DE29818056U1 - Tanker truck - Google Patents

Description

The invention relates to a tanker with a tank for liquid gas, an outlet for dispensing liquid gas and a flow meter arranged between the tank and the outlet for measuring the flow of liquid gas from the tank to the outlet.

Such tankers are known to be used to transport liquefied gas from a central warehouse to a smaller storage tank,

10 in particular a storage tank of an end user. As a rule, the tank of a tanker is filled by the central station in accordance with an order placed by the recipient of the LPG, then the LPG is transported in the tanker and discharged to the recipient via an outlet

15. To determine the amount of liquid gas delivered, volumetric flow meters are used, which measure and add up the volume flow rate of the liquid gas - from which gaseous gas is usually separated beforehand using a gas separator and returned to the tank. The volume determined in this way

20 The total volume of the liquid gas dispensed is used to calculate the total mass required for the cost calculation, which is the product of the total volume and the density of the

Hanover:

Koblenzer Straße 21 D-30173 Hannover Federal Republic of Germany Telephone 0511 / 988 75 07 Fax 0511 / 988 75 09

Please reply to:

Brunswick:

Theodor-Heuss-Straße 1 D-38122 Braunschweig Federal Republic of Germany Telephone 0531 / 28 14 0-0 Fax 0531 / 28 140 28

liquefied gas. To determine the density, the temperature of the liquefied gas in the tank is determined and read on a reading unit on the tank truck. The density of the liquefied gas is then determined from this temperature using a corresponding diagram or table. This allows the total mass to be determined as the product of the total volume and the density of the liquefied gas. Since the precise calculation of the density from the temperature in particular is usually complex and yet must be carried out with sufficient accuracy, the measured temperature and the measured total volume are sent from the tank truck to an external administration station, which calculates the total mass and usually at the same time determines the total costs for the total mass of liquefied gas, creates an invoice and sends it to the recipient of the liquefied gas.

The disadvantage of this, however, is that determining the total mass is very time-consuming and, in particular, the determined value of the total mass is not quickly available.

The invention is based on the object of creating improvements in this respect and in particular of providing a tanker that enables a safe, fast and cost-effective determination of the total mass delivered.

This task is solved in that the flow meter is a mass flow meter that measures a mass flow according to the principle of the Coriolis force, a determination device is provided for determining a total mass delivered from the measured mass flow and a reference quantity proportional to the total mass, and an output device is provided for outputting the determined total mass and the reference quantity.

According to the invention, the total amount of gas delivered is determined using a measuring method based on the principle of the Coriolis force. Such Coriolis forces occur as mass inertia forces whenever a linear and a rotary movement overlap at the same time. In this case, in a co-

riolis measuring method for determining the transported mass, in particular, an oscillation can be generated in which two parallel measuring tubes through which liquid gas flows are made to oscillate in opposite phases. This creates a phase shift in the tube oscillation on the measuring tubes. During mass flow, a tube oscillation is slowed down on the inlet side and accelerated on the outlet side, for example, whereby the phase difference of the oscillation on the two measuring tubes can be determined, for example, by measuring tube oscillations on the inlet side and outlet side, for example using electrodynamic sensors.

The measured mass flow is passed on by the mass flow meter to a determination device that can directly determine the relevant total mass. This can advantageously be done by converting the measured mass flow into measuring pulses within a measuring transducer and summing up these measuring pulses in the determination device. Since, according to the invention, a further proportional, in particular linearly proportional reference value to the total mass is also directly determined in the determination device, the relevant total price for the total mass of liquid gas can also be directly determined and, for example, immediately output via an output device, e.g. printed out. An invoice can thus be created directly by the tanker in which both the total mass of liquid gas delivered and the total price for this can be output directly, so that the necessary communication between the tanker and an administrative center after the treatment process and the subsequent sending of the invoice by the administrative center can be omitted.

The invention is explained in more detail below with reference to the accompanying drawings using an embodiment.

Show it:

Figure 1: A block diagram for a tank truck according to the embodiment;

Figure 2: A measuring attachment for the tanker from Figure 1 in side view;

Figure 3: A top view of the measuring attachment of Figure 2.

According to Figure 1, liquid gas is fed into a tank 1 via a first liquid gas line 8a to a gas separator 2, in which gaseous gas is separated and returned to the tank 1 via a gas return line 9. The liquid gas freed from the gaseous gas is fed from the gas separator 20 via a second line 8b to a mass flow meter 3, in which, according to the invention, a mass flow is determined directly according to the Coriolis force measuring principle. In this case, the liquid gas flows through two parallel measuring tubes and is caused to oscillate in opposite phases. They thus form a type of "tuning fork", with their oscillation behavior differing due to the different relationship between the direction of oscillation and the direction of flow of the liquid gas. Coriolis forces are mass inertia forces that always occur in a system when linear or rotary or rotating movements overlap at the same time. The size of the Coriolis force depends on the moving mass, its speed in the system and the mass flow. Instead of rotation, this measuring method generates an artificial oscillation. The Coriolis forces generated on the measuring tubes cause a phase shift in the tube oscillation, whereby this phase shift is different on the two measuring tubes. Only when the system is at a standstill, i.e. in the absence of

of flow, both pipes oscillate in phase, with a mass flow the pipe oscillation is slowed down on the inlet side and accelerated on the outlet side, whereby the phase difference is larger if the mass flow is larger. The pipe oscillation can be measured, for example, using electrodynamic sensors on the inlet and outlet sides. The measuring pipes are preferably excited to resonate.

The liquid gas then passes from the mass flow meter 3 via a third liquid gas line 8c to a pressure-maintaining valve 4, whereby a constant overpressure above the storage pressure of the liquid gas in the tank 1 is set in the pressure-maintaining valve. This overpressure can be, for example, one bar and is also set in the gas separator 2 via a pressure equalization line 10. This overpressure serves as a safety measure against excessive leakage of liquid gas from the tank 1 into the subsequent system. The liquid gas is then passed on via a liquid gas line 8b to the outlet 5, from which it can be taken to fill a tank, e.g. at a consumer.

According to the invention, the measured mass flow from the mass flow meter 3 is passed to a measuring transducer 11, which converts the measuring signal into digital measuring pulses. These digital measuring pulses are passed on from the measuring transducer 11 to a measuring counter 6, which adds up or integrates the measuring pulses and passes the integral of the measured values on to the calculation unit 7. In this calculation device 7, the total value measured in the measuring counter 6 is assigned to a corresponding total mass and the total price corresponding to the total mass for the amount of liquid gas withdrawn is also determined. These two values, the total mass and the total price, are passed on to an output device 12, e.g. a printer, which can print out the values directly, e.g. also as an invoice for forwarding to the customer. The calculated values are also sent to a transmission device 13, e.g. a radio or advantageously a telephone modem, e.g. a telephone modem for

cordless telephones such as cell phones, and can thus be forwarded by the transmission device 13 to an external central location. The transmission device 13 can also be used to forward data from the central location to the transmission device 13 and then to the calculation device 7. This data can in particular also include the current price for the liquid gas, which also depends on the quantity to be measured, for example.

This tank truck according to the invention can advantageously be used in a system in which an order is sent from a customer to the central office, and the central office forwards a delivery order to the tank truck, stating the current price of LPG and possibly an estimated total mass of LPG to be delivered. The tank truck or road tank truck can accordingly drive to the respective customers, deliver a desired total mass of LPG, directly issue an invoice for the quantity delivered, taking into account the price of LPG, and forward the confirmation of the delivery order, including the delivery date, total mass, and calculated total costs, to the central office via the transmission device 13.

BR/as

List of reference symbols

1 tank

2 gas separators

3 Mass flow meters

4 Pressure holding valve

5 Outlet

6 measuring counters

7 Calculation device 8a first liquid gas line 8b second liquid gas line 8c third liquid gas line 8d fourth liquid gas line

9 Gas return line

10 Pressure equalization line

11 Transducers

12 Output device

13 Transmission device

14 Signal line

Claims (12)

1. Tanker with a tank (1) for LPG, an outlet (5) for dispensing LPG and a flow meter (3) arranged between the tank (1) and the outlet (5) for measuring the flow of LPG from the tank (1) to the outlet characterized in that the flow meter is a mass flow meter (3) which measures a mass flow according to the principle of the Coriolis force measures, a determination device (6, 7, 11) for determining a total mass delivered from the measured mass flow and a reference value proportional to the total mass is provided, and an output device (12) is provided for outputting the determined total mass and the reference value. 2. Tanker according to claim 1, characterized in that a gas separator (2) is provided between the tank (1) and the mass flow meter (3), a gas return line (9) being connected from the gas separator (2) to the tank (1). Hanover: Koblenzer Straße 21 D-30173 Hannover Federal Republic of Germany Telephone 0511 / 988 75 07 Fax 0511 / 988 75 09 Please reply to: Brunswick: Theodor-Heuss-Straße 1 D-38122 Braunschweig Federal Republic of Germany Telephone 0531 / 28 14 0-0 Fax 0531 / 28 140 28 running. 3. Tanker according to claim 1 or 2, characterized in that between the mass flow meter (3) and the Outlet (5) is provided with a pressure retaining valve (4) for setting a desired overpressure and a pressure equalization line (10) runs from the pressure retaining valve (4) to the gas separator (2).
10 4. Tanker according to one of claims 1 to 3, characterized in that the detection device has a measuring transducer (11) for converting the measuring signals of the mass flow meter (3), which converts the measuring signal from the mass flow meter (3) and transmits counting pulses to a measuring counter (6). 5. Tanker according to one of claims 1 to 4, characterized in that the output device (12) is a printer. 6. Tank truck according to one of claims 1 to 5, characterized in that the output device (12), preferably also the calculation device (7), is arranged in the driver's cab of the tank truck. 7. Tank truck according to one of claims 1 to 6, characterized in that a transmission device (13) is provided for transmitting the determined total mass and the reference value from the tank truck to an external central location. 8. Tanker according to claim 7, characterized in that the transmission device (13) receives input data for calculating the reference value from the external central station. 9. Tanker according to claim 7 or 8, characterized in that the transmission device (13) is arranged in the driver's cab. 10. Tank truck according to one of claims 1 to 9, characterized in that the mass flow meter (3) measures the mass flow by generating an oscillation and determining a phase shift of the oscillation. 11. Tanker according to claim 10, characterized in that the mass flow is measurable by the relative phase shift of two measuring streams of the liquid gas. 12. Tanker according to one of claims 1 to 11, characterized in that it is designed as a road tanker suitable for road traffic. BR/as