DE3025009C2 - Device for testing and / or calibration of diaphragm gas meters - Google Patents

Description

The invention relates to a device for testing and / or calibration of diaphragm gas meters by means of a comparison device that can be connected to several test objects of known volume.

Devices of the type mentioned are fundamental

known and are constantly being checked and checked

Oak newly manufactured or due to legal Provisions after a certain operating time

Diaphragm gas meter to be checked and re-calibrated used The main area of application is on the testing and calibration of diaphragm gas meters used in large numbers of items checked annually and new need to be calibrated.

The known test methods or test benches

ίο which several test items can be checked and calibrated at the same time, require a relatively large amount of work and time, especially when checking the lower load point Qmm, because the standards used as comparison devices do have one have minor, but periodically occurring errors. The known devices serve as comparison devices Test benches usually other, very precisely working similar counters or measuring bells or liquid meters.

Furthermore, from DE-AS 14 98 424 a calibration device for flow meters is known It is used specifically for testing and calibration of Liquid meters. A cylinder with a piston is used as a comparison device

The invention is based on the object of providing a device for testing and / or calibration of diaphragm gas meters of the type mentioned above, which has a reliable measurement with, if possible, only a single rotation of the measuring mechanism shaft of the test object in particular also on the lower of the three for diaphragm gas meters load points to be checked are permitted. The amount of work and time associated with the examination is then namely considerably lower than with the known test methods.

Furthermore, it is a particularly efficient way of working

aimed at allowing as large a number as possible

Test objects to a test or calibration at the same time

undergo.

This on which the invention is based is achieved

Task in that as a VerglekSu device. at least one cylinder known per se and one Piston having device is provided nut an associated drive and that this device is arranged between two groups of test objects.

* 5 Because the piston and cylinder are extremely large Accuracy can be produced, the tolerances or deviations from the nominal value are negligibly small and are in an order of magnitude 0.01%. Also the verification and calibration of the lower one Load point Q _m , " can take place with the flow of a single volume unit through the device, which is associated with a single rotation of the measuring mechanism shaft. The verification and calibration of diaphragm gas meters can therefore be essential borrowed to carry out faster and more rationally than before was possible.

The rational and time-saving way of working is finally achieved with the features according to the invention increased by the fact that the Kolhen cylinder device arranged between two groups of test objects will. One group of test objects is then checked in suction mode, while the other group is on the pressure side of the piston-cylinder device lies. With a single piston stroke check and calibrate twice the number of test items compared to the previous one.

Further features of the invention emerge from the subclaims.

The invention is illustrated below using an exemplary embodiment that is shown in the drawing is described in more detail. It shows

F i g. 1 is a schematic view of a device according to the invention;

F i g. 2 is a view as in FIG. 1 with the representation of the flow course during the preparatory Measures for a verification and calibration;

F i g. 3 is a view as in FIG. 1 with the representation of the flow course in a sealing sample;

F i g. 4 is a view as in FIG. 1 with the representation of the flow profile when checking the operating point Q _mm and

Figure 5 is a view as in Figure 4, but with the Representation of the flow curve when testing the 0.2 CW operating point

A device 1 according to the invention for testing and / or calibration of diaphragm gas meters 2 comprises a Comparison device 3 with a known volume in the form of a cylinder 4 that can be connected to the test objects 2, whose comparison volume 5 can be determined exactly, since it is proportional to the path that an im Cylinder 4 covered by displaceable piston 6 The piston 6 is capable of each To suck in the reference volume or to push it out of the inside of the cylinder.

In order to use the activity of the cylinder 4 both on the suction side and on the pressure side, both the cylinder part 7 located on one side of the piston 6 and the cylinder part 8 located on the other side of the piston 6, each with a group 9, 10 of test objects 2 connectable. A line 12 having a shut-off element 11, which leads to one group 9 of test objects 2, and a line 14 provided with a shut-off element 13, which leads to the other group 10 of test objects 2, are used for this purpose. In turn all the specimens 2 are connected by lines 14 to each other or connected in a series, in each case a shut-off device is at the end of 15 and 16, and establishes a connection to the atmosphere o * with a corresponding circuit.

Finally, further shut-off elements 19, 20 are also arranged on each cylinder part 7 and 8, respectively, which at corresponding circuit also connect the interior of the cylinder parts 7, 8 with the atmosphere. * 5 Individual or all shut-off devices 11, 13, 19, 20 can finally also be connected to the two end faces 17, 18 of the cylinder 4 (not shown).

When the piston 6 moves from the position shown in FIG. 1 shifts the position shown, so he sucks through the Line 12 and the test items 2 of group 9 from the shut-off device 15 to air and presses the reference volume 5 on its other side through the line 14 into the test objects 2 of group 10 and through the Shut-off element 16 into the atmosphere. Both groups 9 and 10 of test items 2 are hereby exaki measured comparison volumes and can therefore be checked and / or calibrated.

As a drive for the piston rod 21 d = s piston 6 is used in the illustrated embodiment Threaded spindle 22, which is moved with the aid of a spindle nut 23 and an electric drive 24. the Spindle nut 23 is freely rotatable and axially immovable and thereby pulls or pushes the Threaded spindle 22 with the piston rod 21 and the piston 6 each from one end position to the other. A transmission gear 25 can also be arranged between the drive 4 and the spindle nut 23 so that the spindle nut 23 rotates at a desired speed

To enable particularly efficient operation, a further comparison device 26 in the form of a second cylinder 27 with a piston 28 can be connected to the two groups 9 and 10 of test objects 2 in the same way as the first cylinder 4. The comparison volume 29 of this cylinder 27 corresponds to the test volume for the test 0.2 Qmax. Since the test of 0.2 Qmax takes place at a considerably higher flow rate per unit of time, it is possible to work with several revolutions of the measuring mechanism of the test objects 2 without losing any appreciable time. The cylinder 27 is therefore larger than the cylinder 4.

In detail, the cylinder 27 or the cylinder part 30 located on one side of the piston 28 is connected to the group 10 of test objects via a line 32 with the interposition of a shut-off device 31, while the other cylinder part 33 with the interposition of a shut-off device 34 via a line 35 with the other Gnippe 9 v ^ n test objects 2 is connected. last test item 2a and 2b of the two groups 9 and 10 respectively

The cylinder part 30 is also via a line 40 and a shut-off element 41 and via the line 44 and the Shut-off element 45 can optionally be connected to the atmosphere. The other cylinder part 33 is on a Line 42 and a valve 43 with a fan 46 in connection and is therefore also - at switched off fan - optionally connectable to the atmosphere via the shut-off element 45.

The two cylinders 4 and 27 are connected to the two test specimen groups 9 and 10 in an identical manner, if one disregards the installation of the fan 46 and the lines 42 and 44 leading to the cylinder 27. The fan 46 is, however, advantageous in the preparation of the test and calibration activity when the test objects 2 have to run in. Expediently, the fan 46 is also connected to the Leicüng ~ 44 at a connection point 47 located in front of the Abspe rrorgan 45.

The flow profile of the air serving as the flow medium is shown in FIG. 2 in thick or dashed lines Lines shown

The fan 46 sucks air from the open shut-off device 15 through the test specimen group 9 and the line 35 as well as the one cylinder part 33 and the line 42 with the shut-off element 43 open and pushes it through the open shut-off element 41 and the cylinder part 30 as well as through the open Shut-off device 31 via line 32 through the test group 10 and line 48 as well as the opened shut-off element 16 back into the open. The shut-off devices 11 and 13 in the to the other Lines 12 and 14 leading to cylinder 4 are closed.

After the preparatory run-in of the test specimens 2, a tightness test is carried out along the lines shown in FIG Lines shown in solid or dashed lines, for example with the aid of the cylinder 4 or piston 6. For this purpose, the shut-off devices 15, 19 and 20 and 16 and 31 are closed, while the shut-off devices 11 and 13 are open.

The F i g. 4 then shows the flow profile during the Qmin test. If the piston 6 is in the position shown, the test items 2 of group 9 are tested and calibrated in suction mode with the shut-off element 15 open, while test items 2 of group 10 are tested in pressure mode.

In addition to the shut-off device 15, the shut-off devices U and 13 and 16 are open while the shut-off devices 19 and 20 as well as 31 and 34 are closed.

The F i g. Finally, FIG. 5 shows the flow profile during the 0.2 Qmax test. Here, too, the shut-off devices 15 and 16 are open, as in the Qmin test. The test and calibration is now carried out with the help of the other comparison device 26, so that the shut-off devices 11 and 13 are closed and the shut-off devices 34 and 31 are opened in their place so that the comparison volumes can be sucked in or expressed by the piston 28 . The Äbsperrorgaiic 4i unu 43 are closed at the same time.

All shut-off devices are expediently operated electro-pneumatically and can be controlled remotely, so that the entire test sequence can be carried out fully automatically. The amount of work associated with testing and calibration is therefore overall considerably simplified and shortened compared to known methods and test benches. Achieved This is especially the case when, according to the programs shown in FIGS. 4 and 5, after the test at the operating point Qmin, a test at the operating point 0.2 Qmax follows, so that the two comparison devices 3 and 76 each operate alternately will. One group 9 is then always with the

Test Qmin and 0.2 Qmax checked in suction mode.

while this is the case with the other test group 50 im

Printing operation takes place. The piston rod 48 of the piston 28 of the second

Comparison device 26 is also connected to the threaded spindle 22 for this purpose, so that the two Pistons 6 and 28 or their piston rods 21 and 48 are rigidly connected to one another.

The pistons S and 28 are in the cylinders. 4 and 27

each displaceable in a very precise manner, including pulse generators that control the drive 24 on suitable Places are arranged.

In addition 5 sheets of drawings

Claims (11)

Patent claims: 1. Device for testing and / or calibration of diaphragm gas meters by means of one to several test items connectable comparison device with known volume, characterized in that as a comparison device, at least one known cylinder (4) and one piston (6) having device (3,26) with an associated drive (24) is provided, and that this Device (3, 26) is arranged between two groups (9, 10) of test objects (2) 2. Apparatus according to claim 1, characterized by the simultaneous use of two Pistons (6.28) and two cylinders (4.27). 3. Apparatus according to claim 1 and 2, characterized in that the two pistons (6, 28) are rigid are connected to each other. 4. Apparatus according to claim 1 to 3, characterized in that the comparison volumes of the both Ztfiader (4,27) are different. 5. Apparatus according to claim 4, characterized in that the comparison volume (5) of one cylinder (4) has the measured variable Qmin and the comparison volume of the other cylinder (27) has the measured variable 0.2 Qmax . 6. Apparatus according to claim 1, characterized in that the on both sides of the piston (6.28) arranged cylinder parts (7, 8 or 30, 33) of the cylinder or cylinders (4, 27) with the two groups (9, 10) of test items (2) can be connected via lines with shut-off devices are. 7. The device according to claim 1, characterized in that the piston (6, TS) is displaceable with the aid of a controllable drive, preferably an electric drive (24). 8. The device according to claim 1, characterized in that one with the piston or pistons (6, 28) connected threaded spindle (22) provided and from the drive (24) by means of a spindle nut (23) is adjustable. 9. The device according to claim 1, characterized in that the threaded spindle (22) is axially displaceable. 10. The device according to claim 1, characterized in that on one side of the Piston (6) located cylinder part (7) with the atmosphere and the one group (9) of Test objects (2) and the other cylinder part (8) with the atmosphere and the other group (10) of Test objects (2) can be connected. 11. The device according to claim !, characterized in that a fan (46) in addition provided and with one cylinder part (33) of one cylinder (27) on the one hand and on the other hand over a shut-off device (16) with the atmosphere and also a group (10) of test objects (2) is connectable.