EP3046683A1

EP3046683A1 - Application system and corresponding application method

Info

Publication number: EP3046683A1
Application number: EP14758784.4A
Authority: EP
Inventors: Manuel STUPP
Original assignee: Duerr Systems AG
Current assignee: Duerr Systems AG
Priority date: 2013-09-16
Filing date: 2014-09-01
Publication date: 2016-07-27
Also published as: US10076766B2; CN105555419A; MX2016003366A; DE102013015313A1; RU2665482C2; WO2015036096A1; RU2016114533A; US20160221024A1; CN105555419B; BR112016004645B1

Abstract

The invention relates to an application system and to an application method for applying a fluid (e.g., polyvinyl chloride, adhesive, paint, lubricant, preservation wax, sealant, or PUR foam) to a component (e.g., motor vehicle body component). The application system comprises a flow measuring cell (3) for measuring a mass flow of the fluid and for producing a measurement signal corresponding to the measured mass flow and an evaluating unit (7) for determining the mass flow from the measurement signal of the flow measuring cell (3) in accordance with a measuring specification. The invention further relates to a calibrating device (8) for automatically calibrating the measuring specification of the evaluating unit (7).

Description

DESCRIPTION

Application system and corresponding application method

The invention relates to an application system and a speaking application method for applying a fluid (for example PVC: polyvinyl chloride) to a component on a motor vehicle body component).

In modern coating systems for coating motor vehicle body components, the material to be applied (eg PVC) is conveyed by a supply of material to an applicator, which applies the fluid to the component. Between the material supply and the applicator in this case a flow cell is arranged, which may be embodied for example as a spindle measuring cell and corresponding to the funded from the material supply to the applicator fluid idstrom generates a corresponding volume flow signal. The problem here is the fact that the relationship between the output from the flow cell flow signal on the one hand and the actual volume flow on the properties of the pumped fluid depends, which makes a corresponding calibration required. So far, this calibration of the flow cell is done manually by the dispensed from the applicator fluid is dispensed during calibration in a measuring cup, wherein the volume flow signal of the measuring cell is measured. From the known volume of the measuring cup and the measured values of the flow measuring cell, a measurement instruction can then be derived in order to calculate from the output signal of the flow measuring cell the actually conveyed volume flow of the fluid. The disadvantage of this manual calibration method is first the fact that the calibration must be performed by hand, which is prone to errors and is associated with additional effort. In practice, the fluid properties of the fluid also change due to, for example, a change in temperature or a batch change, which actually necessitates recalibration, which does not usually occur. The inadequate calibration therefore often leads in practice to a deviation between the set amount and the actual amount of the applied fluid.

Furthermore, it should be noted to the prior art. DE 10 2007 053 073 A1, DE 10 2006 021 623 A1 EP 2 185 293 B1 and EP 1 854 548 A1. These publications likewise disclose an application system with a flow measuring cell and an evaluation unit, wherein the evaluation unit determines from the measurement signal of the flow measuring cell according to a measurement specification the mass flow (volume flow or mass flow) flowing through the flow measuring cell. In addition, these documents disclose that the application system can be calibrated. However, in this case the measurement specification in the evaluation unit is not calibrated, but rather the relationship between the mass flow through the flow measuring cell on the one hand and the pressure and flow conditions downstream downstream of the flow measuring cell directly on the applicator. So lies between the flow cell and the applicator usually a longer hose, so that the pressure and flow conditions on the flow cell usually do not reflect the exact pressure and flow conditions on the applicator, but are distorted, for example, by breathing tubing. The stored in the evaluation unit measurement rule is thus not calibrated, but remains unchanged. As part of the calibra- Only the relationship between the flowing through the flow cell mass flow on the one hand and the pressure and flow conditions of interest on the applicator on the other calibrated. A change in the measuring process ^¬ maintaining the flow measuring line (for example, due to a change of temperature or viscosity of the fluid) can thus not be considered as part of the calibration, resulting in measurement errors.

The invention is therefore based on the object to improve the calibration accordingly.

This object is achieved by an application system according to the invention or an inventive application method according to the subsidiary claims.

The invention provides that the calibration of the measurement specification for the flow cell is not done manually, but automatically by a calibration device that is integrated into the application system.

The application system according to the invention has, in accordance with the prior art, a flow measuring cell, through which the fluid to be applied flows and generates a measurement signal in accordance with the flow rate of the fluid. For example, the mass flow may be the volume flow or the mass flow of the fluid.

However, the term of a flow measuring cell used in the context of the invention is to be understood generally and not limited to mass flow sensors in which the mass flow to be measured (volume flow or mass flow) flows through the measuring sensor itself. Rather, the term of a flow measuring cell also includes such types of mass flow sensors where the mass flow to be measured flows only through a line, wherein the flow measuring cell measures the flowing through the lines mass flow. In addition, the application system according to the invention, in accordance with the prior art, an evaluation unit which determines from the measurement signal of the flow cell according to a predetermined measurement specification, the flow rate flowing through the flow measuring cell or through the conduit. The measurement specification of the evaluation unit is therefore intended to reproduce the relationship between the measurement signal of the flow measurement cell on the one hand and the flow rate measured by the flow cell on the other hand. The evaluation unit thus preferably determines the mass flow which flows through the flow measuring cell itself or at least the mass flow which flows directly through the conduit at the flow measuring cell. It should be distinguished in the preferred embodiment of the invention, the flow that flows through a line elsewhere in the application system, for example, immediately before the applicator. Namely, the calibration according to the invention is intended to take account of a change in the measuring behavior of the flow measuring cell and not a change of another component (eg a flexible, breathing tube between the flow measuring cell and the applicator) of the application system.

In a preferred embodiment of the invention, the evaluation unit has a computing unit which calculates the mass flow according to a predetermined calculation rule from the measurement signal of the flow cell. The evaluation unit can therefore be implemented as hardware or as software in a digital computer. The application system according to the invention now differs from the prior art by an integrated calibration device for automatic calibration of the measurement specification of the evaluation unit.

In the preferred embodiment of the invention, the known from the prior art measuring cup for manual calibration is replaced by a receptacle into which the fluid is dispensed during calibration, wherein the measurement signal of the flow cell is measured as part of the material delivery into the receptacle.

Moreover, in accordance with the prior art, the applicator of the invention preferably has an applicator (e.g., nozzle, nebulizer, etc.) to apply the fluid.

Furthermore, the application system according to the invention preferably also comprises, in accordance with the prior art, a material supply for conveying the fluid through the flow measuring cell to the applicator, wherein the material supply usually comprises a pump (for example a metering pump).

The application system according to the invention is preferably characterized by a first valve arrangement, which makes it possible to connect the flow measuring cell or the line downstream of the flow measuring cell optionally with the applicator or with the receptacle.

In the normal coating operation, the first valve assembly then connects the flow cell downstream of the flow cell to the applicator to apply the fluid via the applicator. On the other hand, during the actual calibration, the first valve arrangement connects the flow measuring cell or the line downstream behind the flow measuring cell to the receiving container in order to guide the pumped fluid into the receiving container.

The calibration device according to the invention is connected to the flow measuring cell in order to be able to detect the measuring signal of the flow measuring cell during the calibration. In addition, the calibration device is connected to the evaluation unit in order to calibrate the evaluation unit of the measurement specification can.

In a variant of the invention, the receptacle has a variable receiving volume. In this variant, a measuring member is additionally provided to measure during the filling of the receptacle with the fluid, the current recording volume. In this variant, the Kalibriereinrich device is connected on the input side both with the flow measuring cell and with the measuring member in order to take into account the relationship between the measurement signal of the flow cell on the one hand and the actual delivery volume on the other.

In another variant of the invention, the Aufnahmebe container, however, on a known receiving volume and be completely filled in the calibration with the fluid flowing through the flow measuring cell be the calibration. The calibration determines the measurement specification then depending on the known receiving volume of the receptacle on the one hand and the total volume flow, which was measured by the flow cell. In this variant of the invention, the receiving volume of the receptacle is therefore preferably constant (non-variable). It exists in this variant jedoc also the possibility that the receiving volume of the receptacle is variable, but is kept constant during the calibration process.

In addition, the application system according to the invention preferably has a fluid pressure regulator, which is arranged between the material supply and the flow measuring cell in order to be able to regulate the fluid pressure. For example, the fluid pressure upstream of the flow measuring cell can be regulated to a predetermined desired value.

Furthermore, the application system according to the invention preferably has an actuator to adjust the receiving volume of the receptacle. For example, the receptacle may be formed as a piston-cylinder arrangement, wherein the piston position of the receptacle determines the receiving volume. The drive of the piston, for example, pneumatically done, but also another type of drive is possible, such as an electric motor drive.

In the variant of the invention described above with a variable receiving volume of the receiving container, the piston can be moved continuously during filling of the receiving container, wherein a piston position sensor continuously measures the current level. From the output signal of the piston position sensor on the one hand and the measuring signal of the flow measuring cell, the measuring instructions can then be derived within the scope of the calibration.

In addition, the application system according to the invention preferably comprises a second valve arrangement for connecting the receptacle to the material supply. This offers the advantage that the fluid conducted into the receptacle during calibration returns to the material supply can be returned and therefore does not have to be disposed of.

Furthermore, the application system according to the invention preferably comprises a third valve arrangement, which between the

Flow measuring cell and the first valve arrangement is arranged.

It should also be mentioned that the actuator for adjusting the receiving volume of the receiving container preferably has a compressed air source and a fourth valve arrangement, wherein the fourth valve arrangement controls the compressed air flow from the compressed air source to the receptacle. This offers the possibility to be able to empty the receptacle controlled, for example, in the material supply back. For example, the compressed air source may displace a piston of a piston-and-cylinder arrangement so that the fluid in the cylinder (receptacle) is pushed out of the cylinder.

It has already been briefly mentioned above that the flow rate measured by the flow measuring cell is preferably a volume flow and thus represents the delivery volume per unit time. Alternatively, however, there is also the possibility that the flow rate measured by the flow measuring cell is a mass flow, which thus represents the delivered mass per unit time.

It should also be mentioned that the first valve arrangement between the flow measuring cell and the applicator is preferably a 5/2-way valve.

Furthermore, it should be mentioned that the invention is not limited to the invention described above Application equipment. Rather, the invention also claims protection for a corresponding application method in which the measurement specification for determining the flow rate from the measurement signal of the flow measuring cell is automatically calibrated.

In a variant of the invention, the receptacle has a variable receiving volume and is filled during calibration with the fluid flowing through the flow measuring cell. During filling, the variable receiving volume of the receptacle is preferably continuously measured, i. the current level of the receptacle. In addition, the flow through the flow cell during filling of the receptacle is measured during calibration. The measurement specification can then be determined, for example, in the form of a characteristic curve from the measured filling level (receiving volume) of the receiving container on the one hand and the measuring signal of the flow measuring cell.

In another variant of the invention, the Aufnahmebe container, however, completely filled with a known Aufnahmevolu men, in which case the measuring signal of the flow cell is then measured after filling the Aufnahmebehäl age. From the known receiving volume of the receptacle on the one hand and the measurement signal of the flow cell can also be derived as the measurement rule, which reproduces the relationship between the measurement signal of the flow cell and the actual flow rate. This variant of the invention allows a waiver of an additional measuring element to measure the current level of Aufnahmeb container.

Preferably, the fluid flow from the material supply during calibration is completely inserted into the receptacle. directs, so that the application of the fluid through the applicator is then interrupted during the calibration.

In addition, the receptacle is preferably completely emptied prior to filling in the calibration, this emptying can for example be done pneumatically.

Finally, it should be mentioned that the calibration of the measuring instructions can be time-controlled in each case at specific time intervals. For example, the calibration can be carried out at intervals of one hour, one day or one week. Alternatively or additionally, there is the possibility that the calibration is started manually, for example, when the fluid is changed.

Furthermore, there is also the possibility that the calibration is carried out in each case between the machining of two components, for example between the coating of two consecutive motor vehicle body series.

In the preferred embodiment of the invention, the application system applied polyvinyl chloride (PVC). However, the inventive principle of an automatic calibration is also suitable for the application of other fluids, such as adhesives (one-component adhesives or

Two-component adhesives), paints, lubricants (eg greases, oils), preservative wax, sealants (eg when applying sealing beads) or PUR foam (PUR: polyurethane). Other advantageous developments of the invention are characterized in the subclaims or are explained in more detail below together with the description of the preferred embodiment of the invention with reference to FIGS. Show it: Figure 1 is a schematic representation of an application system according to the invention with an integrated calibration device, and

2 shows the application method according to the invention with an automatic calibration in the form of a

Flowchart.

1 shows in schematic form an embodiment of an application system according to the invention with a material supply 1, a material pressure regulator 2, a flow measuring cell 3, a controllable valve 4, a 5/2-ege- valve 5 and finally an applicator 6. The material supply 1 promotes the fluid to be applied (eg PVC) through the material pressure regulator 2, the flow cell 3, the valve 4 and the 5/2-way valve 5 to the applicator 6, which then applies the fluid to a component (eg motor vehicle body component).

The flow measuring cell 3 measures the volume flow conveyed from the material supply 1 to the applicator 6 and outputs a corresponding electrical measurement signal to an evaluation unit 7.

The evaluation unit 7 then calculates the actual volume flow from the electrical measurement signal of the flow measuring cell 3 in accordance with a predetermined measurement specification.

The assignment between the electrical measuring signal of the flow measuring cell 3 on the one hand and the resulting volume flow on the other hand is predetermined by a calibration device 8 in the form of a characteristic curve. During a calibration process, the 5/2-way valve 5 redirects the fluid flow from the material supply 1 into a receptacle 9, wherein a measuring element 10 measures the current fill level of the receptacle 9 and forwards a corresponding measurement signal to the calibrating device 8. During calibration, the calibration device 8 thus obtains pairs of values from the electrical measurement signal of the flow measurement cell 3 in accordance with the measured volume flow on the one hand and the measurement signal measured by the measurement element 10 in accordance with the current acquisition volume of the receptacle 9 on the other hand. From these pairs of values, the calibration device 8 calculates a characteristic which is then stored in the evaluation unit 7 as a measurement instruction and during normal application operation determines the calculation of the volume flow from the measurement signal of the flow measurement cell 3.

In addition, the application system according to the invention has a compressed air source 11, which is connected via a valve 12 to the receptacle 9 and allows emptying of the receptacle 9. Thus, the receptacle 9 is formed as a piston-cylinder arrangement, wherein the piston position of the piston in the receptacle 9 reflects the current receiving volume. When the valve 12 is opened, compressed air flows into the receptacle 9 and displaces therein a piston, so that the fluid contained in the receptacle 9 is pushed out of the receptacle 9.

In addition, the receptacle 9 is connected via a valve 13 with the material supply. This connection makes it possible to push the fluid accumulated in the receptacle 9 during calibration back into the material supply 1, which enables reuse of this fluid. Finally, the invention also includes a control unit 14, which controls the calibration device 8, the valves 4, 12, 13 and the 5/2-way valve. The control unit 14 can perform an automatic calibration of the evaluation unit 7 in this way. The carrying out of these calibrations can take place, for example, at specific time intervals or between the coating of two successive components. In addition, the calibration can also be started manually, if necessary.

In a variant of the operation of the application system according to the invention described above, the receptacle 9 is completely filled during calibration, so that the known maximum receiving volume of the receptacle 9 then in conjunction with the flow cell 3 measured by the flow rate the functional relationship between the measurement signal of the flow cell. 3 on the one hand and the resulting volume flow on the other. In contrast, in another variant of the invention, the receptacle 9 is continuously filled during calibration, wherein the measuring member 10 continuously measures the current recording volume. In this way, a multiplicity of value pairs can be measured, which allows a more accurate calibration.

The calibration method according to the invention will now be described below with reference to the flowchart in FIG.

In a first step Sl, the receptacle 9 is first emptied into the material supply 1. For this purpose, the valves 12, 13 are controlled by the control unit 14 so that they open. The compressed air source 11 then controls the piston in the receptacle 9 so that the fluid contained in the receptacle 9 is pushed out of the receptacle 9. The fluid pushed out of the receptacle 9 is then pressed back into the material supply 1 via the valve 13.

In a second step S2, a fluid pressure is then established between the material supply 1 and the applicator 6.

In this case, the valves 12 and 13 are closed. Furthermore, the valve 4 between the flow cell 3 and the 5/2-way valve is closed to allow the pressure build-up.

After this pressure build-up, the filling container 9 is then filled via the opened valve 4 and the 5/2-way valve 5 in a step S3. The flow measuring cell 3 continuously measures the volume flow and outputs a corresponding electrical measuring signal to the calibrating device 8. In addition measures the measuring member 10 while filling the receptacle 9 continuously the current recording volume of the recording volume 9 and outputs a corresponding measurement signal to the calibration device. 8

The calibration device 8 then determines in a step S4 a characteristic curve from the value pairs of the electrical measuring signal of the flow measuring cell 3 on the one hand and the measuring signal of the measuring element 10 on the other hand.

This characteristic curve is then stored as a measurement instruction in a step S5 in the evaluation unit 7 and serves during the normal application operation to calculate the volume flow from the electrical measurement signal of the flow measurement cell 3. The invention is not limited to the preferred embodiment described above. Rather, a variety of variants and modifications are possible, which also make use of the concept of the invention and therefore fall within the scope. In particular, the invention also claims protection of the subject matter and the features of the subclaims independently of the claims referred to.

List of reference numbers:

1 material supply

2 material pressure regulator

3 flow cell

4 valve

5 5/2-way valve

6 applicator

7 evaluation unit

8 calibration device

9 receptacles

10 measuring element

11 compressed air source

12 valve

13 valve

14 control unit

Claims

1. application system for the application of a fluid, in particular polyvinyl chloride, adhesive, paint, lubricant, preservative wax, sealant or PUR foam, on a component, in particular on a motor vehicle body component, with

a) a flow measuring cell (3) for measuring a flow rate of the fluid and for generating a measurement signal corresponding to the measured flow rate, and

b) an evaluation unit (7) for determining the quantity flow in accordance with a measurement instruction from the measurement signal of the flow measurement cell (3),

marked by

c) a calibration device (8) for automatically calibrating the measurement specification of the evaluation unit (7).

2. Application system according to claim 1,

marked by

a) an applicator (6) for applying the fluid, b) a material supply (1) for conveying the fluid through the flow measuring cell (3) to the applicator

(6),

c) a receptacle (9) for receiving the by

Flow measuring cell (3) flowing fluid during calibration, and

d) a first valve arrangement (5) for controllably connecting the flow measuring cell (3) to the receptacle (9) in order to guide the fluid flowing through the flow measuring cell (3) into the receptacle (9), e) wherein the calibration device (8) is connected to the flow measuring cell (3) and calibrates the measurement specification of the evaluation unit (7) as a function of the measurement signal of the flow measuring cell (3).

3. Application system according to claim 2,

characterized,

a) that the receptacle (9) has a variable receiving volume,

b) that a measuring member (10) is provided for measuring the

Recording volume of the receptacle (9) and for generating a measurement signal corresponding to the measured recording volume, and

c) that the calibration device (8) is also connected to the measuring element (10) and calibrates the measuring specification of the evaluation unit (7) as a function of the measuring signal of the flow measuring cell (3) and in dependence on the measuring signal of the measuring element (10).

4. Application system according to claim 2,

characterized,

a) that the receptacle (9) has a known receiving volume and in the calibration is completely filled with the fluid flowing through the flow cell (3) fluid, and

b) that the calibrating device (8) calibrates the measuring specification of the evaluation unit (7) as a function of the known receiving volume of the receiving container (9) and in dependence on the measuring signal of the flow measuring cell (3).

5. Application system according to one of claims 2 to 4, characterized by

a) a fluid pressure regulator (2) between the material supply supply (1) and the flow measuring cell (3) for controlling the fluid pressure, in particular with an adjustable desired value of the fluid pressure, and / or

b) an actuator (11, 12) for adjusting the receiving volume of the receptacle (9), in particular with a pneumatic drive.

6. Application system according to one of claims 2 to 5, characterized

a) that a second valve arrangement (13) is provided for the controllable connection of the receptacle (9) with the material supply (1) in order to empty the receptacle (9) to the material supply (1), and / or

b) that a third valve arrangement (4) between the

Flow measuring cell (3) and the first valve assembly (5) is arranged, and / or

c) that the actuator (11, 12) for the receptacle

(9) a compressed air source (11) and a fourth valve arrangement (12) between the compressed air source (11) and the receptacle (9) for controllably emptying the receptacle (9).

7. Application installation according to one of the preceding claims, characterized:

a) that the mass flow rate measured by the flow cell (3) is a volume flow, and / or

b) that the first valve arrangement (5) has a 5/2-way valve.

8. Application method for the application of a fluid, in particular polyvinyl chloride, adhesive, paint, lubricant, preservative wax, sealant or PUR foam, on a component, in particular on a Kraftfahrzeugkosseriebau- part, with the following steps:

a) conveying the fluid by means of a material supply (1) to an applicator (6),

b) application of the fluid through the applicator (6), c) measuring a mass flow of the fluid by means of a

Flow measuring cell (3) between the material supply (1) and the applicator (6), wherein the flow cell outputs a measuring signal representing the flow rate of the fluid,

d) determining the mass flow of the fluid from the measuring signal of the flow measuring cell (3) according to a measuring instruction,

e) calibrating the measurement specification,

characterized,

f) that the measurement instruction is calibrated automatically by a calibration device (8).

9. Application method according to claim 8, characterized by the following steps for calibrating the measuring instruction: a) filling a receiving container (9) with a variable receiving volume with the fluid flowing through the flow measuring cell (3),

b) measuring the variable receiving volume of the receptacle (9) when filling the receptacle (9), c) measuring the flow through the flow cell

(3) during filling of the receptacle (9),

d) Determining the measurement specification as a function of the measured values of the mass flow and the receiving volume of the receptacle (9) during filling of the receptacle (9).

10. Application method according to claim 8, characterized by the following steps for calibrating the measurement specification: a) Completely filling a receiving container (9) with a known receiving volume with the fluid flowing through the flow measuring cell (3),

b) Measuring the mass flow through the flow cell

(3) during filling of the receptacle (9),

c) determining the measurement specification as a function of the known receiving volume of the receiving container (9) and the measured value of the mass flow during filling of the receptacle mebehälters (9).

11. Application method according to claim 8 or 9,

characterized,

a) that the fluid flow from the material supply (1) during calibration is completely passed into the on Ahmebehälter (9), and / or

b) that the application of the fluid through the applicator

(6) for the calibration is interrupted, and / or c) that the receptacle (9) before filling in the

Calibration is completely emptied, and / or d) that the receptacle (9) pneumatically emptied

becomes .

12. Application method according to one of claims 8 to 10, characterized

a) that the calibration of the measurement instruction is timed at specific intervals, and / or b) that the calibration is started manually, and / or c) that the calibration is performed in each case between the processing of two components.