HU190279B - Electronic fuel charging counter - Google Patents

Abstract

Switching arrangement in the form of a pulse sequence measured quantity, especially fuel quantity and with this amount proportionate value, especially for the amount payable, mainly for multi-component fuel dispensing stations, which switching arrangement is first and a second transducer (10, 20) having a first shunt circuit (30) and first and second a second summing over the multiplier circuit (50, 60) connected to a circuit (70). The first knife circuit (30) output is the quantity display with the unit (40), the second summing circuit (70) and the output is with the sum display unit (80) linked

Description

BACKGROUND OF THE INVENTION The present invention relates to a circuit arrangement for displaying a pulse train volume, in particular a dispensed amount of fuel, and a value proportional to such a quantity, particularly an amount payable, particularly to multi-component fuel dispensing stations.

Fuel dispensing stations traditionally use mechanical counting devices to display the amount of fuel dispensed to the consumer by the dispensing pump and the amount to be paid. In these known solutions, a flow meter is inserted into the fuel delivery pipeline, the angular rotation of which is proportional to the flow rate. Angular rotation is carried out by a complex gear system to a numerical counter. The complexity of the system is exacerbated by the fact that the unit price must be adjustable according to the changes in the unit price. multiplier which converts the measured amount of fuel into an amount payable by inserting a suitable gear wheel. The amount to be paid is indicated by a numeric dial driven by a multiplier.

These mechanical counters are subjected to very high loads and therefore often fail.

The above problems are more pronounced in the case of equipment serving different fuel blends (gasoline + oil, octane mix), where each component has to be measured separately, the measured quantities have to be converted into amounts payable and the subtotals have to be added together.

Recently, fuel metering devices with electronic display, which are only suitable for dispensing single-component fuel (one octane grade pure gasoline, pure gas oil or household fuel oil), are becoming more widely used.

These electronic devices could in principle be redesigned using a variety of microprocessor solutions to allow for multi - component fuels, but this would disproportionately increase production costs and would not solve the need for adaptability due to constant changes in fuel prices. fired programs cannot be changed at will, but programmable solutions require programming capacity).

It is an object of the present invention to overcome these shortcomings of the prior art.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a simple and relatively inexpensive switching arrangement suitable for use in multi-component fuel dispensing stations, wherein unit prices can be readily adjusted at any time as required.

The problem is solved by displaying a pulse sequence of a switching arrangement, in particular the amount of fuel dispensed, and a value proportional to this quantity, particularly for a multi-component fuel dispensing station, by transmitting the circuit arrangement, and a second signal processing and sum display unit connected to a second output of the first signal processing circuit and a second signal processing and sum display unit connected to an output of the multiplier circuit, and having, in accordance with the present invention, first and second encoders, are connected via a multiplier circuit to a second summing circuit and the first summing circuit The output circuit of the sender unit, the second öszszegező circuit output is connected to the display unit amount.

In a preferred embodiment of the circuit arrangement according to the invention, at least one of the summing circuits has two parallel decimal counters and a binary adder circuit having a complementary code unit connected to their outputs.

In another preferred embodiment, at least one of the multiplication circuits comprises a comparator circuit having an oscillator running freely through one input counter and a value adjusting unit connected to a further input of the signal converter.

Preferably, a flanged value adjustment unit is used. The invention will now be described with reference to an exemplary embodiment, which is illustrated in the accompanying drawings. The

Figure 1 is a block diagram of an exemplary circuit layout, a

Figure 2 is a more detailed block diagram of the summing circuits of the circuit arrangement of Figure 1, and

Figure 3 is a more detailed block diagram of the multiplication circuits of the circuit arrangement of Figure 1.

The circuit arrangement of FIG. 1 has a first transducer 10, a second transducer 20, a first summing circuit 30, a quantity display unit 40, a first multiplier circuit 50, a second multiplier circuit 60, a second summing circuit 70 and a sum display unit 80.

The output 11 of the encoder 10 is connected to the input 31 of the first summing circuit 30 and the output 21 of the second encoder 20 to the input 35 of the circuit 30. The output 32 of the circuit 30 is connected to the input 51 of the first multiplier 50, the output 33 is connected to the input 61 of the second multiplier 60, and the output 34 is connected to the input 41 of the quantity display unit 40. The output 52 of the multiplier 50 is connected to the input 71 of the second totalizing circuit 70, the output 62 of the multiplier 60 to the input 72 of the circuit 70 and the output 73 of the circuit 70 to the input 81 of the totalization unit 80.

The circuit arrangement of Figure 1 functions as follows:

The transducers 10, 20 provide a number of pulses corresponding to the flow through the lines conveying each of the components of the dispensed fuel to the inputs 31, 35 of the first summing circuit 30 and to the first multiplying circuits 51 and 61 of the first 50 and second 60s. The pulses subjected to signal generation are summed up by the circuit 30 and then by the quantity 21

It transmits 190 279 signals to 41 inputs of 40 units so that the total amount of the two components can be read out on the unit 40.

Independent signals representing the amount of the two components are multiplied separately by the first multiplier 50 and the second multiplier 60 respectively with the respective unit prices. The two different sum signals appearing at the outputs 52 are summed up by the circuit 70 and fed to the input 81 of the sum display unit 80. The unit 80 reads the total amount payable for the total amount of the two components ¹ .

The adder 30, 70 consist of two parallel circuits ¹ 90.100 numerator decimal, binary adder circuit 110 and a complementary code unit 120 (Figure 2). The counter 90 has 91 inputs and 92 outputs, the counter 100 has 101 inputs and 102 outputs, the circuit 110 has 111, 112, 113 inputs and 114 outputs, and the unit 120 has 121 outputs. The output 92 of the input 111, the output 102 of the ^two inputs 112 and 121 output the input 113 is connected to the STU.

The summation circuit of Figure 2 operates as follows:

The shaped pulse sequences ² arriving at the inputs 91, 101 are passed to independent counters 90, 100 consisting of ten divisors, and then through the outputs 92, 102 and the inputs 111, 112 to the total circuit 110 formed by BC. Circuit 110 is triggered by the rectifier code of complementary ³ circuits of unit 120 to perform a decimal operation.

The multiplier circuits 50, 60 consist of a freely oscillating oscillator 130, a counter unit 140, a comparator circuit 150, a signal converter 160 and a flange ³ -value adjusting unit 170. The oscillator 130 output 131, 140 of the input unit 141 and output 142, 150 of the circuit 151, 152 and 154. The inlet 153 and outlet 160 of the signal converter 161 inputs and 162 outputs, to the output unit 171 is ^4170. Output 131 is connected to input 141, output 142 to input 152, output 162 to input 154, and output 171 is connected to input 161.

A multiplier circuit of Figure 3 operates in the following- ^four ways:

The pulse from the comparator 150 circuit (eg. 1 cl compliant) pulse train supplied by the 130 oscillator reaches számlálóláncra in 140 unit 150, the circuit ⁵ as long permit pulses released amount of the particular component represented by the 153 output (subtotals adder circuit ) until they reach a value of 5 set by the transducer 160 using the flanges of the unit 170. It then disables output 153 until it receives a new control signal.

A very important advantage of this solution is that it does not require any programming capacity or does not require the use of a burned program, which can only be changed at high costs in the event of a change in fuel prices. With our solution, you only need to adjust the rim wheels, which can be done quickly and easily.

It is also an important advantage that the station utilizing the circuit arrangement of the present invention is capable of serving single component fuel without any modification. Finally, the present invention can be incorporated into existing mechanical systems in a simple manner.

Claims (4)

1. A switching arrangement for indicating a pulse sequence quantity, in particular a fuel output and a value proportional thereto, in particular a payable amount, in particular for a multi-component fueling station having a switching arrangement encoder, a first processing circuit connected thereto, and a first output circuit. and a second processing and sum display unit connected to the second output of the first signal processing circuit having a value control unit and a second processing and sum display unit connected to the output of the multiplication circuit, characterized by first and second encoders (10, 20) ), and via a first and second multiplier circuits (50, 60), connected to a second summing circuit (70), and the first summing current the output of the circuit (30) is connected to the quantity display unit (40) and the output of the second totalizing circuit (70) is connected to the total display unit (80). An embodiment of a circuit arrangement according to claim 1, characterized in that at least one of the summing circuits (30, 70) has two parallel decimal counters (90, 100) and a binary adder circuit (120) connected to their outputs with a complementary code unit (120). 110) is. An embodiment of a switching arrangement according to claim 1, characterized in that at least one of the multiplication circuits (50. 60) has a comparator circuit (150) having an oscillator (130) freely running through an input counter (140) for an additional input. a value adjusting unit (170) is connected via a signal converter (160). An embodiment of the switching arrangement according to claim 3, characterized in that it has a flanged value adjusting unit (170).