DE2215702A1 - FLUIDUM MEASURING DEVICE AND METHOD FOR DETERMINING A USAGE FEE - Google Patents

Description

Fluidum measuring device and method for determining a consumption rate The invention relates to methods and devices with a measuring device for measuring a fluid flow around it and in particular for displaying the total load a Fluidumverteilersnlage in the form of a display of the actual amount of during a predetermined period of time a predetermined system section flowing through fluid.

In particular, the invention relates to methods and apparatus to relate a characteristic value of the fluid flow in a specific fluid diversion, which is a function of the flow rate, on the fluid pressure in the system, in order to record an output signal that shows the load on the installation and the amount of fluid flowing past the measuring device in this line reproduces. In addition, the invention aims at the shaft function of a remote display device, with the help of which the fluid consumer receives information about the relative costs of the fluid can be offered if he has the fluid at the relevant time instead of another time wishes to use. Unless otherwise stated, the term fluid used refers to either water or gas, i.e. natural gas.

The conventional fluid distribution networks are of such capacity designed so that they are able to meet their respective peak loads at any time. This means that such a network eo must be designed that the consumers Fluidum is available at all times and even when there is maximum demand. How yourself shows, the peak demand loads of the fluid networks fluctuate from day to day to day within wide limits, are seasonal and occur within such Peak demand periods periodically to almost predictable and random Points in time. For example, summer is a peak demand season for one Water distribution network, as the water consumption is very high and above the annual average is what is in part on sprinkling lawns, filling swimming pools, using Fire hydrants etc. is due. It can also be demonstrated that the average summer peak demand well below the peak demand of one certain day, as water consumption usually occurs during certain hours of the day is excessively high and then e.g. in some areas peak values between 5 p.m. and 8 p.m. can be achieved if the water users living in suburbs are usually sprinkle their lawn. It was found that the peak demand in the summer is approximately 3 to 17 times the average demand for the water network reached during the winter.

The same applies to the delivery of natural gas to consumers Gas network, along with the production and pipeline systems, built with such a capacity, that the peak loads of the network can be met at any time.

In certain distribution networks, for example, gas is stored in large tanks in order to additionally supply the network lines during periods of peak consumption. Depending on the geographical location of the gas distribution network, production and / or pipeline and / or gas storage systems can be used exclusively or the latter can be used to supplement the production and / or pipeline systems in the event of peak demand. It can be shown that natural gas demand fluctuates considerably over the course of a day and also shows wide seasonal fluctuations, with the maximum consumption usually occurring in December or January. Therefore, in many such systems, where locally produced gas is sold, the natural gas production plant or where natural gas is supplied via pipelines to local distribution, the pipeline plant is usually operated continuously on a 24-hour basis, with the gas in Peak demand periods are deducted from large tanks and delivered to them outside of these periods. The distribution network naturally has sufficient capacity to meet the peak hourly consumption, and the entirety of the gas generation or pipeline and storage system is sufficient to satisfy both peak consumption and daily maximum consumption. Because of the gas storage possibility, the required production or pipeline capacity varies depending on the total amount of gas consumed per day or week, while the storage capacity inevitably depends on the specific requirements of the respective system. In practice, the natural gas consumption is not constant, but rather shows strong seasonal fluctuations, especially when the gas is used for space heating. In these cases, the distribution network must be powerful enough to deliver the seasonal maximum consumption and to keep the pressure within a target range. The main gas lines must be dimensioned sufficiently large so that the gas can be transferred without an unacceptable pressure drop.

In addition, fluctuations in demand occur daily and with natural gas even on an hourly basis. For example, there is a gas requirement for hot water generation and cooking purposes usually at specific, predictable times of the day.

Because of this common fluid consumption scheme with water as well Gas networks must have the conventional supply networks - as it actually does Case is - be designed so that they are sufficient during these peak demand periods Deliver fluid to meet consumer needs.

In other words, the conventional supply networks have under Conditions of average demand, large overcapacity.

Usually has a consumer connected to the fluid system a fluid meter, i.e. its own gas and water meter, which it actually does Measure the amount of fluid used. For example, is with a suburban homeowner or another consumer, usually a flow meter or flow meter installed, with the help of which the total fluid consumption within a given Period of time can be totaled. To invoice one to the water network connected consumers, the water suppliers usually use a price system with falling basic fee. In the case of gas systems, the charges are often after a Quantity tariff with either a constant basic fee per cubic meter or according to a basic fee system calculated with decreasing prices depending on the quantity. For the latter, the costs are the Consumption quantity inversely proportional in steps. Both with water and in the case of gas supply, the marginal costs are therefore higher with low consumption than with high consumption. As a result, the small consumers pay for this graduated price system In fact and inevitably part of the fluid costs of the bulk consumers. Using of throughput or flow meters, which - as is currently customary - only Show the amount consumed, and when using one, only show the amount consumed based on the fee system, the bulk consumer will not use his proportional Part of the system costs, which are inevitably proportional to the extent in which the network must be available for its supply.

According to the invention, on the other hand, a novel and unique flow measuring device is used, the output signal of which is a function of both the total load on the fluid network and the total volume of fluid that is drawn from a particular network section or from a specific consumer. As a result, a consumer can be charged not only in accordance with his actual fluid consumption, but also in accordance with the extent to which he uses the network at any given point in time for his own supply. The pressure-load measuring device according to the invention is based on the network pressure as a fluid consumption indicator and relates it to the actual consumption quantity of this consumer in order to register required units of measure which are directly proportional to the fluid quantity consumed and inversely proportional to the network pressure. (With a gas supply network, this type of calculation is possible if only production and / or pipeline systems are used. As will be explained in more detail below, the pressure display and volume are related to where gas tanks to support the gas supply from these systems are in The supply network can be used to register demand units that are directly proportional to both the gas volume and the network pressure.) In a tariff system based on quantity, the invention provides a method and a device by means of which the costs for the consumer are directly related to the network load can be set at the time of consumption. If, for example, a consumer uses the fluid network at a time of high network load, the measuring device according to the invention registers in units of quantity a value that is simultaneously directly proportional to the actual consumption amount and the network load, this value being higher than that which regstrirt when the same amount of fluid is consumed during an intermediate or a low load period will. The larger quantity units registered at peak or high demand times thus cause an increase in the consumer end costs (if costs and consumption amount are directly related) compared to those for the same amount of fluid during a period of low pollution. The costs to be imposed on the consumer are thus directly related to the network load and consequently he directly bears the additional costs for his needs during a period of peak or high load on the network, which leads to a fairer distribution of costs.

By changing circumstances as consumers change are informed in the tariff and accordingly their final costs and take them into account can, this information is according to the invention the consumer in the moment issued, in which he decides on the use or non-use of the fluid, whereby a significant increase in the load inefficiency of the supply network and accordingly a lower third party fee rate and a more even distribution of prices become possible according to the cost. The inventive measuring device has a Pernanzeiggerät for the consumer, which informs him about the network load informs other consumers. Thus, the consumer receives before anything Fluidumverbrauoh, at a time when he is over consumption or Non-consumption has to decide, an indication of its final cost at Fluiduverbrallch at this point in time, i.e. he will be informed of the relative costs then incurred in the Compared to the costs of using Fluidum> consumption at other times and arise at other stress periods. Through this consumer education for Taking into account changes in final costs has the effect that consumption peaks are flattened and consumption valleys filled and thus higher and lower utilization rates Average fee rates are achieved. Translated into practice this means that as a result of the dampening of the peak load periods, the time horizon for existing ones Fluid supply systems can be expanded, which among other advantages too postponing the periodic search for new natural gas or water sources leads. In addition, future systems will not need specials in accordance with the usual peak load periods to be designed only for significantly lower capacity and still be able to use the perform the same task.

The object of the invention is therefore primarily the shaft fungus a novel load measuring device for fluid systems and in particular one Measuring device for measuring pressure and load parameters of the fluid flow in a fluid distribution network.

This device is intended to control both the flow rate and the fluid pressure measure in a fluid bypass and the two measured values to each other to register units in relation to which of the flow rate in the fluid bypass direct and the Network pressure are inversely proportional.

In addition, one connected to the fluid network should be possible A remote display of the network load can be supplied to consumers.

Another object of the invention is to provide an improved one Load measuring device for measuring the throughput and load parameters of the water flow in a water distribution network, either as a uniform, one-piece Unit or as an add-on to a conventional, volume-measuring water meter can be formed by modifying the same.

A related object of the invention is to provide a method and a device for determining consumer fees in a fluid distribution network, which shows the total network load and the amount of fluid consumed reflect and thereby flatten load peaks.

The following are preferred embodiments of the invention explained in more detail by drawings. They show: FIG. 1 a vertical section through a measuring device which can be used in particular as a water meter and has the features of the invention, FIG. 2 is a partial section through the gear train of a conventional positive displacement water meter, 3 shows a vertical partial section through a, on an enlarged scale control gear used in the measuring device according to FIG. 1, FIG. 4 shows a section approximately along the line 4-4 in Fig. 3, Fig. 5 is an enlarged scale, vertical partial section through a modified embodiment of one in the measuring device according to Fig. 1 usable control gear, 6 shows a section approximately along the line 6-6 in Fig. 5, Fig. 7 for the purpose of a simplified illustration Partly broken away and shown in section partial side view of a lost motion linkage for the measuring device according to FIG. 1, FIG. 8 is a plan view of the linkage according to FIG Fig. 7, Fig. 9 a view similar to Fig. 7 of a modified linkage, Fig. 10 is a pictorial view of a modified and in particular a gas meter usable embodiment of the measuring device according to the invention, in the purpose simplified representation broken away certain parts and shown in section 11 is a reduced-scale view of the device according to FIG Fig. 10, a gas line is installed and a remote display device for the load of the gas distribution network, FIG. 12 shows an enlarged scale Section through part of the device according to FIG. 10, FIG. 13 shows an enlarged Section maintained to scale approximately along the line 13-13 in FIG. 12, FIG. 14 a FIG. 13 similar view, which illustrates another position of the device according to FIG. 13, and FIG. 15 shows a view similar to FIG. 12 of a further modified embodiment.

The principles of the invention apply to both water and gas distribution networks applicable. With regard to the structural differences between water and gas meters However, the invention is initially based on a water and danaoh on the basis of a Gas meter described.

The pressure-load measuring device according to the invention shown in FIG. 1 10 uses parts of a conventional positive displacement meter 12 for measurement the flow rate through a fluid or water line F.L., whereby of course throughput meters of other types can also be used. For example, the Water flow rate through the line F.L. also by means of a conventional thermoset meter be measured, the pressure difference generated by an inserted line constriction used to determine the flow velocity and about it and the constriction area can calculate the throughput rate as known factors.

The swash plate water meter shown has a housing 14 with inlet 16, outlet 18 and therebetween, substantially cylindrical Measuring chamber 19 in which a wobble plate 20 is housed. The latter points preferably a radial partition 22 and a central ball 24, which in turn is pivotally mounted between two ball sockets 26 and 28, which in the intermediate wall 30 or

lower wall 32 of the housing 14 are formed. On this ball 24 sits eccentrically a driving pin 34, which sioh on an inverted frustoconical Bevel gear 36 is applied, which on a shaft 38 running in the direction of the counter is mounted. When water flows through the measuring chamber 19, the wobble plate nutates 20 as can be seen and drives via the friction clutch from pin 34 and bevel gear 36 the shaft 38 on.

1 and 2 drives the shaft 38, the output power of which Water flow rate through the line F.L.

is proportional, a countershaft 40 in the form of a conventional reduction gear on, through which its speed on a compatible with the gear of a counter 44 Speed is reduced. 2 is in such a conventional positive displacement counter the drive shaft 42 of the countershaft via gears 46, 48 and a shaft 50 with connected to the gear train 52 (Fig. 1) of the counter 44, the two display of the water throughput by the management F.L. e.g., as shown, several indicated at 54 in standardized Has units of measure divided into scales. Instead, of course, if desired, other visual displays, for example a combination of numeric Counters and a dial coating pointer may be provided. The conventional one Counter 44 is mounted on the housing head in a suitable manner, specifically removable and provided with a hinged cover 56 to protect a sight glass 58 and gear train.

According to the invention there is also a measuring device 60 for the in line F.L. prevailing water pressure provided.

As mentioned at the beginning, the latter provides an indication of the total load of the entire water distribution network than it would be with a high network load is low and comparatively higher when the network load is low. To this end the pressure measuring device 60 has a housing 62, the chamber 64 of which by a Membrane 66 is divided and on the. one side via a tap with the Fluid diversion F.L. communicates. The membrane 66 is on both sides Central part covered with washers 64 by means of a nut 72 at one end of a shaft 70 attached, the other end by provided in the housings 62 and i2 Bores extends through and an input signal to a yet to be described in more detail Variable speed gearbox 76 (Fig. 1) supplies. A spring 78 holds the diaphragm 66 and thus the shaft 70 in a predetermined axial position. One on the opposite side of the case provided adjustment tube 80 enables the membrane 66 to be inserted into it desired location.

The one shown in Fig. 3, between the output shaft 32 and counter 44 engaged control gear 76 is used to relate the network load, namely network pressure for measuring the quantity of durometer for the purpose of delivering an output signal in load quantity units, which is the flow rate through the consumer water pipe are direct and inversely proportional to the total network load. To this end If the control gear 76 has a disk seated on the countershaft output shaft 42 82 preferably made of plastic and a second disk 84 on a shaft 86, the axis of which is laterally offset with respect to that of the shaft 42, is rotatably mounted and parallel to and at a distance from the shaft 70 on its facing away from the disk 82 Side is arranged. A ball 88 is freely rotatable in a socket 89 in the shaft 70 mounted, which the disc 82 approximately radially center and the disc 84 at diametrically opposite point touched radially end. Obviously, one Rotation of disk 82 rotates disk 84 in the same direction via ball 88. There but the direction of rotation of the shaft 42 that of the input shafts of conventional flow meters is opposite, the direction of rotation of the disk 84 is not in the same direction the input shaft 90 of the counter, but via the bevel gear attached to the former 92, the bevel pinion 94 standing at right angles to it and the bevel gear 96 opposite transfer.

The variable speed gearbox 76 ensures a constant reference to measured throughput and pressure or load on the water system. In Fig. 3 is the shaft 70 on shown at the extreme end of its shift to the right. This position corresponds to the detection of the peak pressure in line F.L. and shows thus low network load.

With increasing network load and correspondingly decreasing line pressure The pressure sensitive diaphragm 66 displaces under the force of the spring 78 to the left according to FIG. 1 and takes the shaft 70 and the ball 88 resting on it also to the left according to FIG. 3 with, which thereby their radial distance on the Disk 82 enlarged and that on disk 84 reduced, which can be seen to an increase in the speed of the disk 84 and also the output shaft 90 leads. Because of their coupling to the gear train 52 of the counter 44, the The incremental speed of the scale displays of the counter 44 is proportional to the decrease of the water network pressure increases and thus reflects the higher network load. The counter 44 therefore registers the quantity / debit units which have been used The amount of water is directly proportional and inversely proportional to the network load. Consequently will a water consumer who consumes water during periods of peak demand (when calculating costs according to water consumption amount) have to pay more than if he were the same Amount of water consumed during periods of low pollution.

A special feature of the invention is that the respective Network load on the water consumer on a remote display device before consumption begins is announced, which is on a tap through which the main part of the water consumed by the consumer flows.

According to FIGS. 1 and 7, the fee display device 100 has a 12 representation sfront, which is calibrated in such a way that it provides the consumer with an indication of his charges for water consumption during certain time periods. For example this display device can be used in several variable cost units per unit of measure used water to be calibrated, i.e. a performance of more graded Show prices per unit of water which is effectively a proportional display the network load shown. Of course, the display device can also be different be calibrated and, for example, have a drum pointer that is on various load indicators, how high, medium or low shows. To enable this remote load display, through which the potential water consumer is informed about the network load and thus an indication of its comparable water consumption even before any water consumption Receives water fees, are in the control gear 76 of the measuring device 10 several reed switches 104a to 104c are provided, the line cables 106 of which extend through a housing opening and can be connected to the remote display device 100, the corresponding electrical Has circuits and a Stromquellenansohluß, so that behind the load indicator elements 102 provided light sources 108 selectively for lighting according to the network load can be brought. According to FIG. 3, the shaft 70 carries several axially to one another offset magnets 110 (ac), one of which in the extreme right position shown of the shaft 70 of the magnet 110a aligned with the reed switch 104a is that the latter closes, completes an electrical circuit and thereby the light source 108 lights up, which corresponds to the low network load, i.e., display element 102 indicating high network pressure. This will indicated a low water charge to the potential consumer. With ainking The shaft 70 is displaced in accordance with the network pressure corresponding to a higher network load 3 axially to the left, so that now magnet 110b is in the operative position against the reed switch 104b arrives, closes this and that light source 108 in the remote display device lets aufletchten that the consumer a certain mean network load and a comparatively average water price indicates. As the shaft 70 is shifted to the left, the magnet is first reached 110a in such a position that the reed switch 104a opens again, and then the magnet 110c in the operative position with respect to the reed switch 104c, whereby he closes it and switches on the lighting of the associated display element 102, that shows the water consumer an even higher water price if he goes to this Time should run water. At the same time, of course, the magnet moves 110a to a position in which the reed switch 104a opens.

The debit or basic price display device could either be also be provided on the main counter 12 itself; does not need a remote display device at all to be.

While in the embodiment according to FIG. 3, any increase in displacement of the shaft 70 a significant change in the rate-load output of the counter 44 causes, this is the same in the case of the control gear shown in FIG. 5 Shaft displacement gradually smaller.

For this purpose, the axis of rotation of the disk 84a is only slightly opposite that of the shaft 42 is offset with the disk 82, and both disks the center distance of the point of contact with the ball 88, i.e. the effective radius, only somewhat unequal. Thus - based on the same amount of displacement of the shaft - the speed change of the disk 84a compared to the speed of the disk 82 comparatively smaller than that in the Pig embodiment. 3.

For the purpose of adapting to conventional counters, the disk 84a is furthermore Via a gear 112 seated on its shaft 114 and one from the output shaft 90 carried gear 116 with the latter and the gear train connected to it of the counter 44 coupled.

To operate the remote display device 100 from the control gear according to FIG. 5 microswitches can also be used.

For this purpose, switches are axially offset along the shaft 70 118 arranged, and the shaft itself carries switch actuators 120, which are able to come into contact with the switching arms of the switch 118.

The shaft 70 is the same as in the embodiment according to FIG. 3 shown in its extreme right position, in which the switch 118a is closed and the associated light source in the remote display device 100 lights up. At a 5 to the left-directed axial displacement of the shaft 70 as a result of increasing Network load the Sohalter 118b and 118c are operated one after the other, whereby the associated light sources light up and the corresponding display elements 102 lighten up.

According to FIGS. 7 and 8, a lost motion connection 120 can be incorporated into the variable speed transmission 76 are inserted to avoid excessive wear of those friction-coupled with the ball 88 To prevent disc surfaces. The pressure gauge output shaft is used for this purpose 70 at the end designed as a link 122 into which a link 124 is inserted, the seated at the end of a shaft 70a aligned with the shaft 70. Between the two ends Two springs 126 extend from the handlebar 122 and the transverse web of the handlebar 124 and 128. In addition, there are stops 130 and 132 at the two ends of the handlebar 122 terg as well as 124 stops on the opposite surfaces of the crosspiece of the handlebar 134 and 136 arranged. The shaft 70a carries the function described earlier Friction coupling ball 88 between the two disks 82 and 84.

So as long as there is no flow in the fluid bypass F.L.

prevails, the ball 88 remains independent of fluctuations in the pressure measurements, i.e., the axial displacement of the shaft 70, in the same position. As soon as Flow and corresponding rotation of the swash plate 20 begin, the ball 88 by moving them almost instantly into the corresponding radial position versohoben as if no lost motion connection between it and shaft 70 switched on were.

The embodiment of FIG. 9 has a similar lost motion connection 120 between the pressure knife shaft 70 and the friction coupling ball 88 for a throughput rate proportional to the network load Counter 44, in which, however, instead of a continuous flow rate and network load The reflective display offers a step-by-step display of the amount of throughput and reflects different network load levels. For this purpose is the shaft 70a is provided with a series of axially spaced apart grooves 138 and protrudes with it this grooved end through an opening in the counter housing, into the a spring-loaded ball lock 140 is incorporated. As soon as the shaft 70 is axially is pushed into a position in which the stored in the Xotgang connection 120 Pederkraft overcomes the spring force of the ball lock 140, then it shifts axially in a predetermined locking position in which the ball 88 and depending on small Pressure or load fluctuations, each of which is absorbed by the lost motion connection are held in a predetermined position between the disks 82 and 84 will. Thus, the radial relative position between the ball and the washers is as in the previously described embodiments by the axial displacement of the shaft 70 determined, but the change in position is not, as before, continuous, but is done gradually.

As mentioned. the water system load is a function of the wnhe-i Relative pressure ~ Flute pressure in lhm '; 7 of / measured in any branch line can be and a function of 1) the relative increase in supply to the concerned Line, i.e. the back pressure; 2) the pipe length between the measuring point in the relevant pipe and the water supply source, depending on whether this is a storage tank or is a Puipstation; 3) the pipe diameter; 4) the one at the water flow frictional losses caused by the pipeline; 5) the durometer flow rate through the pipeline and other influencing factors is. Consequently are evidently in different lines depending on the factors mentioned Observe pressure differences. The factors are determinable, and the pressure reading in a given line is made to take account of these factors accordingly adjusted by, for example, the pressure gauge according to these factors Is set in such a way that the counter receives the corresponding input signal is fed in for the load measurement in a certain line. The pressure measurement thus directly reflects the load.

As a result of the invention, it has thus been shown to be possible on Counter 44 to provide a display in units of measure, e.g. cubic meters or the like, which, in addition to the amount of water consumed, also reflects the network load at the time of measurement. The fees to be imposed on the water consumer can therefore be viewed on the quantity display can be obtained from the meter as a price unit per unit of quantity of water consumed. In this consumer fee settlement method, the water cost is thus proportional to the amount consumed and the network load.

10 to 15 there is a pressure load measuring device according to the invention 210, which is particularly suitable for a gas distribution network. It includes Parts of a conventional gas meter 212, for example of the double diaphragm displacement type with two membranes 214 and attached to a flagpole 216. As shown, the membranes 214 are housed in a bucket-like housing, which is through a Central plate, not shown, is divided into two chambers. The heads of both Figgon dusts 216 are coupled via a linkage 218 which actuates two valves, one of which is indicated at 219.

Dae displaces gas flowing into the meter via a gas inlet 220 the membranes and operated via the plague sticks 216 and the linkage 218 the valves in such a way that a measured amount of gas flows off via the outlet 222. This type of gas meter is known in terms of its mode of operation and in particular Embodiment, for example, in Catalog No. M1001 from Pirma Rockwell Manufacturing Company described in more detail. For the present purpose, it is sufficient to state that the oscillating movement of the plague rods 216 by means of the linkage 218 in a Rotational movement of a central shaft 226 is converted, which is the case with conventional gas meters The underside carries a gear 228 which meshes with a gear 230 (FIG. 15). The latter normally drives a shaft 264, which in turn is coupled to a counter 232 is at which the gas flow rate through the gas meter is directly proportional Rotational movement of shaft 226 into a numeric display in, for example, cubic meter units this gas flow rate is converted.

11 shows the pressure-stress measuring device 210 as being in a Installed consumer line, the natural gas supplied via a distributor line 240 will. The latter usually has a shut-off valve 242 and a regulator 244 on which the line pressure to a pressure adapted to the consumer gas devices belittles. The gas flowing in via line 240 thus occurs at a reduced rate Pressure in the gas meter inlet 220 and is by actuating the diaphragms 214, of the linkage 218 and the valves i.B.

219) an outlet line connected to the consumer gas devices 246 assigned. The amount of gas flowing through the device is of course determined displayed on the counter 232, which usually has several scales, which record the gas flow rate, e.g. in cubic meters. Instead of the dial scales other visual displays can also be provided.

According to the invention, the quantity display on the counter 232 is predetermined for a Gas throughput through the meter according to the total load on the gas distribution network modified.

For this purpose, one of the regulator is on the distributor line 240 244 upstream point a Druokzapfstelle 250 is provided. As mentioned, offers the pressure prevailing in the distribution line 240 is an indication of the total network load and is yours under normal conditions, if only production and / or pipeline facilities Release gas to the network, inversely proportional To the network load, i.e.

the pressure in line 240 is related to the totalizer 232 To set, leads from the printer tap 250 a line 252 to one in the meter housing 211 arranged bellows 254, which is due to the practical pressure constancy in the surrounding the upper housing part of the network pressure increase and decrease accordingly in the direction of the arrow according to FIG. 12 expands or contracts axially.

While the usual gas meter usually has one between the output gear 230 (Fig. 15) and counter 232 has switched-on shaft and the latter consequently the gas flow rate registered directly by the gas meter is according to the invention according to FIGS. 10 and 12 between output gear 230 and counter input 262 switched on a control gear that is function-dependent with the network pressure and creates the possibility of relating the network load and quantity measurement and to deliver a result in debit quantity units to the counter 232, which the Gas flow rate in the consumer line 246 (Fig. 11) directly and the total network load is inversely proportional. For this purpose, the control gear 260 has two axially aligned shafts 264 and 266, each in mating at one end Meter areas 267 are stored.

The shaft 264 carries the output gear 230 as well as at the other end a gear 268 with elongated hub 270, in which the other end the shaft 266 is rotatably mounted. With the shaft 266 is a step gear 272 non-rotatably connected, which carries several axially offset gear rims 274, 276 and 278, which have decreasing diameters towards the end of the shaft remote from the counter.

The variable speed gearbox 260 also has a sleeve 280 which is in matching Bearing 279 is mounted in the meter housing 211 and a cylindrical bore 281 and a portion of enlarged Durohmesser having a with the output shaft gear 264 meshing gear 282 forms.

As a result, the sleeve 280 is disengaged from the rotating shaft 264 constantly driven. The sleeve 280 also has a slimmer portion 284 as a hub for several free-running gears 286, 288 and 290 each different Diameter, of which the smallest gear 284 always has the largest ring gear 274, the medium-sized gear 288 constantly with the middle ring gear 276 and the Largest gear 290 constantly with the smallest ring gear 278 of the one on shaft 266 Gear 272 meshes.

The end of the bellows 254 facing away from the conduit 252 is connected to a die Sleeve bore 281 penetrating shaft 292 coupled, which between its ends a has spherical thickening 294 which is within the bore and axially to it is arranged displaceably. As already mentioned, the sleeve 280 follows over the gears 268 and 282 of the rotational movement of the shaft 264, without any of the freely rotating on it seated gears 286, 288 and 290, unless there is a connection between it and one or more of the latter and thus to the counter drive shaft 266 exists. To produce this, each gear 286-290 has on its sleeve-side Inner surface of several three-sided, circumferentially offset openings 296 and the case 280 in the axial distribution corresponding to the gear wheel spacing, a series of circumferential lengthways each relocated and in the associated bore 302 radially displaceable pins 298, which at 13 outermost radial position with its conical head 300 in one of the triangular cutouts 296 of the associated gear 286, 288 or 290 engage and according to Fig.

14 innermost radial position with the inner ends of their sole 301 through the sleeve 280 protrude through into the bore 281.

Obviously, the respective axial position of the shaft thickening determines 294, which of the gears 286, 288 or 290 via a series of pins with the sleeve 280 is rotatably connected. For example, the thickening 294 is located according to FIG 12 in an axial position in which it is associated with the central gear 288 Pins 298 is in contact and their conical heads 300 outward and into the triangular cutouts 296 of this gear pushes into it. As a result, that takes Gear 288 together with the sleeve 280 in a rotation of the shaft 264 and drives Also the shaft 266 via the gear rim 276 of the mare gear wheel 272 meshing with it and thus ultimately the counter 232. As soon as the shaft 292 is due to elongation of the bellows or shortening according to a pressure change in line 240 from the one shown Position shifted axially, also engages the thickening 294 on another series of pins 298 at. For example, if the Batgen 254 senses an increase in line pressure, then the shaft 292 is displaced axially to the right as shown in FIG. 12 that its thickening 294 engages the pins associated with the gear 286. In line with Druokabnshme On the other hand, the bellows 254 sees itself together, shifting the shaft in the process 292 according to FIG. 12 axially to the left and brings its thickening with the gearwheel 290 associated pins 298 in engagement. With non-rotatable coupling of the sleeve 280 and gear 286 obviously drives the latter biggest Toothed ring 274 and thereby sets the shaft 266 at a predetermined speed in Rotation, the counter 232 a predetermined amount of gas flow through the counter displays in units of measure. When the middle gear 288 is connected to the sleeve 280 and drives the medium-sized ring gear 276, the shaft 266 runs at a higher speed predetermined speed, and the counter shows for the same meter throughput a larger number of units of measure. If eventually as a result of low line pressure detection in the bellows 254 the thickening 294 migrates to the left so far that the sleeve 280 with the gear 290 is coupled, then this drives the shaft 266 via the smallest Toothed ring 278 at an even higher speed, and the counter 232 reports for again the same meter throughput has an even larger number of units of measure.

The variable speed gearbox 260 thus creates a step-by-step process on the counter 232 Relation between the measured throughput rate and the pressure or load of the Gas network. That is to say, to repeat it, in the case of a left shift according to FIG of shaft 292 due to high network load, i.e. correspondingly low pressure in Line 240, the units registered on the counter 232 for the counter throughput comparatively higher than those for the same meter throughput from the counter with low network load, i.e. correspondingly high line pressure and The right shift of the wave 292 resulting therefrom can be registered. Vice versa are the registered units of measure for one and the same meter throughput comparatively smaller with low network load than with high network load.

To an intermediate position of the thickening 294 within the sleeve 280 To prevent between two series of pins 298, a ball lock 310 is provided. It consists of a number from axially longitudinally on shaft 292 distributed circumferential grooves 312 of larger diameter and a ball 314, which through a spring 316 is urged into engagement in such a groove. The locked positions the shaft 292 correspond to those in which the thickening 294 is each on one Set of pins in sleeve 280 is aligned.

To inform a gas consumer at a point away from the meter about the respective network load, so that at any time about gas consumption or -nioht consumption and the consumption costs applicable at the time can also take into account, a remote display device 320 (FIG. 11) is provided which at any convenient point, but preferably next to the gas taps for the The consumer's gas devices are arranged and, for example, in units of the actual costs per consumed Gas quantity unit can be divided according to the respective network load, the actual consumption charges for gas consumption at a specific point in time and to be displayed when there is a certain network load. This remote display device 320 can, for example 11 have three display fields, which the consumer the actual costs Specify the unit of measure for three different network loads. With high network load and correspondingly low network pressure, the remote display device can give the consumer a Unit fee of a certain amount and with low network load and accordingly display a cheaper unit charge due to high network pressure. For this purpose can this Display fields can be assigned to light sources 324a, 324b and 324c, which shine through behind Discs with printed, different unit costs arranged and over open contacts 325a, 325b and 325o with a power source 328 in the form of a battery are connected. At the end of shaft 292 is a strip 329 of conductive material Depending on their axial position, the network load, as mentioned, is provided indicates between a selected Contact pair engages. So Lights up when the network load is low and the pressure in line 240 is correspondingly high the light source 324a, informing the consumer that a possible Gas consumption at this time is associated with low costs. With high network load, i.e., low network pressure, on the other hand, the light source 324c will illuminate and show the consumer higher costs for any gas consumption that may then take place at.

As a result, the consumer can decide at any time whether he Consume gas or not, as it always has its relative cost of gas consumption compared to such at another time is informed.

Although the control gear in terms of three load or pressure positions As has been described, it can of course be any number of stages desired a-air iron. This means that depending on a larger number of load levels correspondingly more different throughput units registered at the counter 252 may be provided by simply increasing the number of gears of the transmission 260 will. Likewise, instead of the multi-step transmission shown and described a continuously variable transmission, for example the one previously described in connection with Fig. 3 described type be provided. In addition, the remote display device 320 could also have a larger number of display fields 324 to a larger number of load levels to display. In addition, display means other than that shown can also be used used instead of the actual price per unit of quantity of gas consumed can simply display the relative fees at any point in time.

In systems that use gas from gas containers during periods of peak load or tanks are supplied, increases when using such supply gas the pressure prevailing in the supply line 240 is above the normal network pressure exclusive gas supply from production or pipeline systems. In the illustrated embodiment of the invention, a mechanism is now provided that of the last-mentioned type of gas delivery at the counter 232 in the manner described supplies a quantity display that is directly proportional to the network load, but with the addition Supply of the distribution lines from gas boilers or tanks during periods of peak loads indicates a higher load because then, as I said, the Netzdruok over the middle Normal pressure rises, which is the case with simple gas charging from production plants or Pipelines prevail.

It is for this purpose that Meohanism measures according to Pig. 12 these over the pressure increase beyond normal gas network pressure and actuates the unit of measure counter 232 with higher counting speed, similar to this with low network pressure and high network load is seen if the network consists only of production or pipeline systems is fed.

For this purpose, the device according to FIG. 12 is through a fourth Gear 330 is added, as shown in FIG. 15. So much for this modification the same parts occur as in the device described earlier and are identical work, they have the same reference numbers. The gear wheel 330 also points to his the inner surface facing the sleeve 280 has several circumferentially offset triangular cutouts on, which cut out 296 of the gears 286, 288 and 290 correspond. aside from that is at a point corresponding to the greatest axial displacement of the shaft 292 Sleeve 280 provides another series of pins 298 which they selectively connect to a gear 332 able to couple. If now the bellows 254 as a result of the Zusatzbeschiokung of the network in the supply line 240 measures the prevailing high pressure, the shaft 292 is shifted to the right as shown in FIG. 15 that its thickening 294 engages the pins 298 associated with the gearwheel 330, pushing them outwards and with their conical heads 300, similar to the gear wheel 330, can be engaged, so that it is coupled to the sleeve 280.

Furthermore, the toothing 332 is one in diameter with the gear wheel 330 small end portion 331 of the step gear 272 in constant engagement. An abnormal one Gas pressure in the distribution network, which is based on additional charging of the network from gas boilers and therefore indicates a period of high network load, has the consequence that the counter 232 is driven at a comparatively higher speed, so that the increase in Rate of the units of measure registered on the register 232 for this higher network load is directly proportional, and thus for one and the same predetermined gas flow rate the meter quantity / at this high load and this high pressure a larger one Number of units of measure is displayed than it would be with normal network load, i.e. average high pressure, and exclusive net feed from production or Would register pipeline facilities.

In using this embodiment of the invention, the gears are arranged so that the thickening / preferably then the associated with the gear 286 Contacts pins and couples the latter to sleeve 280 when in line 240 there is a normal pressure range below peak pressures. If the Pressure of the gas supplied by the production or pipeline facilities decreases and thus indicates higher network load, shifts - as described earlier - The shaft 292 to the left, shows on the display device higher load and increases also the rate at which the counter 232 flows through the gas meter Amount of gas registered. On the other hand, if the gas lines are additionally charged, this shifts the shaft 292 in its extreme right position according to FIG. 15, thereby couples the Sleeve 280 with the gear 330 and thus also increases the rate at which the counter 232 the gas flow rate is registered by the counter. With this modified Embodiment, another pair of contacts 336 is connected to the light source 324c, so that even if the pressure in line 240 is above average, the higher network load is supplied.

Of course, the measuring device according to the invention is both for industrial, public and economic as well as for private household consumers usable. In addition, the device and the method according to the invention are also on other fluid flow systems are applicable where flow meter readings are desired are.

In summary, the invention therefore also provides a measuring device a flow meter, a pressure meter and a counter. The exits of pressure meter and flow meter are so geeetzt each other in relation that they provide a numerical display on the counter that shows the irtit fluid pressure in the Fluid diversion is inversely and the flow rate is directly proportional, being the fluid system load is reflected in the volume display.

Claims (9)

Claims measuring 1. Fluidum device, such as water or gas meter, marked thereby a measuring device for measuring a characteristic value of the fluid flow in a Fluid diversion and for the delivery of an output signal dependent thereon, which the Flow rate of fluid through the conduit is proportional to a device to measure the pressure of the fluid and to supply a pressure proportional to this Output signal, a counter and a device for processing throughput signal and pressure signal for the purpose of providing an indication on the counter which the flow rate proportional by fluid diversion and inversely proportional to fluid pressure is. 2. Apparatus according to claim 1, characterized in that the counter has a unit of measure registering presentation, the increase in the counted for a given unit of the actual pluidum rate and units of measure displayed for a first fluid pressure is greater than the increase that for the same amount of fluid flow rate at a second, the first fluid flow pressure exceeding fluid pressure counted and displayed units of measure. 3. Apparatus according to claim 1, characterized in that the counter has a unit of measure registering presentation, the increase in the Quantity units at a given pressure at a first throughput rate are registered is greater than the increase in the units of measure that are required for the predetermined pressure can be registered at a second throughput rate, which is smaller than is the first throughput rate. 4. Apparatus according to claim 1, characterized in that the processing device Has means for continuously relating the throughput signal and the pressure signal, to provide a display on the counter that constantly shows the throughput through the Fluid diversion proportional and constantly reversed to fluid pressure in the line is proportional. 5. Apparatus according to claim 1, characterized in that the processing device Means for converting the flow rate signal into a rate output signal for has the counter, which is proportional to the flow rate through the line is, and that to the output pressure signal means for changing the conversion means according to the pressure signal is connected to a quantity output signal on the counter to deliver that in a different proportion to the Durohsatzquote through the line stands as the last-mentioned relationship. 6. Apparatus naoh claim 1, characterized in that the processing device a number of gears that the flow rate output signal this Can drive gears that the gears with an output to the counter are connected, which has a display in the form of throughput units the line supplies, and that at the pressure signal output a device for changing the transmission ratio of the gears is connected to the quantity display change in inverse proportion to the pressure in the fluid bypass. 7. Apparatus according to claim 1, characterized in that a remote display device and means are provided for communicating the remote display device with the print output signal couples, to provide a display proportional to the fluid pressure on the display device. 8. Fluid measuring device for a fluid network with several fluid distribution lines, characterized by a device for measuring the fluid network load, a Device coupled to this measuring device for supplying one of the network load proportional output signal, a device for measuring the fluid flow rate through a certain line during a predetermined period of time, one to the device coupled to the latter device for delivering one of these throughput quantities proportional output signal and a device for setting the two output signals in relation for the purpose of delivering one proportional to the amount of fluid used and the network load Advertisement. 9. Apparatus according to claim 8, characterized in that a counter is provided and that the display in the register is presented in units of measure. 10. Apparatus according to claim 8, characterized in that a remote display device and means for delivery coupling this device to the fluid measuring device a remote display of the network load are provided. 11. The device according to claim 8, characterized in that the fluid system is a water distribution network. 12. The device according to claim 8, characterized in that the fluid system is a gas distribution network. 17. Procedure for determining consumer charges for a with a Fluid system with several fluid distribution lines through a consumer line flowing fluid as a function of the system load and the consumed fluid or amount of water, characterized in that the load on the water system is measured and an output signal proportional to it is generated during a predetermined The amount of fluid flowing through a consumer line is measured and entered output signal proportional to this is generated, the two output signals to each other can be related to one of the amount of fluid consumed and the system load to provide a proportional display and a charge to the fluid system user based on the net change in the latter display during the given Time span is calculated. Blank page