DE10156929A1 - Volume flow meter and gas meter with relaxation chamber - Google Patents

Abstract

This volume flow meter for gas contains a housing (1), which is divided by a membrane (2) into an expansion chamber (3) and a housing chamber (4), as well as a sensor for the displacement of a locking device (8). Means are provided to obtain a clearly constant difference between the pressure prevailing in the inlet line of the chamber (3) and that prevailing in the outlet line of this chamber.

Description

The present invention relates to volume flow meters for gas and gas meters in which che volume flow meters of this type are installed and which with a device for Integrate the volume flows over time.

It is common to use a gas flow meter and a device to make a gas meter device for integrating the volume flows determined by the volume flow meters the time to finish.

Numerous types of meters are known, for example meters with deformable walls, in which the ratio of the minimum volume flow to the maximum volume flow, which is also called measurement dynamics, is of the order of magnitude of 140. These meters are very voluminous, in such a way that in practice their maximum volume flow cannot exceed 1000 m ³ per hour. Counters with rotary pistons are also known, which have a measurement dynamic that does not exceed the number 50. The ultrasonic meters are very sensitive to dust and therefore require long straight distances, especially in front of the meter, just like the vortex meters and the volume meters with a vacuum gauge. A volume flow meter is also known which uses a venturi tube which works on the nozzle neck according to the sonic principle. This volume flow meter is difficult to use and manufacture due to the mechanically machined profile and provides inaccurate results that show a certain degree of variation.

The invention relates to a volume flow meter and thus a gas meter with min derten dimensions even for high volume flows, which in a wide range of Pressing the incoming medium can be used, which is from 100 millibars to 8 Bar is sufficient, which has a large dynamic range of over 140, against disturbances the flow profile is insensitive before entering and therefore does not have a long Ge bike routes required, which has a high intrinsic accuracy by being completely in the area works below the speed of sound by simply connecting the the piping is easy to install and is insensitive to dust. The The meter is robust even at high pressures such as 8 bar and does not generate any parasitic Pressure loss.

The volume flow meter according to the present invention contains a housing that through a flexible membrane into a relaxation chamber into which an intermediate line  opens out, which is equipped with a closing valve and an outlet line, and a housing chamber is divided, in which a means, in particular a spring - but it can also be a pilot pressure - a force exerted on the membrane. The membrane is firmly connected with the locking device in terms of displacement, and it is a Transducer provided for the displacement of the locking device. According to the Erfin Means are available which comprise an input connection and which are intended for this purpose are, for a given volume flow regardless of its size and also independent depending on how high the pressure in the inlet connection for this Vo lumen flow is a clearly constant difference between the pressure in the Intermediate line prevails and to maintain the pressure prevailing in the outlet line A clearly constant difference means, in particular, one of about 5%, but preferably about 1% constant value. The pressure in the inlet line can between 100 millibars and 8 bars.

According to one form of performance, the means intended to do so clearly exist constant difference between the pressure in the intermediate line and to obtain the pressure prevailing in the outlet line from one before the intermediate Primary gas expansion device installed at a certain distance from the housing. This primary decompressor therefore provides an intermediate to the volume flow meter pressure that is clearly constant for any given volume flow, d. H. that this pressure can change from one volume flow to another.

The primary decompressor can include a valve which is fixedly connected to the displacement of a diaphragm directly via a spindle or by means of a mechanism with multiplier effect for the displacement, by this mechanism a lever arm r for the closing device of the valve and a lever arm R for the membrane contains. In the present document, the closing device is understood to mean the movable part of the valve which moves with respect to the fixed valve seat. The ratio S _c / S _m r / R is less than 0.01, but preferably less than 0.001, where S _{c is} the area of the valve seat and S _{m is} the area of the membrane. Since the ratio of the change in the intermediate pressure to the change in the inlet pressure is on the one hand proportional to the ratio of the area of the valve seat to the area of the diaphragm and on the other hand is proportional to the ratio of the lever arm of the closing device to the lever arm of the diaphragm if there is a multiplier effect, this enables further ahead On mentioned arrangement that a clearly constant difference between the pressure prevailing in the intermediate line and the pressure prevailing in the outlet line is created. The area of the membrane is equal to the diameter of the membrane that is taken on the outer circumference on which it is attached.

Another way of making a constant difference between the pressures in the Intermediate line prevails and to maintain the pressure prevailing in the outlet line ten is to provide an articulated parallelogram, one of which the corner is fixed and the opposite one with the membrane of the mechanism the multiplier effect is firmly connected and between the other two corner points of the parallelogram extends a spring which is mounted in such a way that it continues a mainspring of the primary expansion as it evolves stressed. When the diaphragm of the primary decompressor lowers, the main spring exercises this primary relaxer, which exerts a counterforce to the intermediate pressure by relaxes, a force whose strength becomes smaller and smaller. If you have the articulated Parallelogram provides a spring acting on tension, which is either in the Chamber with the main spring or in the chamber of the primary expansion device, in which the intermediate pressure prevails and which is on the other side of the membrane than that Main spring, the intermediate pressure remains as constant as possible, even if the pressure at the inlet changes for the same volume flow. you can use an articulated parallelogram alone or in conjunction with the arrangement zen, which uses the ratio of the areas of the valve seat and the diaphragm.

It is also possible to use means to achieve that the pressure, that prevails in the input port on a surface of one side of the locking device of the valve acts which is smaller than an area of the opposite side of the closure device where the intermediate pressure acts. This also enables one and the same Volume flow to keep the intermediate pressure constant, even when the input pressure changes. As a means by which to achieve the pressure in the one there is no connection to a surface of one side of the locking device of the Ven tils acts, which is equal to an area of the opposite side, where the intermediate pressure is present, you can provide a cylinder on the locking device from the side is attached, which is opposite the valve seat, and an opening, which is in the closing device is located and runs from one side of the same to the other. Therefore there is the intermediate pressure from the side opposite the valve seat as from the other Side in the entire part of the closing device, which is opposite the valve seat place. This embodiment is preferably combined with that with a parallelogram.

Another preferred means that is used to make the difference between the Pressure in the intermediate pipe and in the outlet pipe prevails, is clearly constant, is that the primary relaxer is a body contains that of a membrane in a relaxation chamber and in a reference chamber is subdivided and that means are provided which determine that a Be  tension in the reference chamber. The means that are intended for that the reference pressure prevails, may contain a reference relaxer, the starting line tion opens into a reference chamber. But the input line of the reference relaxer or the primary expansion device can be connected to the expansion chamber. you receives a regulation of the intermediate pressure. This type of execution can with the before the types of execution concerned, and in particular those associated with Contains means that are designed so that the inlet pressure is not on a surface of a Side of the valve closing device acts.

According to the most preferred embodiment, the reference relaxer and the primary decompressor one and the same housing. This gives a very compact Arrangement and one piece.

The reference pressure that prevails in the reference chamber, thanks to a line that the Reference chamber and the relaxation chamber connects to be equal to the outlet pressure. This makes the difference between the intermediate pressure and the output pressure more constant with less possibility of scattering.

The displacement sensor can be of the conventional type. He can esp special from a gear between the spindle of the valve and the axis of a pot tiometers exist. This can also be a linear displacement transducer, the is preferably arranged in the alignment of the spindle of the valve. He can also be a System with differential transformer, an optical pickup or a capacitive pickup mer or somebody else.

According to a preferred embodiment, a means for reducing the who tes the displacement of the locking device provided by, for example, a Attaches rack to the valve stem, which engages a gear train, the End wheel can contain magnets which are distributed on the circumference and which are suitable to act on interrupters with flexible leaflet (reed contact). You win that Volume flow from the duration of the stay in the different positions.

According to another embodiment, the means which are intended to contain one clearly constant difference between the pressure in the intermediate line, and the pressure prevailing in the outlet line to obtain a line to the manufacturer the connection between the intermediate line and the housing chamber. In this Fall is independent of the pressure in the intermediate line and consequently in the housing secammer prevails, the pressure difference between this latter pressure and the  Pressure in the intermediate line is constant for a given volume flow, regardless of how high this volume flow is, which is how it should be understood is that this pressure difference can change depending on the volume flow.

Thanks to this clearly constant difference between the pressure in the intermediate line prevails, and the person who rules in the output line gives the different Exercise the closing device of the valve the volume flow in an accurate manner again. By simply calibrating the equipment, in which the volume flows in Depends on the displacement of the locking device, one can therefore not get the volume flows by simply shifting the Locking device detected.

One can also use a transducer for the pressure in the intermediate line and Provide means for calculation which determine the volume flow of the gas on the basis of the pressure signal supplied by the transducer and the pressure in the output line prevails, calculated. One can also provide a transducer for the pressure, which in the output line prevails, and ensure that the means for calculation the Vo lumen flow of the gas based on the pressure signal from the transducer for the pressure prevailing in the intermediate line and the signal which is supplied by is delivered to the transducer for the pressure prevailing in the outlet line, be expected.

According to an improved embodiment, a sensor for the temperature, the prevails in the input line, provided, this temperature sensor to a signal provides the means for the calculation so that it depends on the volume flow of the gas Correct the temperature.

The calculation means can also be used as a device for integrating the volumes currents depending on the time can be used to implement a counter.

The closing device preferably contains, in addition to an elastic part, the sealing ensures a rigid part that allows the relative displacement to be accurate to determine.

In the attached drawing, which is intended solely as an example, are

Fig. 1 to 4 are sectional views of four embodiments of the invention, and

Fig. 5 is a sectional view of the mechanism for reducing the displacement of the locking device.

The volume flow meter shown in Fig. 1 contains a housing 1 , which is divided by a flexible membrane 2 into a relaxation chamber 3 and a housing chamber 4 un. The housing 1 contains an intermediate line 5 and an output line 6 , both of which open into the expansion chamber 3 . The intermediate line 5 is equipped with a valve which comprises a seat 7 and a closing device 8 . The closing device includes an elastic part 9 , which ensures tightness, and a rigid part 10 , which comes into contact with the seat 7 first when the valve closes. Thanks to this contact between the rigid seat 7 and the rigid part 10 , the position of the closing device is precisely determined, even if the volume flow is virtually zero. The locking device 8 is carried by a small rod 11 , which is mounted on recesses recessed in the housing 1 in such a way that it can be translated. The spindle 11 is articulated by an arm 12 with a diaphragm bearing journal 13 which is firmly connected to the diaphragm 2 . A position sensor 14 is attached opposite the spindle 11 , which enables the displacement of the spindle 11 and thus that of the locking device 8 to be determined.

A spring 15 is fastened in the housing chamber 4 in the manner conventional for a gas expansion device, one end of which abuts the membrane, while the other abuts the top of the housing 1 .

The intermediate line 5 opens against the direction of flow into an expansion chamber 16 of a primary gas expander, which contains a body 17 which is divided by a membrane 18 into a first compartment 19 in which there is a main spring 20 , one end of which against the membrane 18 presses and pushes the other end onto the top of the body 17 and into the chamber 16 . A diaphragm bearing pin 21 , which is fixedly connected to this, is articulated with a lever 22 which acts on a spindle 23 of a closing device 25 of the valve and can act or not act on a seat 26 according to its position. An input port 27 opens into chamber 16 .

When gas flows through the volume flow meter, the closing device 8 moves away from the seat 7 more or less depending on the volume flow. This steering is detected by the transducer 14 , which displays the current volume flow. If you want to convert this volume flow meter into a meter, it is sufficient to add a device for integrating the volume flows over time.

In the chamber 16 there are a pressure sensor 29 , which is connected to a computing device 31 via a line 30 , and a temperature sensor 32 , which is connected to the computing device 31 via a line 33 . There is also a pressure transducer 34 in chamber 3 . This sensor 34 is connected via a line 35 to the computing device 31 , and the sensor 14 is also connected to the computing device 31 via a line 36 . In the device 31 , the pressure difference is calculated on the basis of the signals supplied by the sensors 29 and 34 , and the instantaneous volume flow can be determined on the basis of this pressure difference signal and the position signal supplied by the sensor 14 , the computing device 31 immediately transmitting these volume flows integrates the time to provide an indication of the cumulative volume flows corresponding to what a meter should deliver. The calculation preferably includes a temperature correction based on the signal output by the sensor 32 .

In FIG. 2, the flow meter is similar to that of FIG. 1, only one conduit 28 is provided for producing a connection between the chamber 16 and the chamber 4 and the spring 15 is no longer a pressure spring, but a spring, which on Train works. The membrane 2 is therefore subject to this tensile force and a force that results from the difference between the high pressure that prevails in the housing chamber 4 and the lower pressure that prevails in the expansion chamber 3 .

The embodiment shown in FIG. 3 is identical to that of FIG. 1, but with the following differences:
Here is a line 37 for establishing a connection between the expansion chamber 3 and the compartment 19 . To ensure accuracy, the pressure of chamber 3 should prevail in compartment 19 instead of atmospheric air pressure, for example 20 mbar.

In addition, the embodiment of FIG. 3 contains the following two improvements:
On the underside (in the figure) of the closing device 25 , that is to say on the side which is remote from the seat 26 , a cylinder 38 is fastened which slides tightly in a connecting piece 39 which emerges from the body 17 . An opening 40 is drilled in the closing device 25 , which connects the space in the cylinder 38 to the chamber 16 . The inlet pressure therefore does not act on the closing device 25 in the part of the same compared to the cylinder 38 , so that even if this pressure changes, this has only a slight influence on the intermediate pressure.

An articulated parallelogram 41 is present, one of its corner points 42 being articulated to the lever 22 , while the opposite corner point is articulated to the body 17 . A spring 46 is mounted between the two other corner points 44 and 45 . Thanks to this articulated and provided with spring parallelogram program, when the main spring 20 of the primary expander relaxes and thus a smaller and smaller force to the diaphragm 18 through which Parallelogrammvorrich tung a compensation force in the same direction on the diaphragm 18 applied. This helps to keep the intermediate pressure at a clearly constant value.

The embodiment shown in FIG. 4 takes up that which is shown in FIG. 1, with the following difference:
The body 17 is divided in the figure from top to bottom by an upper membrane 50 , an upper partition 51 , a lower partition 52 and a lower membrane 53 into an upper chamber 54 , an intermediate chamber 55 , an intermediate chamber below 56 and a lower chamber 57 . The lower intermediate chamber 56 is connected via a line 58 to the input connection 27 . The upper chamber 54 is connected via a line 59 with the expansion chamber 3 in United. The upper intermediate chamber 55 is connected via a line 60 to the expansion chamber 16 of the primary expansion device. Line 60 is calibrated. The upper intermediate chamber 55 is connected to the lower chamber 57 via a calibrated line 61 . The lower chamber 57 is connected to the expansion chamber 16 of the primary expansion device via a calibrated opening 62 . The opening 62 has a smaller diameter than the diameter of the lines 60 and 61 .

A reference spring 63 is mounted in the upper chamber 54 , one end of which acts on the body 17 and the other end acts on the top of the diaphragm 50 . On the opposite side of the diaphragm 50 , a reference closing device 64 is fastened, which is accommodated in the lower intermediate chamber 56 and whose spindle passes through the partition wall 51 in such a way that it is firmly connected to the underside of the diaphragm 50 . The locking device 64 can be designed such that it fits on a seat 65 which is worked out on the underside of the partition 51 . The spindle 21 is attached to the underside of the membrane 53 . The body 17 encloses the entirety of the parts that have just been described.

The volume flow meter works in the following way: The inlet pressure prevails via the line 58 in the lower intermediate chamber 56 . Depending on the pressure prevailing in the expansion chamber 16 of the primary decompressor and acting in the upper intermediate chamber 55 , a very low volume flow occurs between the valve 64 and the seat 65 and thus maintains the reference pressure in the lower chamber 57 by means of the line 61 at a given value corresponding to the load on the spring 63 . The gas can escape from the lower chamber through opening 62 . The pressure prevailing in the chamber 16 is therefore clearly constant for a given volume flow and for a large range of the inlet pressure.

In FIG. 5 is mounted on the spindle 11, a rack 66, which engages in a pinion 67 which rotation is firmly connected to a gear 68 with respect to. The gear wheel 68 engages in a pinion 69 , which is fixedly connected with respect to the rotation with another gear 70 , whereby the effect of the reduction comes about. The wheel 70 engages in an end wheel 71 , which carries eight magnets 72 on its circumference, which move to the extent that the wheel 71 rotates in front of an interrupter 73 with elastic leaflets. The interrupter 73 is connected to the computer 31 .

Claims (15)

1. volume flow meter for gas, which comprises a housing ( 1 ),
which is divided by a flexible membrane ( 2 )
into a relaxation chamber ( 3 ),
into the an intermediate line ( 5 ), which is equipped with a valve with closing device ( 8 ), and an outlet line ( 6 ),
and into a housing chamber ( 4 ),
in which a means ( 15 ) exerts a force on the diaphragm ( 2 ), where in the latter the displacement is firmly connected to the closing device ( 8 ),
and a sensor ( 14 ) for displacing the locking device ( 8 ),
and means are provided which contain an inlet connection ( 27 ) and are intended for a given arbitrary volume flow in the inlet connection and regardless of the pressure prevailing for this volume flow in the inlet connection, a clearly constant difference between the pressure , which prevails in the intermediate line ( 5 ), and that which prevails in the outlet line ( 6 ), the said means consisting of a primary gas expansion device ( 16 to 27 ) which is on the flow side in front of the intermediate line ( 5 ) a certain distance from the housing is attached, which in the intermediate line ( 5 ) delivers a clearly constant pressure for a given arbitrary volume flow, characterized in that the primary expansion device contains a closing device ( 25 ) which is fixedly connected with respect to the displacement Membrane ( 18 ) directly over a rod ( 21 ) or by means of a mechanism ( 22 ) with multiplier effect for the displacement, which has a lever arm r of the closing device ( 25 ) of the valve and a lever arm R of the membrane ( 18 ), the ratio S _c / S _m r / R being less than 0.01, but preferably less than 0.001, where S _{c is} the area of the valve seat and S _{m is} that of the membrane ( 18 ). 2. Volume flow meter according to claim 1, characterized by an articulated parallel lelogram ( 41 ), one of its corner points ( 43 ) being fixed and the corner point ( 42 ) opposite this being firmly connected to the membrane ( 18 ) or the mechanism with a multiplier effect and in which between the two other corner points ( 44 , 45 ) extends a spring which is mounted in such a way that it continues a main spring ( 20 ) of the primary expansion device to the extent that it yields. 3. Volume flow meter for gas, which comprises a housing ( 1 ),
which is divided by a flexible membrane ( 2 )
into a relaxation chamber ( 3 ),
into the an intermediate line ( 5 ), which is equipped with a valve with closing device ( 8 ), and an outlet line ( 6 ),
and into a housing chamber ( 4 ),
in which a means ( 15 ) exerts a force on the membrane ( 2 ), which is firmly connected with respect to the displacement with the closing device ( 8 ),
and a sensor ( 14 ) for displacing the locking device ( 8 ),
and means are provided which contain an inlet connection ( 27 ) and are intended for a given arbitrary volume flow in the inlet connection and regardless of the pressure prevailing for this volume flow in the inlet connection, a clearly constant difference between the pressure , which prevails in the intermediate line ( 5 ), and that which prevails in the outlet line ( 6 ), the said means consisting of a primary gas expansion device ( 16 to 27 ) which is on the flow side in front of the intermediate line ( 5 ) a certain distance from the housing is attached, which in the inter mediate line ( 5 ) delivers a clearly constant pressure for a given arbitrary volume flow, characterized by means which are intended to cause the inlet pressure to a surface of one side of the closing device ( 25 ) of the valve acts, which is smaller than an area of the opposite side of the closing device where the intermediate pressure is present. 4. Volume flow meter according to claim 3, characterized by a cylinder ( 38 ) which is attached to the closing device ( 25 ) on the side opposite the seat ( 26 ), and by an opening ( 40 ) which in the closing device ( 25 ) is spared and leads from one side of the same to the other. 5. Volume flow meter according to one of claims 1 to 4, characterized in that the primary expansion device comprises a body ( 17 ) which is divided by a membrane into a relaxation chamber ( 16 ) and a reference chamber ( 19 ), and by means ( 20 ) which are intended to cause a reference pressure to prevail in the reference chamber. 6. volume flow meter for gas, which comprises a housing ( 1 ),
which is divided by a flexible membrane ( 2 )
into a relaxation chamber ( 3 ),
into the an intermediate line ( 5 ), which is equipped with a valve with closing device ( 8 ), and an outlet line ( 6 ),
and into a housing chamber ( 4 ),
in which a means ( 15 ) exerts a force on the diaphragm ( 2 ), which is firmly connected to the closing device ( 8 ) with regard to the displacement,
and a transducer ( 14 ) for the displacement of the closing device ( 8 ), and there are means which contain an inlet connection ( 27 ) and are intended for a given volume flow in the inlet connection and independent of the pressure which is used for this volume flow prevails in the inlet connection, to obtain a clearly constant difference between the pressure prevailing in the intermediate line ( 5 ) and that prevailing in the outlet line ( 6 ), the means from a primary gas expansion device ( 16 to 27 ) exist, which is mounted on the flow side in front of the intermediate line ( 5 ) at a certain distance from the housing and which in the intermediate line ( 5 ) delivers a clearly constant pressure for a given volumetric flow, characterized in that the means which should cause that the reference pressure prevails, have a reference expander, the output line ( 61 ) in d The reference chamber ( 57 ) opens, and the fact that the input line of the reference expansion device is connected to the expansion chamber ( 16 ). 7. Volume flow meter according to one of claims 5 or 6, characterized that the reference relaxer and the primary relaxer are the same body to have.   8. Volume flow meter according to one of the preceding claims, characterized in that the means which are intended to obtain a clearly constant un difference between the pressure prevailing in the intermediate line and that prevailing in the outlet line receive a line ( 28 ) for the produc- tion of the connection of the intermediate line ( 5 ) and the housing chamber ( 4 ) included. 9. Volume flow meter according to one of the preceding claims, characterized by a sensor ( 29 ) for the pressure prevailing in the intermediate line ( 5 ), and by means ( 31 ) for calculating the volume flow of gas on the basis of the pressure signal, which is supplied by the transducer ( 29 ) and the pressure prevailing in the outlet line ( 6 ). 10. Volume flow meter according to one of the preceding claims, characterized by a sensor ( 34 ) for the pressure prevailing in the outlet line ( 5 ), and by means ( 31 ) for calculating the volume flow of gas on the basis of the pressure signal, which is supplied by the sensor ( 29 ) for the pressure prevailing in the outlet line ( 6 ) and the pressure signal supplied by the receiver ( 34 ) for the pressure prevailing in the outlet line ( 6 ). 11. Volume flow meter according to one of the preceding claims, characterized by a sensor ( 32 ) for the temperature in the intermediate line ( 5 ). 12. Volume flow meter according to one of the preceding claims, characterized in that the closing device ( 8 ) includes, among other things, an elastic part ( 9 ), which ensures tightness, and a rigid part ( 10 ), which enables the relative displacement to be precise to determine. 13. Volume flow meter according to one of the preceding claims, characterized by a means of reducing the value of the displacement of the locking device tung. 14. Counter, characterized in that it has a volume flow meter according to one of the preceding claims and a device for integrating the volume contains currents over time.   15. Volume flow meter according to one of claims 1 to 7, characterized in that the compartment ( 19 ) or the chamber ( 54 ) through a line ( 37 , 59 ) with the Ent voltage chamber ( 3 ) is in communication.