DE19705660A1 - Measuring insert for gas meter - Google Patents

Abstract

The measuring insert is fitted in a cylindrical gas meter housing (2) and has an insert housing (4) with a gas inlet (5) and a gas outlet, enclosing a measuring wheel with peripheral angled turbine blades, rotated by the gas flow. An annular channel (20) is provided between an entry body (7), in front of the gas inlet and the measuring insert housing, supported via radial ribs, with a flow equaliser element (8) at the gas inlet.

Description

Technical subject

The invention relates to a measuring insert for measuring the flow of gaseous Media, with a measuring insert that can be inserted into a tubular meter housing housing, which has a gas inlet and a gas outlet, with a between the Gas inlet and the gas outlet arranged measuring wheel, which is rotatably mounted and has inclined blades circumferentially on the circumference ei Nes annulus extend, with a between the gas inlet and the measuring wheel coaxially arranged inlet body, which is held by means of radial ribs, wherein an annular channel is formed between the inlet body and the measuring insert housing.

State of the art

A generic measuring insert is known from DE-PS 27 02 319. The in egg Nem meter housing arranged measuring task has the task of flowing through To measure the amount of gas, the number of revolutions one in the measuring insert arranged rotatably mounted measuring wheel is a measure of the volume flowing through. This is summed up, for example, in a counter. The measuring wheel is off eventually moved by the gas flow.

Such a measuring insert is assembled in a tubular meter inserted and fastened in the housing. The measuring insert essentially settles from a measuring insert housing, an inlet body, a measuring wheel with one in one Bearing housing housed shaft and an outlet body together. The one Running body is arranged coaxially to the longitudinal axis of the measuring insert and is by Ribs held. The inlet body causes the pipe flow to be between two rule the inlet body and the measuring insert housing ring cross-section is directed. This achieves a certain leveling of the flow.

To maintain the measuring accuracy, measuring wheel counters require an undisturbed inflow measurement of the gas to be measured. In a gas measuring system, the flow profile is each but often arranged by upstream of the meter components such. B. fittings, Pressure regulator or tube sheets, considerably disturbed. This leads to deviations in the Measuring accuracy of the measuring wheel counter. In order to have an impairment in the  Avoidance of measurement accuracy is usually upstream in front of the measuring wheel counter arranged a device for rectifying the flow. The rectifier device of a fluid flow can, for example, by a sufficiently long inlet stretch or by arranging a flow straightener. Designs flow straighteners are described in DIN 1952.

The arrangement of an inlet section or a flow straightener has the Disadvantage that this component requires additional space and also to increase the Assembly and material costs contributes. Another disadvantage is that the influence of the rectifier for the measuring accuracy of the measuring insert leaves, because the calibration of the measuring insert takes place outside the gas measuring system.

Presentation of the invention

The invention is therefore based on the object, a measuring insert of the above Form in such a way that its flow properties improved and the pre mentioned disadvantages can be avoided.

This object is according to the invention in a measuring insert according to the preamble of independent claim 1 solved in that in the gas inlet of the measuring insert ses at least one rectifier element is arranged. Enter the measuring insert End pipe flow is segmented through openings in the rectifier element and then meets the face of the inlet body through which the pipe flow is directed into the ring channel. Through the interaction of rectification terelement and inlet body is a complete within the measuring insert Rectification of the flow causes so that irrespective of the pre-interference smooth flow against the blades of the measuring wheel is guaranteed.

This solution has the advantage that there is an additional current before the measurement set arranged device for rectifying the flow can be dispensed with. Another advantage is that the effect of the current integrated in the measuring insert housing rectifier are already taken into account when calibrating the measuring insert can. Otherwise, the measuring insert can be used independently of the meter housing to which it is ordered. This has the advantage that the measuring properties of the Measuring wheel counter can only be determined by the measuring insert.

The rectifier element arranged in the measuring insert is not specific Limited design. For example, it can be designed as a perforated plate or as a grid  be. Rectifier elements that have a large number of channels are also suitable point, these formed by walls aligned parallel to the direction of flow be det. Also the formation of the inlet body on the gas inlet side is not on tied a certain shape. It can, for example, as a calotte, as one or also be designed as a multi-stage baffle. The selection of the rectifier element takes place depending on the design of the inlet body on the gas inlet side.

The rectifier element can be used in different ways in the measuring insert be attached to the house, e.g. B. in which it is positively inserted, cast or is fastened by screws in the measuring insert housing. The latter has the advantage that a conventional measuring insert with one or more rectifier elements can be set up, so that its flow properties and its measuring accuracy have it subsequently improved.

Another advantage is that for the manufacture of measuring inserts according to the invention only minor changes to the existing for the production of the known measuring inserts tools are required. The measuring insert according to the invention can be produce accordingly economically.

The invention is further developed in that the measuring insert housing in the gas inlet has a recess in which the rectifier element is arranged in a form-fitting manner is, and that the rectifier element by means of fastening elements releasably on the measuring Insert housing is attached, the fasteners according to the arrangement of the Measuring insert in the meter housing are no longer accessible. This has the advantage that a sealing of the meter housing includes the rectifier and thus the lead sealing of the rectifier, which is common in the known arrangement, is eliminated. A Another advantage is that the diameter in the region of the recess is larger than that Diameter in the remaining part of the measuring insert, so that it is in the recess arranged rectifier element over the entire pipe cross section of the measuring unit sentence can extend and thus only a slight increase in pressure loss causes.

According to another feature of the invention, the rectifying effect can be there by improving that two or more rectifier elements in a row in the measuring insert are arranged differently, with at least two of the rectifier elements in their Differentiate design or other details. For example, two perforated plates with openings of different sizes or a perforated plate and a rectifier  be arranged with lattice-shaped partitions. It is advantageous if the The rectifiers are arranged at a distance from one another.

It becomes a particularly good rectifying effect with low pressure loss is sufficient if the free passage cross section of the rectifier element is about 80% of the Pipe cross section of the measuring insert is.

In a further development of the invention, the inlet body is made as a calotte on the gas inlet side formed, which engages in an omission in the rectifier element. So out formed measuring insert causes particularly low resistance losses.

As a further feature, the invention proposes that the inlet body on the gas inlet side Form baffle plate, the distance between the baffle plate and rectifiers element corresponds at least to the ring channel width. By complying with the minimum distance between baffle plate and rectifier can be trained with such a Deten inlet body to achieve an optimal rectification of the pipe flow. The The same applies if the baffle plate has two or more stages.

Such combinations of the invention are also considered to be disclosed as essential to the invention appropriate features that deviate from the links discussed above.

Brief description of the drawing

In the drawing there are several embodiments which serve to explain the invention examples are shown schematically. In detail shows:

Fig. 1 shows a longitudinal section through a Meßradzähler with a measuring insert;

Fig. 2 to 4 three variants for the gas inlet side formation of measuring inserts;

Fig four to 12 different designs rectifier elements, each represented. 5 in a plan view and in a longitudinal section.

Corresponding components are given the same reference symbols in all figures Mistake.  

Way of carrying out the invention

Fig. 1 of the drawing shows an overall designated 1 measuring wheel meter with egg nem tubular meter housing 2nd In this a measuring insert 3 is arranged with a measuring insert housing 4 , which has a gas inlet 5 and a gas outlet 6 . In the measuring insert housing 4 are an inlet body 7 on the gas inlet side and a rectifying element 8 in the form of a perforated plate and an outlet body 9 on the gas outlet side is arranged. Between the inlet body 7 and the outlet body 9 there is a measuring wheel 10 with a shaft 12 arranged in a bearing housing 11 , the bearing housing 11 being arranged within the outlet body 9 . The measuring insert 3 can be assembled precisely outside the meter housing 2 and is pushed into the meter housing 2 from the inlet side of the measuring wheel counter. Then the measuring insert 3 is secured in a known manner by screw connections or dg, not shown. The concentric arrangement of the measuring insert 3 in the meter housing 2 is achieved by short, ring-shaped seating surfaces 13 , 14 , 15 , each with the same radius. The seal between the measuring insert 3 and meter housing 2 is made by round seals, not shown, which are arranged in a known manner in the area of the seat surfaces 13 , 14 .

The bearing housing 11 has an essentially cylindrical shape and surrounds the shaft 12 aligned coaxially with the counter housing 2 . The ver with the shaft 12 connected measuring wheel 10 is substantially cup-shaped and has around obliquely inclined blades 16 which extend over an annular area in the cross section of the measuring insert 3 .

The inlet body 7 is formed by a cylinder jacket 17 and a spherical cap 18 connected to it in a form-fitting manner. The ball cap 18 is arranged in the gas inlet and the cylinder jacket 17 is open on its side facing the measuring wheel 10 . The interior of the hollow inlet body 7 is irrelevant in terms of flow.

The inlet body 7 is aligned coaxially to the measuring insert housing 2 and is held by radially directed ribs 19 which extend between the cylinder jacket 17 and the measuring insert housing 4 . An upstream of the measuring wheel 10 in the axial direction extending annular channel 20 is limited on the inside by the circumference of the cylinder jacket 17 and on the outside by the measuring insert housing 4 .

The measuring insert housing 4 has an annular recess 21 in the gas inlet 5 . In this, the perforated plate 8 is arranged in a form-fitting manner. It is attached to the measuring insert housing 4 by screws 22 . The screw heads, not shown, are arranged on the side facing away from the gas inlet and are no longer accessible after installation of the measuring insert 3 in the meter housing 2 . In addition to a large number of openings 23, the perforated plate 8 has an outlet 24 in its center into which the ball cap 18 engages with its nose.

FIGS. 2 to 4 each show longitudinal sections through various embodiments of the gas inlet side forming a measuring insert. In Fig. 2, the inlet body 7 is formed on the gas inlet side as a baffle plate 27 and the rectifier element as a perforated plate 8 . So that a good rectification of the pipe flow is achieved, the baffle plate 27 is arranged at a distance from the perforated plate 8 . Fig. 3 also shows a running body 7 with a baffle plate 27 , here upstream of the baffle plate 27 two rectifier elements in the form of one behind the other and spaced perforated plates 8 a, 8 b are available. These perforated plates differ in their design in that the openings 23 of the perforated plate 8 a have a smaller cross-sectional area than the openings 23 of the perforated plate 8 b arranged downstream. Otherwise, the openings 23 of the perforated plate 8 b are arranged offset to the openings 23 of the perforated plate 8 a. Fig. 4 shows an inlet body 7 having a two-stage designed baffle plate 27 and an inlet disposed upstream of the body 7 rectifier element 8.

Fig. 5 to 12 show various types of rectifying elements, which are very well suited for the present invention are suitable arrangement in a measuring insert. In Fig. 5 and Fig. 6 is a perforated plate 8 having circular openings 23 and in Fig. 7 and Fig. 8 a rectifier element 8 is shown with radially and axially oriented partitions 28th

FIGS. 9 and 10 show a rectifier element 8, the lattice-shaped partition walls 28 arranged in the form of lamellae. The expansion of the fins 28 in the flow direction of the gas is relatively small, so that short channels 29 are formed with a predominantly square cross-sectional area. In Fig. 11 and Fig. 12, a rectifier element 8 is shown, the partition walls 28 are arranged honeycomb, so that a hexagonal cross-sectional area is formed.

In the context of the invention, there are quite a number of possible modifications. So can the measuring insert housing is composed of several individual parts. This is it possible to the gas inlet side part of the measuring insert housing together with the To manufacture inlet body, for. B. in the injection molding process. The openings in perforated plates  are not limited to a specific form of training. For example Openings with oval, square or rectangular cross-sectional areas are conceivable.  

Reference list

1

Measuring wheel counter

2nd

Meter housing

3rd

Measuring insert

4th

Measuring insert housing

5

Gas inlet

6

Gas outlet

7

Inlet body

8th

Rectifier element

9

Outlet body

10th

Measuring wheel

11

Bearing housing

12th

wave

13

Seat

14

Seat

15

Seat

16

shovel

17th

Cylinder jacket

18th

Ball cap

19th

rib

20th

Ring channel

21

Recess

22

screw

23

opening

24th

omission

27

Baffle plate

28

partition wall

29

channel

Claims (7)

1. Measuring insert for measuring the flow of gaseous media, with a measuring insert housing ( 4 ) which can be inserted into a tubular meter housing ( 2 ) and has a gas inlet ( 5 ) and a gas outlet ( 6 ), with a measuring wheel arranged between the gas inlet and the gas outlet ( 10 ) which is rotatably mounted and has circumferentially inclined blades ( 16 ) which extend over the cross section of an annular space, with an inlet body ( 7 ) arranged coaxially between the gas inlet and the measuring wheel, which is held by means of radial ribs ( 19 ) is, wherein an annular channel ( 20 ) is formed between the inlet body and the measuring insert housing, characterized in that at least one rectifier element ( 8 ) is arranged in the gas inlet ( 5 ) of the measuring insert housing ( 4 ). 2. Measuring insert according to claim 1, characterized in that the measuring insert housing ( 4 ) in the gas inlet ( 5 ) has a recess ( 21 ) in which the rectifier element is arranged positively and that the rectifier element is fastened detachably in the measuring insert housing by means of fastening elements ( 22 ) , The fastening elements after the arrangement of the measuring insert in the meter housing ( 2 ) are no longer accessible. 3. Measuring insert according to claim 1 or 2, characterized in that in the measuring insert ( 3 ) two or more rectifier terelemente ( 8 ) are arranged one behind the other, with at least two of the rectifier elements differ in their design or other details. 4. Measuring insert according to at least one of claims 1 to 3, characterized in that the rectifier element ( 8 ) is designed such that its free passage cross section is more than 30%, preferably about 80% of the pipe cross section of the measuring insert housing ( 4 ). 5. Measuring insert according to at least one of claims 1 to 4, characterized in that the inlet body ( 7 ) is formed on the gas inlet side as a Ka lotte, which engages in an outlet ( 24 ) in the rectifier element ( 8 ). 6. Measuring insert according to at least one of claims 1 to 4, characterized in that the inlet body ( 7 ) is formed on the gas inlet side as a baffle plate ( 27 ), the distance between the baffle plate and rectifier element ( 8 ) corresponds at least to the width of the annular channel ( 20 ). 7. Measuring insert according to claim 6, characterized in that the baffle plate ( 27 ) is formed in two or more stages.