DE4016140A1 - Controlled gas flow regulator and controller - Google Patents

Abstract

A controller and regulator of gas flow consists of a chamber containing nozzles (16, 17), piston operated stop valves (20, 21) and a reservoir. The chamber has a high pressure entry space (1) within which an internal wall (22) supports two stop valve pistons (20, 21). The pistons are actuated by conduits (23, 24) and are fitted with return springs (18) (19). Nozzles of varying capacities (16, 17) are screwed into an internal wall (15) and these feed a reservoir (10) and outlet pipe (11). Total flow is regulated by microprocessor selection of combinations of nozzles opened or shut.

Description

The invention relates to a device with the help all control and control related to gas consumption control engineering (measurement, remote display, control, Regulation) tasks can be solved, regardless of whether the supply of gas consumer devices from a line of public works or from one or more containers he follows.

The supply of gas consumers brings - regardless of the gas source - both control and regulation technology Tasks with themselves. In the simplest case (in the case of Supply of small consumers from a traditional Low pressure supply network) the task is to measure the amount of gas consumed. In case of greater consumption, e.g. with a complete gas energy consumption furnished family home, which is becoming more urgent increasing demand for realizing an effective Protection against supply errors (gas shortage protection, Overpressure protection) and suddenly occurring major errors (e.g. gas leakage due to pipe breakage).

Become more common (especially in the province) Gas lines laid under a pressure (under this term is the pressure of the traditional To understand low-pressure gas supply network) To stand pressure; in this case, every single consumer via its own pressure regulator (building pressure regulator) to the Gas network connected.

In the case of industrial consumers, the control and control tasks from the point of view of Energy industry further expanded. In addition to the call for Peak limitation used in different applications Time periods different (cheapest or tightened) tariff rates required tariff switching, the  Limiting consumption and achieving protection against pipe defects, the demand for realization also grows of remote measurement and remote display increasingly.

For the fulfillment of the individual tasks are after establishments based on different principles, their use but the connection points of the gas consumers (the so-called "gas receiving stations") to increasingly complex, more expensive, more and more different Complexes containing devices.

Experiments with the Aim made to individual construction units shape it to do more than one of the tasks listed can provide. The function of the pressure regulator and Suitable construction to provide a quick-release fastener describes e.g. DE-PS 20 15 555; one for simultaneous Suitable temperature and pressure control Device describes the DE-PS 7 44 779, also as Shut-off valves can be used pressure regulators from individual Patents such as DE-PS 29 37 978 are known and further construction units fulfilling several tasks in the patent documents DE-PS 27 59 091 and DE-PS 33 26 523 to be discribed.

DE-PS 29 37 978 describes a device in which the High pressure room with the low pressure room over two different connected pipe branches with pipe shut-off fittings is, the gas permeability (throughput) of two branches is different.

In GB-OS 21 29 170 one with a locking element working, with several, but possibly the same Permeable line branches provided Pressure regulator - with a microprocessor control - described. The description of this related to the controller However, the facility does not contain any information as to whether the microprocessor-based control even after one of the  smoothly advancing different program can be done.

For regulating the quantities of different gases are Notes - especially when describing methods for Production of gas mixtures with a given composition Help of injectors - contained in GB-OS 21 08 285.

One used to determine the amount of gas flowing through Device is described in DE-OS 27 25 410. At this Facility is in the way of the inflowing medium (analog working, known per se) pressure reducer or Flow rate limiter arranged, the through this flowing gas stream by means of changeover valves in branches containing different flow resistances and the flow rate by means of the variable Flow resistance is regulated. The permeability of the individual branches is considered to be twice the permeability of the previous branch, but the Facility does not contain a control that the way the individual line branches after any predetermined Would control function. None of the above Execution solutions offer opportunities to meet measurement and remote viewing tasks.

A device that is suitable for solving almost all essential control and control tasks is described in HU-PS 1 95 346. In this device, the basic arrangement of which is shown in FIG. 1, the pipe 1 connected to the gas line network under higher pressure is connected to a container 10 connected to the line network under consumption pressure via several line branches connected in parallel so that one in each branch Controlled pipe shut-off valves 2 , 3 , 4 and 5 as well as a throttle 6 , 7 , 8 and 9 are provided and the pipe shut-off valves 2-5 are controlled via lines of action (signal lines) depending on the outlet pressure by means of a control unit 12 (the pressure sensor and the associated belonging line of action was not shown in Fig. 1), with a certain functional relationship between the transmission capabilities of the chokes 6 , 7 , 8 and 9 used in the individual branches (in the simplest case, each choke can double the amount of the choke in front of it let it flow through) and the respective position g of the pipe shut-off valves 2 , 3 , 4 and 5 is determined by the control unit 12 according to a corresponding program (in the simplest case according to a binary series of numbers). Since the current state of the control unit 12 is in a clear functional relationship with the let-through amount of gas, this device is suitable for pressure control, for displaying, measuring and remotely displaying the instantaneous value of the amount of gas flowing through, with integration of the signal after the time for measuring the total flow rate in a manner suitable for billing, in the case of a program aimed at this (by linking the opening of the individual pipe shut-off valves to other conditions) to a peak limitation, in the case of remote control of the control unit 12 also for tariff switching, for consumption limitation; by switching off the pipe shut-off fittings, it also functions as a closing fitting and, due to the differentiation of the signal proportional to the gas quantity currently flowing through, can also perform the function of a quick-release fastener, etc.

According to the description of the invention, the number of control stages can be set by the number of line branches: if n = 8 branches are used, the tubular armature valves can have a total of 2 ⁸ = 256 different positions and so, taking into account even a closed state, control can be carried out with accuracy of 1/225 ∼0.4% can be achieved.

The practical use of the device described brings however, there are two problems:

Pipe shut-off valves 2 , 3 , 4 and 5 have to carry out an extraordinarily large number of switch-on and switch-off processes in the event of dynamically changing loads. This applies in particular to the pipe shut-off valves which are arranged in line branches with a lower permeability (when using a binary system in the branches corresponding to the values 2 ⁰ , 2 ¹ and 2 ² ). If conventional (known) pipe shut-off valves (eg solenoid valves) are used, this results in an inefficiently short service life.

The other problem is that of industrial Large consumers on a case-by-case basis (especially on non-working Days) of extremely low consumption values caused.

In the embodiment cited as an example in HU-PS 1 95 346, when using n = 8 branches, the 1 / (2 ⁿ -1) times the value (1/255 part ∼0.4%) of the total consumption (peak consumption ) still be such a significant amount, at which the regulation of the pressure and the exact consumption measurement cannot be avoided. In such cases, the number of line branches used must be increased to such an extent that the device becomes extremely expensive in order to control and measure precisely.

The invention is essentially a device which represents an improved embodiment of the device according to HU-PS 1 95 346 and which, on the one hand, solves the problem of the pipe shut-off fittings which operate reliably even with extremely high switching numbers, as well as in the case of the area 2 ⁰ -2 ¹ falling gas quantities the task of precise pressure control and measurement, in the latter case without having to increase the number of branches irrationally.

The invention is based on the knowledge that the Working accuracy of the known and in a wide Circuits used pressure regulators and measuring devices in the case of a slowly changing and low gas consumption in general is satisfactory and that 0.0-3.0% of the  Peak consumption of bulk consumers Consumption values the other associated with the consumption control engineering tasks (Consumption limitation, tariff switching) generally not queue. With the remote displays for the purposes of The management's energy management tasks are the display (Registration) sufficient for the fact that consumption has not reached this lower threshold.

To measure the amount of gas consumed is a simple one Summation of the by an analog working known per se Gas meter and by a measuring device of the device according to the HU-PS 1 95 346 displayed values are sufficient.

Added to this was the realization that the functions of those in the different chokes and chokes Pipe shut-off valves by a (in the facility expediently arranged interchangeably) - for corresponding Flow-dimensioned - can be united by the nozzle one attached to the piston rod of a working cylinder Locking element is reliably completed in the rest position and by actuation (a shift of two to three Millimeter) of the working cylinder can be opened.

The simplest embodiment of the invention The facility is accordingly the one in which the facility is in accordance with the HU-PS 1 95 346 is modified so that in one at least partition arranged in two compartments a certain functional connection Permeability nozzles are arranged, wherein the opening of the nozzles for each nozzle Working cylinder and one attached to its piston rod Shut-off element are provided, which shut-off elements are the Lock the nozzles in the rest position of the working cylinder.

At the same time, the smallest permeability branch of the device, with the nozzle in line switched or connected in parallel to this branch, one analog  working gas pressure regulator and a flowing gas quantity integrated gas meter installed.

The invention will be explained in more detail with reference to Embodiments, with reference to the drawing explained. The drawing shows:

Fig. 1, the most characteristic schematic illustration of the apparatus of the HU-PS No. 1 95 346,

Fig. 2, the apparatus of the HU-PS No. 1 95 346 parallel-connected with a first to their branch analog pressure regulating valve,

Fig. 3 shows the device according to Fig. 1 and 2, respectively, having first switched on in their branch analogue pressure gauge and counter, shown schematically,

Fig. 4 shows an embodiment according to the invention, provided with the nozzle and the working cylinder in a cross-sectional view sketch with a single acting cylinder with spring return,

Fig. 5 shows a detail of the embodiment shown in Fig. 4, with a double-acting cylinder, schematically, and

Fig. 6 shows a variant of the embodiment of FIG. 4 in a schematic representation, in which compressed air is used to actuate the working cylinder, whereas the energy of the gas with the secondary pressure is used for closing.

Fig. 1 shows - apart from the reference numerals - with the Fig. 1 of the HU-PS 1 95 346 corresponding to a device in which between the pipe 1 connected to the gas line network with a higher, so-called supply pressure and the container 10 (and above this with the pipe 11 ) with a lower, so-called consumption pressure, for example four connecting branches are provided, of which (seen from the left in the figure ) in the first branch a pipe shut-off valve 2 and a throttle 6 , in the second a pipe shut-off valve 3 and a throttle 7 , in the third a pipe shut-off valve 4 and a throttle 8 and in the fourth a pipe shut-off valve 5 and a throttle 9 are arranged. In this embodiment variant, 2 ⁴ = 16 different positions of the pipe shut-off valves 2 to 5 are possible, and after this one position corresponds to the closed state, the "zero" position, the pressure and amount of the gas flowing through can be adjusted in 1 / (2 ⁿ -1 ) = 1/15 ∼6.7% "steps" or steps regulated and measured according to the time integral of the position of the pipe shut-off valves 2 to 5 .

In the device according to FIG. 2, a connecting pipeline is provided between the pipe 1 and the container 10 (so to speak as a "zero branch"), in which a pressure reducer 13 and a flow meter 14 are installed. The flow meter 14 is connected via a signal line 14 'to the control unit 12 .

In the embodiment according to FIG. 3, the pressure reducer 13 and the flow meter 14 are arranged in the first branch and are connected in series with the pipe shut-off valve 2 and the throttle 6 .

In the embodiment according to the invention according to FIG. 4, the tube 1 and the container 10, with their corresponding outer geometrical dimensions, form a housing which is separated by a partition 15 . In the partition wall 15 nozzles are arranged 16 and 17 which are secured, for example by means of a screw thread in the partition 15 °. In the high-pressure chamber fulfilling the function of the tube 1 , working cylinders 18 and 19 are attached to a supporting wall 22 , arranged coaxially with the nozzles 16 and 17 , and are each provided with a shut-off element 21 on their piston rods 20 . The working cylinders 18 and 19 are designed, for example, in FIG. 4 as single-acting, with spring return. The working cylinders 18 and 19 close the nozzles 16 and 17 in their rest position, the lines 23 and 24 being used for their actuation.

In the embodiment according to FIG. 5, the working cylinder 19 is double-acting and an additional line 25 is used to control the locking.

In the embodiment according to FIG. 6, the housing formed is divided into three rooms by the partition walls 15 and 26 . The pipe 27 connected to the line network having the higher pressure breaks gas-tight through the partition wall 26 , so that the high-pressure space which fulfills the function of the pipe 1 forms the middle space. The first space 28 , calculated from the left in the figure, is connected via a line 29 to the container 10 under secondary pressure, so that the lower secondary pressure is established in this space 28 . An opening is provided in the rear wall of the working cylinder 19 installed gas-tight in the partition wall 26 , so that the space behind the piston is also under the secondary pressure. Under the action of the pressure pulse arriving via line 24 , working cylinder 19 opens the nozzle, and when line 24 is blown off (at atmospheric pressure), secondary pressure ensures that working cylinder 19 closes and holds it in the closed state.

When operating the device according to HU-PS 1 95 346 and according to FIG. 1, a pressure sensor, not shown in the figure, measures the secondary pressure prevailing in the container 10 .

When this pressure drops, the control unit 12 opens (and of course by means of an electrical signal) the pipe shut-off valves 2-5 in the order corresponding to their own program in such a way that in each case the flow cross section is opened which is sufficient for a given one Consumption the pressure in the container 10 remains the same as the set - prescribed - consumption pressure. In the event of an interruption in consumption, an error signal or a control signal acting in this sense, the control unit 12 closes all pipe shut-off valves 2-5 and the device comes into the closed, ie "zero" state. The position of the pipe shut-off valves is in a known functional connection with the gas volume flowing through and therefore the control unit 12 can display the current consumption by displaying a "number" corresponding to the position of the pipe shut-off valves (or transmit it by forwarding the signal representing this number), whereby the total amount of gas consumed is displayed by summing the time integral of this value and displaying it, and the function of a consumption meter can thereby be fulfilled.

Under the influence of an external control signal, the work of certain pipe shut-off valves (the ones with the greatest permeability) can be prevented (peak limitation), while in the case of several meters and remote-controlled tariff switching, the device also works as a multi-tariff counter. The sudden change in the differential of a signal proportional to the gas quantity currently flowing through can - via corresponding construction components known per se - trigger a lock, the device functioning as a quick-release fastener. However, if the consumption reaches such extremely low values that they fall below the 1 / (2 ⁿ -1) times the value of the peak consumption, the mode of operation of the device becomes unsafe, the pipe shut-off valve 2 belonging to the throttle 6 with the lowest permeability will temporarily open and temporarily close and meanwhile the secondary pressure in the container 10 fluctuates in an undesirable manner.

In the embodiment of FIG. 2 at such a low consumption of the Rohrabsperrarmatur 2 closes and the gas flow is effected by the (low power having) pressure reducer. 13 The amount of gas flowing through is measured by the flow meter 14 , from the counter of which a digital electrical signal reaches the control unit 12 via the signal line 14 '- where the value measured in this way is then added to the consumption value measured digitally. In this embodiment, the device can only perform a locking function if a separately controllable pipe shut-off fitting is also provided in this branch - such a pipe shut-off fitting is not shown in FIG. 2, however.

The blocking function of the device remains unaffected in the case of the embodiment according to FIG. 3. Here, the analogue pressure reducer 13 of low power and the flow meter 14 in the branch of the pipe shut-off valve 2 and the throttle 6 are arranged in series with these components. The mode of operation of this embodiment corresponds in all respects in all cases in which the consumption exceeds 1 / (2 ⁿ -1) times the peak value to the mode of operation of the device according to HU-PS 1 95 346, as is shown in FIG Fig. 1 has been described. However, if the consumption falls below this limit value, the secondary pressure in the container 10 cannot rise because the pressure reducer 13 is activated and ensures the prescribed value of the secondary pressure. In this case, the first branch must be switched off from the consumption measurement, since the flow meter 14 measures the amount of gas flowing through this branch exactly at all times and the two measurements (the analog measurement result of the flow meter 14 and the result of the digital measurement carried out from the second branch). jointly deliver the decisive measurement result.

A union of Rohrabsperrarmaturen 2-5 and the throttles. 6 - 9 aspiring embodiment of Figure 4 includes in a housing any number of conveniently mounted in the partition wall 15 by means of a screw thread nozzle (nozzle 16 and 17), in front of which on the high pressure side One working cylinder (in the figure, working cylinders 18 and 19 ) are arranged coaxially (axisymmetrically). To the extent that these, as in FIG. 4, are single-acting working cylinders with spring return, the spring ensures that the shut-off elements 21 fastened to the piston rod 20 of the working cylinders 18 , 19 close the nozzles 16 and 17 until line 23 or 24 a signal arrives. The signal in this case is a unit pressure jump , which moves the piston of the working cylinder against the spring, to the left in the figure , and opens the flow cross section of the corresponding nozzle. When the signal disappears, the spring closes and ensures that the closed state is maintained.

The given configuration of the control unit 12 can justify the special embodiment according to FIG. 5, in which case the opening is triggered by the signal arriving via the line 24 , while the closing is triggered by the signal arriving via the line 25 . By maintaining the constant pressure level prevailing in line 25 , the closed state must be ensured during operation.

In the embodiment according to FIG. 6 it is achieved by means of the line 29 that the secondary pressure (eg 0.03 bar) prevails in the space 28 . This is sufficient to maintain the closed state of the working cylinder 19 . The opening signal comes via line 24 . After this signal has disappeared, the pressure in line 24 must be blown off to a value below the secondary pressure (expediently to atmospheric pressure), the secondary pressure from chamber 28 closing the working cylinder 19 and ensuring that the closed state is maintained.

The embodiments according to FIGS. 2 and 3 are used in the sense of the above in the manufacture of devices with a high gas permeability. In this case, the dimensions of the device enable the device according to FIG. 2 to be arranged in such a way that the pressure reducer 13 and the flow meter 14 , connected to a bore provided in the partition 15 and containing no nozzle, in a space corresponding to the container 10 are housed, but they can also be attached using a pipeline outside the housing shown in Fig. 4 attached to this, etc.

Similarly, the device according to Fig. 3 are formed, but with the difference that in this case the pressure regulator 13 and the flowmeter 14 to which the smallest throughput capacity having nozzle of the device are to be connected.

According to HU-PS 1 95 346, the control unit can be any control unit known per se, which provides the explained task and as far as the pipe shut-off valves 2-5 solenoid valves or other electrically operated components, the control unit can also be a completely electrical control unit . Of course, an electropneumatic or pneumatic control unit could also be used in the device designed according to the HU-PS; in this case the pipe shut-off valves 2-5 could also be membrane-equipped pneumatic amplifier components.

In the case of the invention, the control unit must be a pneumatic or electropneumatic control unit, since a pneumatic signal is always required to actuate the working cylinders 18 and 19 : in the case of an electropneumatic control unit, such an electrically controlled pipe shut-off valve is required, as is the case with the pipe shut-off valve 2-5 of FIG. 1 would represent in the case of the use of an electrical control unit. The problem existing according to the objective of the invention is therefore apparently only shifted. However, this is not really the case. While the pipe shut-off valves 2-5 in the device according to FIG. 1 have to let an ever increasing gas flow pass through and so their dimensions are larger and constantly increasing from the outset, only the control signal that is the same size and with each working cylinder has to be let through in the electropneumatic control unit is orders of magnitude smaller than the actual gas flow, so that the change means a cheaper solution.

To operate the pneumatic devices, as long as the embodiment according to FIG. 6 is not used (under primary pressure), the gas itself can be used as the working medium, which gas is led into the container 10 after the work has been carried out. The gas used for control may have to be filtered and dewatered in the interest of safe operation, in some cases even its pressure must be reduced to the pressure required for control with the aid of an analog pressure reducer. In most cases, this is not an obstacle because, for example, in a device connected to a line network with a pressure of 6 bar, a gas with a pressure of 1 bar is used as the working medium for control, which after the work is carried out in a container 10 with a Consumption pressure of 0.03 bar is passed. When using an embodiment according to FIG. 6, the working medium should expediently be compressed air, because the medium here has to be blown off to a pressure below the secondary pressure after the work has been carried out, but such a pressure is not present in the gas system. Here it is most appropriate to reduce the compressed air to atmospheric pressure, ie to blow it off into the surrounding atmosphere, which is why this embodiment is best used where a compressed air network is available.

With the help of one of the above explanations constructed and actuated facility can with simpler Averaging under further limits with increasing accuracy and much more durable components with the Gas consumption related control and regulation Tasks to be accomplished.

Claims (6)

1. Device for controlling and regulating the gas consumption, which is a pipe ( 1 ) connected to the gas source, a pipe ( 11 ) connected to the consumer to be supplied, and a container ( 10 ) connected to this and between the pipe ( 1 ) with the Higher pressure and the pipe ( 11 ) with the lower pressure and / or the container ( 10 ) according to a certain functional context variable permeability and with a control unit ( 12 ) controllable according to a predetermined program pipe branches ( 2-5 ) provided pipe branches of a number n contains, characterized in that the pipe shut-off fittings ( 2-5 ) as nozzles ( 16 , 17 ) of certain permeability , which are fixed in bores of a partition ( 15 ), expediently by means of screw threads, opposite them on the inlet side to the nozzles ( 16 , 17 ) Coaxial (axially symmetrical) arranged in a supporting wall ( 22 ) attached working cylinders ( 18 and 19 ) and to the Kol benstangen ( 20 ) of the working cylinder fixed shut-off elements ( 21 ) are formed. 2. Device according to claim 1, characterized in that the working cylinders ( 18 , 19 ) are single-acting, with spring return. 3. Device according to claim 1, characterized in that the Working cylinders are double-acting. 4. Device according to claim 1, characterized in that the working cylinder in the opening direction via a line ( 24 ) to the control unit ( 12 ), and in the blocking direction to a same pressure as the secondary pressure vessel ( 10 ) having space ( 28 ) connected are. 5. Device according to one of claims 1 to 4, characterized in that between the bore of the partition ( 15 ) and the container ( 10 ), a pressure reducer ( 13 ) and a flow meter ( 14 ) are connected in series, the signal of Flow meter ( 14 ) via a signal line ( 14 ') is connected to the control unit ( 12 ). 6. Device according to one of claims 1 to 4, characterized in that in the container ( 10 ) leading tube with the smallest permeability nozzle connected in series, a pressure reducer ( 13 ) and a flow meter ( 14 ) are switched on, wherein the output signal of the flow meter ( 14 ) via the signal line ( 14 ') is connected to the control unit ( 12 ).