NO317072B1 - Monitoring system for a pipeline system - Google Patents

Abstract

The invention relates to a monitoring system and a monitoring method for a pipeline system (1) comprising a feeding point (2) and a plurality of delivery points (3) as is used, for example, for fueling aircraft with kerosene at an airport. According to the invention, a first measuring device (6) which is arranged at the feeding point is provided for detecting a quantity of fluid fed into the pipeline system and is provided for generating a corresponding first measured quantity. In addition, withdrawal devices for withdrawing fluid from the pipeline system (1) are provided at said delivery points (3). A second measuring device (6) provided for detecting a quantity of fluid withdrawn from the pipeline system (1) and for generating a corresponding second measured quantity is arranged on each withdrawal device (4). The first and second measured quantities (5, 6) are transmitted to a computing device (7) which composes a differential value between the first measured quantity and the summed second measured quantity, which sums a plurality of differential values over a certain period, and which compares the resulting sum differential value with a predetermined limiting value. The inventive monitoring system and monitoring method serve to quickly and reliably detect leaks in the pipeline system (1).

Description

The present invention relates to a monitoring system for a pipeline system, which is used e.g. at airports for the supply of fuel to aircraft. The present invention also relates to a method for monitoring a pipeline system of this type. The monitoring system in accordance with the invention and the monitoring method in accordance with the invention are used in particular to detect leaks in the pipeline system, so that leakage of fluid, such as e.g. kerosene, to the environment, can be detected and stopped as quickly as possible.

' Pipeline systems such as airports are equipped for the supply of kerosene to aircraft, include a fueling point and a majority of withdrawal points. The fluid transported in the pipeline system, e.g. kerosene, is fed into the pipeline system at the feed point, and can be withdrawn at the majority of withdrawal points as required. The pipeline system is usually under pressure, so that large quantities of fluid can flow out into the surroundings if a leak occurs.

An opportunity to detect leaks that occur in the pipeline system is realised, e.g. by simply measuring the flow of fluid at the feed point and at the outlet points. The amount of fluid flowing into the system at the feed point and the amount of fluid discharged from the piping system at the outlet points can be compared to determine the instantaneous flow rate. However, leakage monitoring that only uses flow measurements falls short already due to the insufficient continuity of the measured value reporting and the fact that the flow only represents a relative value at a given time,

not an absolute value over a longer withdrawal period. Furthermore, a flow measurement is also affected by the error for time measurement and small absolute resolution, in addition to error tolerance for pulse measurement in the flow meter

It is therefore the purpose of the present invention to provide a monitoring system and a monitoring method for a pipeline system with a feed point and a plurality of outlet points, which allows fast and reliable leak detection in the pipeline system using simple means.

This purpose is achieved by a monitoring system in accordance with the appended claim 1 and a monitoring method in accordance with the appended claim 9. Advantageous embodiments are described in the respective subclaims.

The monitoring system for a pipeline system with a feed point and a plurality of withdrawal points in accordance with the present invention comprises a first measuring device arranged at the feed point to determine an amount of fluid fed into the pipeline system and to generate a corresponding first measurement variable. Furthermore, withdrawal devices for withdrawing fluid from the pipeline system are provided at the withdrawal points, a second measuring device being arranged on each withdrawal device to determine an amount of fluid withdrawn from the pipeline system and to generate a corresponding second measurement variable. The first and second measurement variables are transferred to a data processing device, which forms a differential value between the first measurement variable and the sum of the second measurement variables, adds together a plurality of differential values over a given

time period, and compares the resulting sum of differential values with a predetermined threshold value.

Similarly, the monitoring method for a pipeline system with a feed point and a plurality of withdrawal points in accordance with the present invention comprises the following steps: determining an amount of fluid fed into the pipeline system at the feed point and generating a corresponding first measurement variable, withdrawing fluid from the pipeline system at the withdrawal points , wherein a quantity of fluid drawn from the pipeline system is determined at each outlet point, and a corresponding second measurement variable is generated, and transfer of the first measurement variable and the second measurement variable to a data processing device, where a differential value between the first measurement variable and the sum of the other measurement variables is formed, where a a plurality of differential values over a given time period are added together, and the resulting sum of differential values is compared to a predetermined threshold value.

In this respect, the purpose of the present invention is to allow, as far as possible, a continuous comparison of the amount of supplied fluid with the amount of drained fluid. As a result of the completely asynchronous behavior of the first measurement device and the second measurement devices, there is always a differential quantity for each monitoring result. The addition of measured differential values over a defined time period and the comparison with a predetermined threshold value allows a reliable and simple detection of leaks in the pipeline system in a simple way.

It is advantageous that the tapping devices are mobile, and that they can be connected to the tapping points, as a transmission device for transferring the second measurement variable to the data processing device is provided on each tapping device. In the example of pipeline systems provided at airports, e.g. supply of fuel to the aircraft via mobile fuel supply vehicles, which can be connected as needed to the take-off points, such

that the kerosene can be drained from the pipeline system, and the respective aircraft can be filled with fuel. 1 according to the present invention is a transfer device for transferring the second measurement variable to the data processing device in the monitoring system provided on each fuel supply vehicle.

The first measuring device and the second measuring device advantageously measure the respective amount of fuel as volume per unit of time. The first measurement variable and

the other measurement variables are therefore values whose unit is volume per unit of time.

The predetermined threshold value is also set as volume per unit of time.

Furthermore, it is advantageous if the data processing device generates a

corresponding warning signal if the sum of the differential values exceeds the threshold value and transmits said signal to the tapping devices. The withdrawal devices, which withdraw fluid from the pipeline system when they receive a warning signal, automatically interrupt the withdrawal process. In this way, the process of draining fluid from the pipeline system is easily and quickly interrupted, thereby allowing repeated testing to determine whether a leak really exists, and if this is confirmed, location of the leak is permitted.

If the data processing device during the confirmation procedure detects

a further increase in the sum of differential values, and if a second, higher threshold value is exceeded, the data processing device initiates a shutdown of the pipeline system, and connection to a parallel pipeline system.

The location of the leak can then be found in the shut-off piping system, and the leak can be repaired.

During the formation of the sum of differential values eliminates

the data processing device advantageously permanently occurring differential values which are caused by time delays in the pipeline system and/or by system tolerances. In other words, permanently occurring differential values caused by timing errors and tolerances in the measuring instruments are eliminated in the data processing device.

Furthermore, it is advantageous to provide at least one temperature sensor, which is used

for temperature compensation of the sum of differential values detected by the data processing device.

The present invention will be described in more detail in the following by means of a preferred embodiment, with reference to the attached drawings, where: fig. 1 is a schematic overview of a pipeline system where the present invention is used, and

fig. 2 is a circuit diagram of a monitoring system in accordance with the invention.

Fig. 1 is a schematic illustration of a pipeline system 1, where the present invention can be used. The illustrated pipeline system 1 is integrated in e.g. an airport, and is used to supply planes etc. with kerosene. In the following, only those components of the illustrated pipeline system 1 which are relevant to the present invention will be described.

The pipeline system 1 represents the connection between a tank 17 for kerosene with outlet points 3 arranged on the platforms (eng.: the aprons) for the planes. The pipeline system 1 is laid out as a ring with a view to maximum accessibility and with a view to avoiding pressure waves in the system. The pipeline system usually has a length of several km, and kerosene transported in the pipeline system is usually under an operating pressure of several bars.

The tank 17 for kerosene is filled e.g. via an external pipeline 20, fuel freight train 18 or railway trailers 19 supplied with tanks via corresponding connections. The pipeline system 1 is supplied with kerosene from the tank 17 via a feed point 2. Kerosene can be withdrawn from the pipeline system 1 at a plurality of withdrawal points 3, e.g. a withdrawal point 3a, a withdrawal point 3b and a withdrawal point 3c, by means of corresponding withdrawal devices 4. Given that kerosene is not withdrawn from each withdrawal point 3 at all times, the withdrawal devices 4 are usually mobile, and they can be connected when necessary to corresponding withdrawal points 3 E.g. the illustrated dispensing device in 4a is a fuel supply vehicle, which is shown connected to the dispensing point 3a and which refuels an aircraft. Connected to the outlet point 3d is a fuel supply trailer 4b, which supplies fuel to a jet fighter. Connected to the fuel supply point 3c is a fuel tank 4c, which e.g. used to refuel helicopters. As soon as the respective fuel supply process is completed, the withdrawal devices 4 are again released from the withdrawal point and used with another withdrawal point. 1 addition to the above-mentioned components, which are relevant to the invention, the illustrated pipeline system 1 also includes, among other things, a pumping station for a fuel supply vehicle, an emptying station for a fuel tanker, a pipeline transfer station and a hydrant pumping station.

Fig. 2 is a circuit diagram showing an embodiment of a monitoring system in accordance with the invention, for the pipeline system 1 illustrated in fig. 1. The monitoring system comprises a first measuring device 5 arranged at the feed point 1. The measuring device 5 registers the amount of kerosene supplied to the pipeline system 1 from the tank 17 as a volume size, i.e. as supplied volume per unit of time. In this regard, the first measuring device 5 generates the determined amount of kerosene as a first measuring variable. Arranged on the tapping devices 4, i.e. e.g. on the fuel supply vehicle 4a, the fuel supply trailer 4b and the fuel tank 4c, in each case is a second measuring device 6, which detects the amount of kerosene drawn from the pipeline system 1 via the corresponding outlet point 4 in each case, and generates a corresponding second measuring variable. Here, the amount of kerosene drained is also measured in units of drained volume per unit of time. The first measuring device 5 and the second measuring device 6 are e.g. flow meters. The first measurement device 5 arranged at the feed point 1 leads the first measurement variable to a connected data processing unit 7. The other measurement devices 6 are connected via a processing device 13 to a transmission device 12, which transmits the second measurement variable to the data processing unit 7 via an antenna 14 via a radio connection. The data processing unit 7 is connected to a plurality of antennas 15a, ISb, 15c, which are arranged over the airport in such a way that signals can be transmitted and received in all possible positions.

The radio transmission between the tapping device 4 and the data processing device 7 can e.g. is realized using a LAN network. Furthermore, the antenna 15 is preferably connected by means of optical waveguides to the data processing device 7 to ensure fast and reliable transmission even of large amounts of data.

The processing units 13 arranged on the tapping devices 4 transform the second measuring variable for the other measuring devices 6 into signals which can . transmitted by radio in a similar way. Furthermore, a receiving device 16 is connected to the antenna 14 provided on each tapping device 4 to receive signals from the data processing unit 7. The receiving device 16 is also connected to the processing device 13, which transmits the signals received by the data processing unit 7 to the fuel supply control 9, a device for transmitting acoustic or optical signals 10 or a display device 11, depending on the type of signals received. The second measuring device 6 is also connected to the display device 11, so that the amount of kerosene dispensed by the dispensing device 4 can be read. The other measurement variables received by the data processing device 7 are added together, after which a differential value between the first measurement variable and the sum of the other measurement values is formed. In this respect, the sum of the other measurement variables is preferably subtracted from the first measurement variable. The first measurement variable and the other measurement variables are not average measurement variables, but instantaneously measured flow quantities, which are measured at a specific clock frequency, i.e. at given time intervals. A plurality of differential values over a given time period are added together in the data processing device 7, after which the resulting sum of differential values is compared with a predetermined threshold value. The predetermined threshold value can be e.g. several thousand liters per my. If the sum of the differential values exceeds the predetermined threshold value, there is a high probability that a large leak has occurred in the pipeline system 1. When the sum of the differential values exceeds the threshold value, the data processing unit 7 generates a corresponding warning signal and transmits this by means of radio via the antenna 15 to the withdrawal devices 4. Here, the warning signals are received via the antenna 14 and the receiving device 16, and transmitted by means of the processing device 13 to the device 9 for fuel supply control, the device 10 for transmitting an acoustic or optical signal, and

the display device 11. The device 10 generates an acoustic or optical

. warning signal, so that the respective operator of the tapping device is informed that the pipeline system is automatically interrupted. The device 9 for fuel supply control interrupts the withdrawal process immediately after receiving the warning signal, so that kerosene is no longer withdrawn from the pipeline system 1 as a whole.

A pressure monitoring procedure is then carried out which lasts approximately 1 minute, where the pressure behavior is essentially monitored in defined, specific pipe sections in the pipeline system 1. If there are differences in the pressure levels, it can be concluded that there are possible leaks. If the sum of the differential values continues to increase, i.e. if a quantity of kerosene that exceeds the threshold value is fed into the pipeline system 1 at the feed point 2, and a second predetermined threshold value, which is higher than the first threshold value, is exceeded, the data processing device 7 initiates a shutdown of the pipeline system 1 and switches over to a parallel, second pipeline system. The second parallel pipeline system is arranged parallel to the first pipeline system 1 and is used to ensure the supply of kerosene in the event of failure of the first pipeline system 1.

During the formation of the sum of differential values in the data processing device 7, permanently arising differential values, which occur e.g. as

result of time error and the tolerance for the first and second measuring devices 5 and 6. Furthermore, temperature sensors 8, 21 are respectively provided in the vicinity of the first feeding point 1 and in the vicinity of the measuring device 6, which is connected to the data processing device 7, and is used for temperature compensation of the sum of differential values.

Claims (10)

1. Monitoring system for a pipeline system (1) with a feed point (2) and one or more outlet points (3), with a first measuring device (5) arranged at the feed point (1), which determines a quantity of fluid or quantity of fluid per unit of time fed into the pipeline system (1) and generates a corresponding first measurement variable, withdrawal devices (4) which withdraw fluid from the pipeline system, a second measurement device (6) arranged on each withdrawal device (4), which determines one amount of fluid or amount of fluid per . time unit tapped from the pipeline system (1) and generates a corresponding second measurement variable, and a data processing device (7), to which the first measurement variable and the second measurement variable are transferred, which forms a differential value between the first measurement variable and the sum of the other measurement variables, adds together a majority of differential values over a given time period and compares the resulting sum of differential values with a predetermined first threshold value, characterized in that if the sum of differential values exceeds the first threshold value, the data processing device (7) generates a corresponding warning signal and transmits said signal to the tapping devices (4), after receiving the warning signal, the withdrawal devices (4) which withdraw the fluid from the pipeline system (1) automatically interrupt the withdrawal, and if a further increase in the sum of differential values is detected and a second threshold value is exceeded, the data processing device (7) initiates a shutdown of the pipeline system (1). 2. Monitoring system for a pipeline system in accordance with claim 1, characterized by the tapping devices (4) are mobile and can be connected to the tapping points (3), a transmission device (12) being provided on each tapping device (4) to transmit the second measurement variable by means of radio to the data processing device (7). 3. Monitoring system for a pipeline system in accordance with claim 1, characterized by if a further increase in the sum of differential values is detected, and if a second, higher threshold value is exceeded, the data processing device (7) initiates a shutdown of the pipeline system (1) and switches over to a parallel pipeline system. 4. Monitoring system for a pipeline system in accordance with one of the above requirements, characterized by that the data processing device (7) during the formation of the sum of differential values permanently eliminates occurring differential values caused by time delays, in the pipeline system (1) and/or system tolerances. 5. Monitoring system for a pipeline system in accordance with one of the above requirements, characterized by at least one temperature sensor (8) for temperature compensation of the sum of differential values determined by the data processing device (7). 6. Monitoring method for a pipeline system with a feed point (2) and one or more outlet points (3), comprising the steps: determining a quantity of fluid or a quantity of fluid per unit of time fed into the pipeline system (1) at the feed point. and to generate a corresponding first measurement variable, to withdraw fluid from the pipeline system at the withdrawal points (3), whereby a quantity of fluid or a quantity of fluid per time unit drawn from the pipeline system (1) is determined at each outlet point (3), and a corresponding second measurement variable is generated, and, to transfer the first measurement variable and the other measurement variables to a data processing device (7), where a differential value between the first measurement variable and the sum of the other measurement variables is formed, whereby a majority of differential values over a given time period are added together, and the resulting sum of differential values is compared with a predetermined first threshold value, characterized in that if the sum of differential values exceeds the first threshold value, the data processing device (7) generates a corresponding warning signal and transmits said signal to the withdrawal devices (4), the withdrawal of fluid at the withdrawal points (3) is automatically interrupted when the warning signal is received, and if a further increase in the sum of differential values is detected and a second threshold value is exceeded, the data processing device (7) initiates a shutdown of the pipeline ing system (1). 7. Monitoring method for a pipeline system in accordance with claim 6, characterized in that the other measurement variables are transferred to the data processing device by means of radio. 8. • Monitoring procedure for a pipeline system in accordance with claim 6, characterized by if a further increase in the sum of differential values is detected, and a second, higher threshold value is exceeded, the data processing device (7) initiates a shutdown of the pipeline system (1) and switches over to a parallel pipeline system. 9. Monitoring procedure for a pipeline system in accordance with one of claims 6-8, characteristically the data processing device (7) during the formation of the sum of differential values eliminates permanently occurring differential values caused by time delays in the pipeline system (1) and/or by system tolerances. 10. Monitoring method for a pipeline system in accordance with one of claims 6-9, characteristically the sum of differential values determined by the data processing unit (7) is temperature compensated.