DE4028734A1 - Fluid dispenser module(s) for motor vehicles - has integral electronic controlwith display, card reader, memory and interface(s) for hydraulic module(s)and power section - Google Patents

Abstract

A system for measured delivery of fluids into motor vehicles consists of a hydraulic delivery arrangement, a fluid container, a measurement device, a journal, a power stage and an electronic controller. A hydraulic module contains a delivery pump with a drive motor, may contain a fluid container with an electrical overflow indicator, a visual float indicator and a fluid level min. switch. A delivery tube has a valve mounted in a housing with a function display and keyboard and electrical, electronic and hydraulic interfaces. A single electrical power unit and a single electronic unit have electrical or electronic interfaces for one or more hydraulic modules and mutual interfaces. USE/ADVANTAGE - E.g. for delivering metered quantities of engine, transmission or hydraulic oil, braking fluid, etc. Can be integrated or made up of discrete units.

Description

The invention relates to a system for custody transfer Fluids for motor vehicles from a hydraulic conveyor unit, a fluid container, a measuring device, a tap device as well as a power unit and an electronic Control exists. The fluids come in any combination Engine oils, gear oils, hydraulic oils, brake fluids, frost preservatives, two-stroke mixtures and fluid greases u. Ä. in question. As a custody transfer, the fulfillment is in accordance with the German one and / or European verification regulations (e.g. verification laws, verification regulations etc.), the approval of such devices or systems by the responsible federal authorities (e.g. physical-technical Federal Institute) and their testing and acceptance by the local calibration authorities (e.g. verification offices) for direct or indirect sale of bulk, d. H. not packaged, fluids End users (e.g. customers at petrol stations), e.g. B. in Selbstbe service to understand.

Individual devices of the above type, e.g. B. in particular for delivery of engine and gear oils, are to a considerable extent in automotive Workshops used; the loose delivery does not take place here to the end user, but fluids are drawn directly into that Motor vehicle (e.g. in the engine) filled (indirect delivery).  

The end consumer then gets on the invoice to know the quality, quantity and price; the levy was carried out here in line with the legal requirements.

In addition, these fluids are available in so-called Disposable containers (e.g. oil cans), be it for use inside a workshop or for direct sale to end users. The increasing disposal problems of these single-use containers, at the fluids are generally water endangering Substances of different hazard classes, called the legislator on the plan, the appropriate rules to avoid Packaging waste, which is not insignificant Deposit payment for the above Problem packaging with one Take-back obligation provided by the original seller is. But this regulation cannot solve the problem, because the disposal question is not solved. The primary The premise of waste management is therefore "avoid" instead of "disposal". After all, it is z. Z. in the federal republic by more than 100 million annually only from disposable Packs for engine oil that are available. A question initially remained completely open: the point in time the payment (before or after the delivery of the fluid), your location (Cash register or device) and their type (cash, chips, cards); such as a possible remote release from the cash register, with a cash payment. Previous payment solutions clearly favored that "Pre-pay solution", i. H. payment before receiving the goods in clear contrast to the processing of the self-service levy of power fabrics for cars ("after-pay"). For the delivery of 2-stroke Mixtures of mopeds and mopeds dominated the payment by means of minted special coins that were previously bought at the cash register and were assigned to a dispensing volume.

Building on these conditions and the state of the art it proves to be particularly advantageous in terms of a building a whole device system for the different fluids, the z. Z. are needed on the motor vehicle to develop the  the immediate consumer in self-service mode Allow purchase as bulk goods.

In further development of the above Conditions in the sense of the "pre-pay Procedure "in the sense of increased security against counterfeiting therefore the plastic card solution using a magnetic card in the Foreground, which has enough memory to hold the assign different fluids and quantities to one card. With a card reader at the central point of a control the programmed data are taken from the device unit for a specific fluid and the associated Quantity released by a signal and the tapping process initiated there by manual actuation; a manual Emergency stop device can interrupt the process as desired. The respective volumetric metering ent by a measuring mechanism speaking of the preselected amount is done either by a Reciprocating meter with the specification and counting of a whole lot times a full piston stroke, the end position of which is electrical registered, counted and compared with the specification until this is zero, d. H. the preselected piston strokes are carried out are. By a corresponding hydraulic control of a 4/2 way solenoid valve, the piston stroke becomes double acting and acted twice. So it is an intermittent one Measurement that has proven to be extremely robust. An entirely other, rotating-continuous measurement represents the mode of action of the Piston meter represents a higher measurement and control effort needed, and therefore less possible.

Thanks to the hydraulic parallel connection of the hydraulic modules for the different fluids any combination of Levies, even spatially separated, can be achieved. Through a mobile, interchangeable container of the respective The fluid of a hydraulic module is its immediate close order and its addition. For calibration reasons it is necessary to lower the pump on the suction side  than the lowest level in the tank so the fluid can flow to the pump through its own gradient.

Another solution, without an integrated fluid container, provides a collection tank for each fluid that removes, for. B. in the ground, is not part of the system. Here is in the vicinity of a feed pump and an air measurement contraceptive device required, which is also not for System belong and by means of long-distance lines with the hydraulic Module are connected.

The control part is located at a central point for the customer brings where the self-service process is initiated by there z. B. the magnetic card is inserted into a card reader, which releases the corresponding module through a display gives. This can e.g. B. happen so that on the display first the encrypted data of the magnetic card are displayed (fluid quality, preset quantity); then the display jumps to zero and the delivery quantity is displayed continuously until the process be ends is. For reasons of termination on the part of the operator is internal arranged a memory that stores all dispensing processes and a certain amount of time can be called up here at will (quantity, Quality, number, date). An internal interface enables the connection of a printer or an interface to a zentra len computer. Through appropriate plug-in modules in the control section the system for dispensing additional fluids is expandable. Corresponding hydraulic, electronic and electrical cut the latter for the power section of the entire system, make the entire system expandable as required; this applies to the number of fluids and their modular delivery points, the spatial arrangement of the modules (together, separately or partly arranged together / partly separately) and the space Liche arrangement of the fluid container.  

The figures show in detail:

Fig. 1 The delivery system with the circuit diagram of a hy metallic module (pump drive electrical) (schematic).

Fig. 2 The delivery system with several external fluid containers (schematic).

Fig. 3 The delivery system in its preferred device version.

Fig. 4 A special hydraulic active circuit of the conveyor unit and the measuring mechanism (tandem measuring mechanism).

A preferred embodiment of the invention is shown below with reference to the circuit diagram of the delivery system for a hydraulic module ( 1 ) shown in FIG. 1; the elec trical power part is ( 2 ), the electronic control part ( 3 ). The hydraulic module ( 1 ) contains, as assemblies, a hydraulic delivery unit ( 45 ), a fluid container ( 6 ), a hydraulic measuring mechanism ( 10 ), a function display ( 14 ), a delivery nozzle ( 11 ) with a full hose valve ( 12 ), an electrical distribution box ( 44 ), a hydraulic interface ( 18 ), an electrical ( 16 ) and an electronic ( 17 ) interface. The electrical power part ( 2 ) and the electronic control part ( 3 ) are connected to the power supply by an electrical plug ( 46 ); the corresponding outputs in the system are the electrical ( 16 ) and the electronic ( 17 ) interface.

The delivery unit ( 45 ) in turn contains a delivery pump ( 4 ) which hydraulically actuates the measuring mechanism ( 10 ), an electric drive motor ( 5 ) and an adjustable overflow valve ( 47 ). The hydraulic measuring mechanism ( 10 ) consists of a double-acting reciprocating piston ( 27 ); its application and alternate delivery of the respective fluid is effected by an electrically controlled 4/2-way solenoid valve ( 30 ). The electrical signals at the respective stroke end ( 28 ) of the stroke piston ( 27 ) take place through a limit switch ( 29 ). The volumetric metering of the fluid takes place intermittently in accordance with the type of action of the reciprocating piston ( 27 ); the sum of its strokes per pre-programmed delivery process results in the pre-selected delivery quantity.

Via a discharge line ( 48 ), in which a sight glass ( 34 ) with a lighting device ( 35 ) is visible to the customer, the fluid is supplied to the discharge nozzle ( 11 ), which is displaceable via a telescopic tube ( 40 ). A full hose valve ( 12 ) in the delivery nozzle ( 11 ) only opens when a hydraulic minimum pressure in the delivery line ( 48 ) is built up. The respective delivery process is started by a start device ( 41 ), and a possible stop by the emergency stop device ( 42 ); it is initiated by the customer.

The fluid container ( 6 ) consists of an exchange container ( 22 ), the wheels ( 23 ), a filler neck ( 36 ) with closure ( 50 ), a driving bracket ( 43 ), an optical float indicator ( 8 ), an electrical overfill indicator ( 7 ), an electrical fluid level minimum switch ( 9 ) and a drain opening ( 37 ) with a drain screw ( 38 ). The minimum switch ( 9 ) is switched and adjusted so that when the minimum level of the fluid in the exchange container ( 22 ) is reached, the current dispensing process can still be handled completely in accordance with the preselected quantity. A foot valve ( 24 ) on the bottom of the exchange container ( 22 ) with a hydraulic quick coupling ( 25 ) for the suction line ( 49 ) of the feed pump ( 4 ) contains the hydraulic interface ( 18 ). The foot valve ( 24 ) must be higher than the suction port ( 39 ) of the feed pump ( 4 ) in order to avoid the intake of air in all operating conditions.

An electrical distribution box ( 44 ) exists for both the internal electrical and the internal electronic part of the module ( 1 ). The associated interfaces are electrical ( 16 ) and electronic ( 17 ).

Several modules ( 1 ) for the different fluids in combination with a single electrical ( 2 ) and electronic ( 3 ) power or control part result in the delivery system (see also FIG. 3).

FIG. 2 shows an example schematically a delivery system for two different fluids which come from two header tank (51) for three different hydraulic modules (1). The two collecting tanks ( 51 ), feed pumps ( 4 ) with electric drive motor ( 5 ) and overflow valve ( 47 ), as well as one air measurement prevention device ( 52 ) - see below - are external, ie outside the hydraulic modules ( 1 ) arranged. A feed pump ( 4 ) supplies two different hydraulic modules ( 1 ), which can be set up as required. The corresponding interfaces of the modules ( 1 ) are hydraulic ( 18 ), electrical ( 16 ) and electronic ( 17 ) analogous to those of the power section ( 2 ) and the control section ( 3 ). The air measurement prevention device ( 52 ) is located downstream of the feed pump ( 4 ); it ensures that there is no air in the fluids that are released to the customer (legal requirement); With this solution it is irrelevant at which geodetic level the feed pump ( 4 ) is in relation to the liquid level ( 53 ) of the associated collecting tank ( 51 ).

The electrical power part ( 2 ) contains the various components such as transformer ( 54 ), fuses ( 55 ) and. Ä., The electronic control part ( 3 ) logical elements, for. B. AND ( 56 ), transistors ( 57 ), a memory ( 21 ) u. Ä., But above all, for use by the customer, a card reader ( 20 ) and a display device ( 19 ) in the form of a display ( 33 ). Each electrical connector ( 46 ) links both devices to the power grid.

Fig. 3 shows an example of a preferred device-like design of the entire delivery system for five different fluids, ie five hydraulic modules ( 1 ). The link to the control part ( 3 ) is made through a line channel ( 58 ) in which the electrical lines and possibly the hydraulic lines (when the fluids are stored in collection tanks) are laid. The control part ( 3 ) shows the display ( 33 ), the diaphragm ( 59 ) for inserting a memory card (eg magnetic, chip, optical card) for the card reading device ( 20 ). The sight glass ( 34 ) and a combined start / emergency stop device ( 41/42 ) are shown on the front of each module ( 1 ); under the delivery nozzle ( 11 ) for "anti-freeze fluid" is a reusable canister ( 60 ). The module ( 1 ) for the "two stroke fluid" is spatially completely separate from the other modules ( 1 ), for. B. on a tank island.

In FIG. 4, the hydraulic module (1) is shown, the electric power unit (2) and the electronic control member (3); the interfaces between them are electrical ( 16 ) or electronic ( 17 ); the connection to the power supply are the plugs ( 46 ). In the hydraulic module ( 1 ) are the individual assemblies, the fluid container ( 6 ) with its hydraulic interface ( 18 ) to the suction line ( 49 ), the electrical distribution box ( 44 ), the delivery unit ( 45 ), the function display ( 14 ) and the Dispensing nozzle ( 11 ) with the full hose valve ( 12 ).

The delivery unit ( 45 ) consists of the delivery pump ( 4 ) with the pump delivery direction 1 ( 61.1 ) or 2 ( 61.2 ), the reversible electric drive motor ( 5 ) with the direction of rotation 1 ( 62.1 ) or 2 ( 62.2 ), the tandem -Measuring mechanism ( 71 ) with a double-acting, adjustable overflow valve ( 47 ). The tandem measuring mechanism ( 71 ) in turn has a single-acting single piston 1 ( 63.1 ) and 2 ( 63.2 ); a piston rod ( 70 ) connects the two individual pistons 1 and 2 ( 63.1 and 63.2 ). The two limit switches ( 29.1 and 29.2 ) register the respective stroke end ( 28 ) of the two individual pistons ( 63.1 and 63.2 ); At the same time, an adjusting screw 1 and 2 ( 64.1 or 64.2 ) as well as a discharge line ( 48.1 or 48.2 ) are integrated in a common stroke adjustment device ( 32 ), which via the discharge line ( 48 ) and the sight glass ( 34 ) to the discharge nozzle ( 11 ) to lead. Various check valves ( 65 ) in the individual lines logically safeguard the hydraulic flow conditions.

The hydraulic function of the tandem measuring mechanism ( 71 ) according to the circuit of the tandem piston ( 63 ) is as follows: The feed pump ( 4 ) with the pump delivery direction 1 ( 61.1 ), which is assigned to the direction of rotation 1 ( 62.1 ) of the drive motor ( 5 ), via the pressure line 1 ( 66.1 ) into the hydraulic chamber 1 ( 67.1 ) in front of the single piston 1 ( 63.1 ); this moves (to the right) until it has reached its stroke end ( 2 B) on the adjusting screw 1 ( 64.1 ) and at the same time an electrical signal is emitted from the limit switch 1 ( 29.1 ); simultaneously the metered volume through the discharge pipe 1 (48.1) of the dosing chamber 1 (69.1) is discharged through the discharge port (11); A possibly too large amount of the feed pump ( 4 ) is returned to the suction line ( 49 ) via the overflow valve ( 47 ). At the same time, according to the "pump delivery direction 2 " ( 61.2 ), on the one hand, the fluid is sucked out of the hydraulic chamber 2 ( 67.2 ) and, if necessary, via the suction line 2 ( 68.2 ), on the other hand the metering chamber 2 ( 69.2 ) is filled on the suction side.

When the direction of rotation of the drive motor ( 5 ) is reversed according to the direction of motor rotation 2 ( 62.2 ), the functional sequence is analog, ie the tandem piston ( 63 ) with its individual pistons 1 and 2 ( 63.1 and 63.2 ) moves to the left until it reaches the stroke end ( 28 ) reached and conveyed alternately from the dosing chamber 2 ( 69.2 ) into the discharge line 2 ( 48.2 ). Basically, it must be ensured in all operating states that the feed pump ( 4 ) with all suction lines ( 49 ) and suction lines ( 68.1 , 68.1 ', 68.2 , 68.2 ') and the tandem measuring mechanism ( 71 ) is geodetically lower than the foot valve ( 24 ) the replacement container ( 22 ).

In addition to the above Versions are the variants of hydrau mical or pneumatic modules or sub-modules or control processes possible that are analog or run analog and so in the basic system can be integrated; these are:

Variant 1 : hydraulic module for the non-verified delivery of water.

Variant 2 : pneumatic module for making compressed air available (not calibrated).

Variant 3 : hydraulic module to provide a high-pressure washing or spraying device.

Variant 4 : electro-pneumatic module to provide various devices (e.g. vacuum cleaners).

Variant 5 : Basically all offers for the self-service service on the motor vehicle, which is to be paid for.

Reference numerals.

1 module, hydraulic
2 power section, electrical
3 control part, electronic
4 feed pump
5 drive motor
6 fluid containers
7 Overfill indicator
8 float indicator
9 minimum fluid level switch
10 measuring mechanism
11 dispensing nozzle
12 full hose valve
13 housing
14 Function display
15 function keyboard
16 interface, electrical
17 interface, electronic
18 interface, hydraulic
19 display device
20 card reader
21 memory
22 replacement container
23 wheels
24 foot valve
25 quick coupling
26 electric motor
27 reciprocating pistons
28 stroke end
29 limit switches
29.1 Limit switch 1
29.2 Limit switch 2
30 4/2-way solenoid valve
31 ring piston counter
32 stroke adjustment device
33 display
34 sight glass
35 lighting device
36 filler neck
37 drain opening
38 drain plug
39 suction port
40 telescopic tube
41 Starting device
42 Emergency stop device
43 moving bracket
44 distribution box
45 conveyor unit
46 plug, electrical
47 overflow valve
48 Output line
48.1 Output line 1
48.2 Output line 2
49 suction line
50 closure
51 collecting tank
52 Air measurement prevention device
53 liquid level
54 transformer
55 fuse, electrical
56 AND (logical element)
57 transistor
58 conduit
59 aperture
60 reusable canisters
61.1 Pump delivery direction 1 (assigned to 62.1 )
61.2 Pump delivery direction 2 (assigned to 62.2 )
62.1 Direction of motor rotation 1
62.2 Direction of motor rotation 2
63 tandem pistons
63.1 Single piston 1
63.2 Single piston 2
64.1 Adjustment screw 1
64.2 Adjustment screw 2
65 check valve
66.1 Pressure line 1
66.2 Pressure line 2
67.1 Hydraulic room 1
67.2 Hydraulic room 2
68.1 Suction line 1
68.1 ′ suction line 1 ′
68.2 Suction line 2
68.2 ′ suction line 2 ′
69.1 Dosing room 1
69.2 Dosing room 2
70 piston rod
71 tandem measuring mechanism

Claims (24)

1. System for the legal delivery of fluids for motor vehicles, consisting of a hydraulic delivery unit, a fluid container, a measuring device, a dispensing device, a power unit and an electronic control, characterized in that
at least one hydraulic module ( 1 ), consisting of a feed pump ( 4 ) with a drive motor ( 5 ), with or without a fluid container ( 6 ) with an electrical overfill indicator ( 7 ), an optical float indicator ( 8 ) and an electrical minimum fluid level switch ( 9 ), a volumetric metering measuring device ( 10 ), a delivery nozzle ( 11 ) with a full hose valve ( 12 ), housed in a housing ( 13 ) with a function display ( 14 ) and keyboard ( 15 ), with at least one electrical ( 16 ), electronic ( 17 ) and hydraulic ( 18 ) interface,
a uniform electrical power unit ( 2 ) with at least one electrical interface ( 16 ) for one or more hydraulic modules ( 1 ),
a uniform electronic control part ( 3 ) with a display device ( 19 ), a card reading device ( 20 ), a memory ( 21 ) and at least one electronic interface ( 17 ) for one or more hydraulic modules ( 1 ) and a power part ( 2 ),
are spatially separated or completely and / or partially combined to form a delivery system for at least one fluid. 2. Dispensing system according to claim 1, characterized in that the feed pump ( 4 ) is a gear pump and its drive motor ( 5 ) is an electric motor ( 26 ). 3. Dispensing system according to claim 1 and / or 2, characterized in that the feed pump ( 4 ) is a piston pump and its drive motor ( 5 ) is a piston-air motor. 4. Dispensing system according to one or more of claims 1 to 3, characterized in that the fluid container ( 6 ) is an exchange container ( 22 ) and with wheels ( 23 ) or the like. Mobile. 5. Dispensing system according to one or more of claims 1 to 4, characterized in that the exchange container ( 22 ) has a hydraulic foot valve ( 24 ) and as a hydraulic interface ( 18 ), a self-locking hydraulic coupling ( 25 ), a filler neck ( 36 ) and one Drain opening ( 37 ) with a drain screw ( 38 ) and a driving bracket ( 43 ). 6. Dispensing system according to one or more of claims 1 to 5, characterized in that the measuring mechanism ( 10 ) has a double-acting and acted upon piston ( 27 ), at its two stroke ends ( 28 ) each have an electrical limit switch ( 29 ) and a hydraulic one 4/2-way solenoid valve ( 30 ). 7. Dispensing system according to one or more of claims 1 to 6, characterized in that the suction nozzle ( 39 ) of the feed pump ( 4 ) is arranged geodetically lower than the foot valve ( 24 ) and the self-locking quick coupling ( 25 ) of the exchange container ( 22 ). 8. Dispensing system according to one or more of claims 1 to 7, characterized in that the measuring mechanism ( 10 ) has an annular piston counter ( 31 ). 9. Dispensing system according to one or more of claims 1 to 8, characterized in that the power section ( 2 ) has an electrical transformer ( 32 ). 10. Dispensing system according to one or more of claims 1 to 9, characterized in that the display device ( 19 ) of the control part ( 3 ) has an electronic display ( 33 ). 11. Dispensing system according to one or more of claims 1 to 10, characterized in that the reading device ( 20 ) is designed for magnetic, chip, punch or optical cards. 12. Dispensing system according to one or more of claims 1 to 11, characterized in that the memory ( 21 ) is designed for the complete recording, storage and return of all data of several dispensing processes of fluids of different modules ( 1 ). 13. Dispensing system according to one or more of claims 1 to 12, characterized in that the electronic interface ( 17 ) is serial or parallel. 14. Dispensing system according to one or more of claims 1 to 13, characterized in that the electric motor ( 26 ) is designed in an explosion protection version. 15. Dispensing system according to one or more of claims 1 to 14, characterized in that the function display ( 14 ) has a sight glass ( 34 ) with a lighting device ( 35 ). 16. Dispensing system according to one or more of claims 1 to 15, characterized in that the functional keyboard ( 15 ) has a hydraulic start ( 41 ) and emergency stop device ( 42 ). 17. Dispensing system according to one or more of claims 1 to 16, characterized in that the fluid container ( 6 ), the overfill indicator ( 7 ) and the fluid level minimum switch ( 9 ) are designed in explosion protection design. 18. Dispensing system according to one or more of claims 1 to 17, characterized in that the dispensing nozzle ( 11 ) is designed as a telescopic tube ( 40 ). 19. Dispensing system according to one or more of claims 1 to 18, characterized in that the measuring mechanism ( 10 ) as a single-acting tandem measuring mechanism ( 71 ) with the single piston 1 ( 63.1 ) and the single piston 2 (63.2) and the piston rod ( 70 ) is trained. 20. Dispensing system according to one or more of claims 1 to 19, characterized in that the electric drive motor ( 5 ) is designed as a rotational direction switchable single-phase asynchronous motor with an operating capacitor or as a three-phase motor. 21. Dispensing system according to one or more of claims 1 to 20, characterized in that the feed pump ( 4 ) has a pressure output of the discharge line 1 ( 48.1 ) and the discharge line 2 ( 48.2 ) independent of the direction of rotation. 22. Dispensing system according to one or more of claims 1 to 21, characterized in that the tandem measuring mechanism ( 71 ), the feed pump ( 4 ), the suction line ( 49 ), the suction lines ( 68.1 , 68.1 ', 68.2 , 68.2 ') and the self-locking quick coupling ( 25 ) are arranged geodetically lower than the foot valve ( 24 ) of the replacement container ( 22 ). 23. Dispensing system according to one or more of claims 1 to 22, characterized in that the relief valve ( 47 ) is formed as an adjustable tandem valve. 24. Delivery system according to one or more of claims 1 to 23, characterized in that the stroke adjustment device ( 32 ) each has a limit switch ( 29.1 ), an adjusting screw ( 64.1 ) and a delivery line ( 48.1 ).