NL8401875A - FLOW METER. - Google Patents

Description

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N032566 1

By flow measurement count tel.

I II I JT

The invention relates to a flow measuring device with a flow meter, such as a meter with a wing wheel, and an additional device which increases the measuring accuracy in the lower measuring range.

It is known that flow meters, such as gauges with touchless wingwheels, give very accurate results over most of the measuring range, but that measurement errors must be taken for granted at small flow rates per unit time. At very small flow rates, the flow meter no longer responds at all. This can give rise to difficulties when a bill of use has to be obtained by the flow measurement, for instance when the heating water consumption or the amount of heat dependent on it has to be determined in district heating installations.

Therefore, many additional devices are already known to increase the measuring accuracy in the lower measuring range. Thus, by generating vibrations, the low friction of a rotor of the flow measuring device can be reduced (DE-OS 3,124,683). The top of the error curve can be lowered by selecting 20 specific configurations of the measuring chamber (DE-PS-846.624). A impeller can be hit by a jet from a nozzle and given it a high speed (DE-OS-2.616.323). In all cases, only the measuring errors in the lower measuring range are reduced, but the fact is not set aside that at very low flow rates the rotor of the flow meter no longer appeals at all.

Furthermore, a flow-through measuring device is known (DE-OS 2.621.278), with which pulsating flow-through quantities must be measured, such as, for example, these are delivered by a membrane pump for fuel in a motor vehicle. The entrance to the flow meter is connected to a variable volume accumulation chamber which is bounded by a movable wall in the form of a spring loaded diaphragm. The opposite diaphragm delimits a bale chamber, which communicates with the output of the flow meter. The pulsation chamber can be smoothed with the accumulation chamber, so that the flow meter determines the average flow rate.

The object of the invention is to provide a flow measuring device of the above-mentioned type, in which not only the errors in the lower measuring range are reduced, but also very small flow rates can be measured.

8401875 '*> ü 2

This object is achieved according to the invention in that the additional device comprises: a) a known volume accumulation chamber known per se, which is bounded by a movable wall, the side of the movable wall remote from the accumulation chamber delimiting a pressing chamber, connected to the side of the flow meter remote from the accumulation chamber, and b) a blocking valve connected after the accumulation chamber and in series with the flow meter, which opens when the movable wall reaches a first position during the outward movement. , which corresponds to a larger volume of accumulation, and closes when the movable wall, when moved inwards, reaches a second position, which corresponds to a small volume of accumulation.

15

If very small flow rates occur in this version, the blocking valve is closed. The liquid then collects in the accumulation chamber until the movable wall reaches the first position. Then the blocking valve is opened and the contents of the accumulation chamber are passed in one go through the flow meter. As soon as the movable wall reaches the second position, the blocking valve closes again. In this mode of operation, the flow measurement is problem-free, because the liquid flows through the measuring chamber of the flow meter at a sufficiently high speed. The blocking valve can be arranged in front of or behind the flow meter.

In a preferred embodiment it is provided that a throttle connected after the accumulation chamber is also in series with the flow meter and the blocking valve and can be changed from a value with a greater throttling resistance to a value with a smaller throttling resistance. movable wall is moved beyond the first position. The throttling means ensures that after opening the blocking valve, the contents of the accumulation chamber are dispensed in a certain period of time, so that the behavior with regard to the start-up and run-out at the flow-through valve is negligible. However, as soon as a larger flow rate has to be measured, the throttle is automatically disabled so that normal measurement is not obstructed.

It is advantageous if the blocking valve has an even closing movement. Since a certain time is required for the closing movement, problems are avoided which occur with hopping-like closing movement. c ♦ 3 occurred by checking the flow meter. Such a closing movement can for instance be effected via a denip device. The blocking valve can also be designed as a diaphragm, such as with a camera, which closes slowly.

5 The throttle is expediently located between the accumulation chamber and the shut-off valve. In this way the throttle can be controlled from the movable wall, without the need for seals.

It is advantageous if the movable wall is loaded inwards by a force in the direction. This force can be generated by a spring, elastic material, weights, a floating body and the like. This makes it possible to send the contents of the accumulation chamber through the flow meter at a predetermined speed after opening the blocking valve.

In a particularly advantageous manner, the side of the movable wall remote from the accumulation chamber limits a pressing chamber which is connected to the side of the flow meter remote from the accumulation chamber. In this way, the predetermined force after opening the blocking valve only has to act against the pressure drop at the flow-through meter, so that correspondingly small forces are sufficient.

In particular, the movable wall comprises a rolling membrane. This enables a relatively large stroke, so that a correspondingly large volume change of the accumulation chamber and relatively large distances between the first and second position of the movable wall are possible. Pistons which are guided close to a cylinder, metal bellows, clamped membranes and the like can also be used as movable walls.

The blocking valve can in particular be a solenoid valve. In this case, an activator must be connected to the movable wall and actuate fixed-position sensors added to the first and second positions. For example, the activator is a magnet and the fixed-position sensors are formed by Reed switches.

A purely mechanical embodiment comprises that the closing part of the blocking magnet is adjustable by an adjusting element, which can be held by a detent device in a closed position and in an open position, and which is connected to the movable wall via a coupling with dead corridor, with which the adjusting element can always be brought back from the closed position to the open position at the end of the dead corridor.

40 The combination of the locking device and the dead-end coupling 8401875 '<- 4 makes it possible to keep the blocking valve open during the movement of the movable wall from the first position to the second position and during the movement from the second position keep the first position closed.

In order to form the locking device, recesses may be present on the frame element which engage in spring-mounted locking bodies. Only if the adjusting element is displaced with a sufficiently great force, the locking bodies are pressed out of the storeys against the force of the associated springs.

The dead-end coupling can herein comprise two flights connected to the movable edge, which act on two supporting surfaces acting in opposite directions on the adjusting element while a spring is interposed. Such a freewheel clutch works quietly and in a guaranteed manner.

In a preferred embodiment, provision is made for the adjustable throttle element of the throttle to have a predetermined rest position, which corresponds to the value of the greater throttle resistance and is connected to the movable wall via a driver, which entrains the throttle element in a working position, which corresponds to the value of the smaller throttling resistance when the movable wall is on the other side of the first position. All connecting elements can be arranged in the accumulation chamber, so that no sealing is necessary.

The driver can be mounted directly on the movable wall or on the frame member 25.

In a particularly advantageous manner, the throttle element is a filler body which partly fills an outlet opening of the accumulation chamber in the rest position and is moved out of the outlet opening in the working position. This results in a small pressure drop with a large flow.

In a further embodiment, the valve seat of the blocking check valve can be present at the outlet opening of the accumulation chamber and the closing part can be designed as a valve disc and the throttle member can be designed as a filling body connected thereto. Throttle-35 and blocking valve therefore form a structural unit.

The invention is explained in more detail below with reference to exemplary embodiments shown in the drawing. In these drawings: Fig. 1 shows a schematic representation of a first embodiment, Fig. 2 shows a schematic representation of a second embodiment, and Fig. 3 shows a schematic representation of a detailed embodiment.

The flow-through device 1 shown in Fig. 1 comprises a supply stub and a discharge stub 3. Between them is a flow meter 4 designed as a wing wheel 5, which is arranged in a measuring chamber 5 and, by contact without scanning, through an optical sensor 6 pulses on a counter 7, the counter value of which corresponds to the quantity which has flowed through up to that time.

For the flow-through measuring device 4, an additional device 8 is connected, which comprises an accumulation chamber 9 and a downstream electromagnetic blocking valve 10. The accumulation chamber 9 has a movable wall 11 which is formed by a rigid plate and a rolling membrane 13. An activator 15, e.g. a permanent magnet connected, connecting two superimposed feet 16 and 17, e.g. Reed switches can activate. These are connected via lines 18 and 19 to a switching device, which in turn can activate an electromagnet 21 of the electromagnetic blocking valve 10. It is provided with a hydraulic damping device 21a known per se, which slows down the closing movement.

A throttle member 22 has as throttle element 23 a filler body arranged in the outlet opening 24 of the accumulation chamber 9. This is provided with a rod 25, which is guided in a bearing 26 and carries a head 25a at the top end, which can be carried along by a carrier 27 connected to the movable wall 11.

The capital letters A, B and C illustrate three positions of the movable wall 11. In position A the sensor 16 is energized, in position B the sensor 17 is energized and in position G the driver 27 engages on head 25a.

The movable wall 11 is loaded by a spring 28. On the side 30 opposite the accumulation chamber 9, there is a pressing chamber 29, which is connected to the exhaust stub via a line 30.

This flow measuring device operates as follows: in the rest position, the blocking valve 10 is closed. If now a very small amount of liquid flows in via the inlet stub 2, the blocking valve 35 remains closed. However, the accumulation chamber 9 becomes larger, while the movable wall 11 is moved upwards against the force of the spring 28. As soon as this position reaches B and the sensor 17 responds, the blocking valve opens and the amount of liquid stored is forced out of the accumulation chamber 9 via the flow meter 40 to the outlet stub 3 under the influence of the spring 28. Here, the throttle 8401875 i * v 6 causes throttling such that the flow rate is sufficient to allow the flow meter 4 to operate satisfactorily, but on the other hand makes the measuring time so long that the start-up and run-out behavior does not have a significant influence on have the measurement result. When the movable wall 11 has reached position A again and the sensor 16 responds, the blocking valve 10 is closed so slowly that the run-out operation of the flow meter with wing wheel is not affected. This cycle can be repeated several times.

If a larger quantity flows against it, the wall 10 of the movable wall 11 is moved beyond position B to position C and beyond. Since the driver 27 becomes active in this case, the throttle element 23 is brought up from the outlet opening 24, so that the throttling action is eliminated. At such flow rates, the flow meter 4 operates normally and without significant errors.

The amount of liquid to be stored depends on the present conditions and the type of flow meter. With a meter with a wing wheel it is sufficient to be able to store about 4% of the maximum flow rate per unit time. In an exemplary embodiment, therefore, the change in the volume of the accumulation chamber 9 was 0.2 liters in the whole, while the flow meter in the measuring range between 40 and 1000 l / h operated normally, ie with continuous flow.

In the embodiment according to Fig. 2, the control of the blocking valve 110 takes place not electromagnetically but mechanically.

Reference numerals which have been increased by 100 relative to FIG. 1 are used for corresponding parts. A closure member 131 of the blocking valve 110 cooperates with a valve seat 132 surrounding the outlet opening 124. This closing part is connected as a part to a throttle element 123, which is arranged in the outlet opening 124.

At the movable wall 111, the plate 12 is replaced by a molded part 112 with an annular receiving space for the spring 128. The molded part 112 carries a rod 133 which is connected to a setting element 135 via a dead-end coupling 134. The dead-end coupling has two pins 136 and 137 on the rod 133, each acting as flights, which can each act on one end of the spring 138 and oppositely oriented supporting surfaces 139 and 139a on the adjusting element 135, which with the different end of the spring 138 can cooperate. A detent direction 140 has two roller-like detent members 141, the shafts 40 of which are always loaded by a compression spring 142 and therefore can optionally engage a recess 143 or an recess 144 located therebetween in the adjusting element 135.

This flow-through device works as follows: in the rest state, the blocking valve 110 is closed. If an insufficient amount of supplied quantity is present, the blocking valve remains closed. However, the movable wall 111 is moved upwards. The adjusting element 135 is hereby held in the closed position by the locking device 140. Only when the driver 137 reaches the spring 138 position B, the adjusting element 135 is carried upwards, whereby the detent members 141 10 transition from the floor 143 into the floor 144. In this case, the head 125a of the rod 125 is raised slightly by the driver 127 at the adjusting element 135, so that the blocking valve 101 is open, but the throttle member 122 is still in the state with the greatest throttling resistance. As a result, the accumulated liquid can be delivered to the outlet via the flow meter through the spring 128. As soon as position A is again reached, in which the driver 136 acts on the spring 138 from above, the adjusting element 135 shifts downwards and the blocking valve 110 is closed again. This cycle can be repeated many times.

If a larger inflowed amount is present, the movable wall 111 moves further upwards beyond position B, pulling the rod 125 and thereby the throttle 123 upwards, until finally the throttle in position C completely out of the exit opening. 124 has been brought up. Now the flow-in quantity can reach the flow meter without throttling.

In Fig. 3, where reference numerals are used which are enlarged 200 for corresponding parts, the accumulation chamber 209 is connected to the supply stub 202 via a branch line 230, while the discharge stub 203 extends away from the baling chamber 229. The blocking valve 110 and the throttling valve 122, as in FIG. 2, are combined together. The parts arranged between the closing part 202 of the blocking valve 110 and the movable wall 211, such as the dead-end coupling and the like, are designed in a similar manner as in Fig. 2. The movable wall can also be formed by a closed piston or by a metal bellows.

The flow meter is particularly suitable for district heating installations, where the water consumption or the use of heat energy must be accurately determined for longer time intervals.

8401875

Claims (15)

1. Flow meter with a flow meter, such as a meter with a wing wheel, and an additional device, which increases the measuring accuracy in the lower measuring area, characterized in that the additional device (8, 108) comprises: a) an accumulation chamber known per se (9, 109, 209) of variable volume delimited by a movable wall (11, 111, 211), the side of the movable wall facing away from the accumulation chamber a baling chamber (29, 129, 229 ) which is connected to the side of the flow meter (4) which faces away from the accumulation chamber, and b) a blocking valve (10, 110, 210) connected in series behind the accumulation chamber and with a flow meter. it opens when the movable wall reaches a first position (B) during the outward movement which corresponds to a larger accumulation volume, and closes when the movable wall reaches a second position (A) when moving inwards, which has a smaller a accumulation volume corresponds. Flow measuring device according to claim 1, characterized in that a throttle (22, 122, 222) connected behind the accumulation chamber (9, 109, 209) also with the flow meter (4) and the blocking valve (10, 110, 210 ) is in series and can be changed from a value with a greater throttling resistance to a value with a smaller throttling resistance when the movable wall (11; 111; 211) is moved beyond the first position (B). Flow measuring device according to claim 1 or 2, characterized in that the blocking valve (10) has an even closing movement. Flow measuring device according to claim 2 or 3, characterized in that the throttle (22; 122) is located between the accumulator (9; 109) and the blocking valve (4). Flow-through measuring device according to one of the preceding claims, characterized in that the movable wall (11; 111; 211) is loaded inwardly by a force. Flow-through measuring device according to one of the preceding claims, characterized in that the movable wall (11; 111; 211) comprises a rolling membrane (13; 113). Flow measuring device according to any of the preceding claims, 40, characterized in that the blocking valve (10) is a magnetic valve 8401875 ί * and that an activator (15) is connected to the movable wall (11), which activator is fixed sensors (16 , 17) energized, which are added to the first and second positions (B, A). Flow-through measuring device according to claim 7, characterized in that the sensors (16, 17) can be controlled without contact. Flow measuring device according to one of Claims 1 to 6, characterized in that the closing part (131) of the blocking valve (110) is adjustable by an adjusting element (135) which is arranged in a locking device (140) in a closed position and an open position can be maintained and which is connected to the movable wall (111) via a coupling (134) with dead passage, via which the adjusting element is always moved from the closed position into the opened position at the end of the dead passage stand and bring it back. Flow-through measuring device according to claim 9, characterized in that recesses (143, 144), in which resiliently arranged locking bodies (142) engage, are formed on the adjusting element (135) to form the locking device (140). Flow measuring device according to claim 9 or 10, characterized in that the dead-end coupling (134) comprises two flights (136, 137) connected to the movable wall (111) and which are interposed by a spring ( 138) act on two support surfaces (139, 139a) acting in opposite directions on the adjusting element (135). Flow measurement device according to any one of claims 2 to 11, characterized in that the adjustable throttle element (23; 123) of the throttle (22; 122) has a predetermined rest position corresponding to the value of the greater throttle resistance , and is connected to the movable wall (11, 111) via a driver (27; 127), which takes the throttle element into a working position corresponding to the value of the smaller throttle resistance, when the movable wall is on the other side from the first position (B). Flow-through measuring device according to one of Claims 9 to 12, characterized in that the driver (127) is arranged on the adjusting member (135). Flow measuring device according to claim 12 or 13, characterized in that the throttle element (22, 122) is a filler body, which in the rest position partially fills an outlet opening (24; 124) of the accumulation chamber (9, 109) and in the operating position is moved out of the exhaust vent. Flow measuring device according to claims 9 and 14, characterized in that the valve seat (132) of the blocking valve (110) 8401875 is arranged at the outlet opening (24) of the accumulation chamber (109) and that the closing part (131) is designed as a valve disc and the throttle element (123) is designed as a filler body connected thereto. 5 ============ 8401875