 30, respectively, and 56 and contributes to the reduction and equalization. On both sides of these gears there is a moderate amount of wear, whereby the spacer rings 59 and 60 which are to be obtained are removed from the shaft by a lock nut assembly 58 which is attached to the shaft for increased service life of the flow meter. .; ■; one side down, tension in their position

Will be held between the end cap 36 and the housing 160 .

If there is a magnetic transmission assembly 20 As shown in Fig. 10, the spacing

opening 164, which is fastened to the plate 42 by means of screws. rings 60 also against the inner ring of the main bearing

connected is. The assembly 164 has a 44 that resides in the hubs 64 of the side plates 40

Bearing plate 168, which are arranged on the shaft 172 and carried by the shafts 29 and 30, respectively

Nite, self-lubricating bronze bearings 170 can be worn without running around with them. The inner ring

will. The shaft 172 is supported by the shaft 30 via 25 each bearing 44 is also located at one end of the

a reduction gear 174 and 176 driven and arranged on the shaft sleeve 62, and the

thereby rotates the outer ring of each bearing 44 , which is fastened by a threaded ring, is in the open

th drive magnets 178 of the magnetic drive 180 bore 66 between the fastening cap 68, the

the hub 64 , which is provided with a thread to avoid a conventional stuffing box, and the fork-feed

is used. The magnetic drive 180 consists of 30-shaped spring washers 69 aligned and held,

the drive magnet 178 from the driven Ma- The play between each end of the wings 28, each

gneten 182 and the magnetic shaft 184. The magnets - the end of the rotary stop 24 and the plates 40

shaft 184 and the bearing plate 168 are adjacent and 42 is arranged so that escape of not

and collectively on their outwardly extending fluid measured by the spring washers

the flanges by the bolts 186 and 187 to-35 69 against the vertical edge of the open

held together. The visual screws 186 are placed in the bores 66 and the outer ring of the bearings 44 .

Plate 42 screwed in. Between the magnetic wave gene, is prevented. This whole arrangement will

184 and the opening 190 in the end cap 36 is in a movable position due to the closure caps 68

sealing the O-ring 188 and preventing it from being held. The caps 68 have a spacer ring

Fluid from the chamber 90 into the bearing 40 60 has sufficient clearance, and they are at their inner

housing 160 penetrates. In this way it is beveled between its diameter, so that oil as a result

the chamber 90 and the bearing housing 160 a rudder gravity effect for the purpose of lubrication in the

existing seal. ^ Camp 44 is running. The outer surfaces of the caps 68

In the bearing 192 , the shaft 194, on which the thread holder 195 is screwed into the recesses 66 with a pin, is rotatably 45 inserted. The axial play of the shafts 29 and 30, of the Roan arranged. The holder 195 is under tension via the gate 22 and the rotary stop 24 is pushed by magnets 182 which drive it. The opening or loosening of the caps is adjustable. The spring left end of the shaft 144 rests, as in FIG. Rings 69 shown in FIG. 5 hold the entire assembly under a predetermined tension in the bearing 196 which is carried by the housing 198 and supports a worm gear 200 which enables precise adjustment of the rotor 22 and the rotatable one Gear shaft (not shown) on the device shaft rotation stop 24 precisely when parts of the Strö 202 are driving. The devices shaft 202 actuates the counting mung diameter prolonged wear were exposed factory 162 in a conventional manner via a Reduzierge- For the lubrication oil is in a Schmiermittelkamtriebe 204 and 206 and the shaft 208. contain the shaft mer 50 which is by means of an oil spray ring 78202 is distributed at the lower end in a self-lubricating 55 (Fig. 9). The oil splash ring 78 is guided by the bronze bearing 210 and rests on the gear 54 separated by the spacer ring 79 and thrust bearing 212 on. attached to it by screws 80 so that it is aligned with shaft 29 in both directions of flow. Bushings 62 prevent lines can be operated, but the direction shown in the escape of the oil from the chamber 50 by Fig. 2 to 5 is preferable, because the 60 central opening in the hub 64th rotation generated by the gap is the usual counters - is between the shaft and the hubs 64 and the lap passes without modification. Like 44 , a small amount of the measured one can move in the opposite direction to that in FIG. 1 fluid entering the chamber 50 , the direction of flow shown would require pressure in a left-hand worm gear on both sides of the plates 40 and 42. 65 compensation is effected. During the rotation of the

As can be seen from Figure 9, end hoods 34 are sleeves 62 hurling tangential force components

and 36 bolted to the main housing body 38, the speed of the

however, by side plates 40 and 42, the th rings 82 excess oil on the wall 84, the

the chamber 50 is opposite, ürid against the inner wall of the Näberi 64, from where ¹ es ¹ danii through did schfägeh Öirrückführungbohrürigen 86 in the lateral plate 40 iii the chamber 50 runs back;

As can also be seen from FIG. 9, the side plate 42 carries the left end of the shaft 29 essentially in the same way as; the plate 4Ö that bears the rdcirte. The LägSf 44 and the bushes ¹ 62 are held by the bearing cover 68 α in their Lägö within the recess 66 ä ; Here, however, the 'bushes 62 aii ddr plate 42 are in contact and the barrels do not press against the rotor 22 üfld deüi tffehäriseliiäg U. Emö second Sc ^ erMitelkäffimeY 9Ö igt' with an oil spillage 78 outwardly, d6r iri Verbiridürig with the Käfflmafäfäf MfKt wid the Kammef 5Ö and the Ölsptltzrihg 78 '. Det ÖlflUßkänäi 86; ä iö the plate 41 conveys the oil _y dä & during the Ün> dfehürig vöb dei can 62 äbggöehleüdert wifd; ία

the same, obfefi nicely explained way back like lines 86 in plate 40.

The fixed Gegeneiüäger 26 (Fig.-10) is

by means of fasteners 94 inside the Rötöfflügel and next to your Drehäfischlag there is one

ünvefäriderlicheii would be the shaft 29 against the

Plate 42 held;

The fluid-transmitting chamber 96 is between the inlet * and the outlet openings

iö 18 ürid 20 and the side plates 40 and 42 _S deffl the rotor 22, the rotating rack 24 and the fixed counterpart 26 are opened and sealed against the escape of non-compliant disruptive means by means of an open area seal. The flow

i§ äiüiigsniitfel käfiri however enter the Käihriierä SO and 90 by the Auspärungü 66 and 66 ä ; ütB äüf jade'f Siitg der- 'Platten 40 ürid 42 to bring about a pressure equalization.

Sheet drawings

Claims (1)

Patent claims: 1. Displacement flow meter with a Measuring housing with inlet and outlet openings which are in communication with an inner chamber, and with two complementary rotating elements that are exclusively stationary Sealing surfaces with closure of the fluid passage area work together in the chamber between the elements and the chamber wall in all operating positions of the elements, one of the elements, as it rotates through the flow of fluid, drives a counter or the like and with the other Element is in a drive connection, thereby characterized in that the element driving the counter (162) is a fluid-driven element The rotor (22) is formed with vanes (28) acted upon by the fluid is and that the other of the elements forms a wingless rotary stop (24) which the Fluid passage between one side of the rotor (22) and the opposite Chamber wall blocked so that all of the fluid entering the chamber only on acts on the blades (28) of the rotor (22) and drives it. 2. Flow meter according to claim 1, characterized in that the wings (28) as parallel, flat surfaces are formed which point in the direction of the flow and so against the radial direction of the rotor (22) are inclined that the inner edge of each wing (28) in the direction of rotation of the rotor (22) lies in front of the outer edge. 3. Flow meter according to claim 2, characterized in that the wings (28) in one Angle of 16 ° against the radial direction are inclined. 4. Flow meter according to claim 1 or 2, characterized in that in the rotary stop (24) Recesses (32) are provided through which the wings (28) move during their movement Move through it with the rotor (22V without contact. 5. Flow meter according to one of the preceding claims, characterized in that the rotor (22) rotates around a central fixed counter-bearing (26) with which the rotary stop (24), forming a sealing surface between the inlet and outlet openings (18 , 20) works together in all operating positions of the two elements. - · ■ '' ■ ■■ -. '''■ ^-:.: - "■' ■: - ■ '■ - ^<->' '■'" ■ · - 6.- flowmeter to-one of the preceding claims, characterized in that the blades (28) are made relatively thin in order to prevent pressure losses, but are thick enough to close surface seals on the housing (38) and on the stationary counter bearing (26) in all operating positions form. 7. Flow meter according to claim 6, characterized in that the wings (28) about 5 mm are thick. 8. Flow meter according to one of the preceding claims, characterized in that the rotary stop (24) between the inlet and outlet openings (18, 20) has at least two Maintains sealing surfaces during one full revolution. 9. Flow meter according to claim 8, characterized in that a sealing surface with the fixed counter bearing (26) is formed and that the other sealing surface with the chamber wall is formed. 10. Flow meter according to one of the preceding claims, characterized in that the. The rotor (22) and the rotary stop (24) are arranged next to one another on parallel shafts (29, 30) which are connected to one another by gears (54, 56) of the counter (162), and that the shaft (29) carrying the rotor (22) is guided through the stationary counter bearing (26) is. 11. Flow meter according to claim 10, characterized in that the rotor (22) and the rotary stop (24) are axially loaded in the same direction by springs (69) and by means of caps (68) which are mounted on the shafts (29, 30) in such a way that they cooperate with the springs (69), are individually adjustable in the axial direction. 12. Flow meter according to claim 11, characterized in that the springs (69) are disc springs which surround the shafts (29, 30) concentrically.