EP1172152A1 - Paint supply system with piggable supply lines for an electrostatic coating device - Google Patents

Abstract

Feed method has a given quantity of coating material moved along a feed line (ZLA,ZLB), providing potential separation, for supplying it to the spray coating head (Z) together with a displacement fluid between two spaced salamanders (M1A,M2A; M1B,M2B). Dosing of the coating fluid at the spray coating head is provided via a dosing pump (PA,PB) in the feedback line (RLA,RLB) for displacement fluid. An Independent claim for a feed system for a spray coating device is also included.

Description

The invention relates to a method for supplying a coating member and a supply system for the particular Series electrostatic coating of workpieces such as for example vehicle bodies according to the preamble of the independent Claims.

In a coating system known from DE 198 30 029 A1 with a supply system of this type for coating of vehicle bodies with frequently changing color material the color materials in the order of the desired Colors introduced into a feed line and through each two pig bodies separated from each other, between them there may be an insulating medium for electrical isolation. The insulating medium can for example consist of cleaning liquid consist.

Furthermore, it is known from DE 197 42 588 A1, the coating material for the serial coating of workpieces to push from a newt to the application organ, whereby the newt in turn from a pressurized one Flushing or other pressure medium is applied. The color material flows through the one required for dosing Pump.

State of the art is also a supply line for electrical conductive coating material for electrical isolation with a to clean reciprocating pig bodies (DE 199 61 271).

The object of the invention is a method and a supply system specify the one that is accurate and as needed during the coating process variable dosage of the material sprayed from the coating member, for example enables and on the other hand less with a color change Rinsing effort in terms of rinsing media and time required as before.

This object is solved by the features of the claims.

In particular, the invention has the advantage that for dosing of the coating material required dosing pump does not need to be rinsed when changing colors as it does not is flowed through by the coating material. Also for them The paint supply line between the pig stations is not a separate one Flushing process required because of the insulating medium and / or the pig bodies are cleaned.

On the embodiment shown in the drawing the invention is explained in more detail.

Fig. 1

ein Farbversorgungssystem für einen elektrostatischen Rotationszerstäuber mit Potentialtrennung; und

Fig. 2

eine zweckmäßige Ausführungsform eines für das System nach Fig. 1 verwendeten Molches.

Show it:

Fig. 1

a paint supply system for an electrostatic rotary atomizer with potential isolation; and

Fig. 2

an expedient embodiment of a pig used for the system of FIG. 1.

1, the color channel 10 of the atomizer Z is over two parallel ink supply circuits A or B to a color changer serving as a color supply device FWA or FWB connected in the usual way. Is between the color channel 10 and the supply circuits A, B. a controlled valve 12A or 12B each switched.

Another color controlled valve 12C is connected to the paint channel 10 of the atomizer Z also for rinsing the atomizer serving detergent system C.

Each of the two ink supply circuits A and B exists mainly from one in the immediate vicinity of the atomizer Z arranged first pig station MS1A or MS1B, one in near the relevant color changer FWA or FWB second pig station MS2A or MS2B, one of the leading to the first pig station Ink supply line ZLA or ZLB and one of the first Pig station leading back to the second pig station Return line RLA or RLB. The feed and return lines each of the two ink supply circuits A and B form a closed circuit, through its entire course an insulating medium can be conveyed through.

Each of the four pig stations mentioned is a double pig station designed to accommodate two pigs each. Everyone Ink supply circuit A, B contains two pigs, with M1A and M2A or M1B and M2B are designated and between the two pig stations can be moved back and forth.

There is a metering pump in each of the return lines RLA and RLB PA or PB switched, the direction of rotation reversible is, so that it is optionally in the opposite direction to the first pig station or convey in the opposite direction to the second pig station can. Between the dosing pump PA and the two pig stations MS1A or MS2A of the ink supply circuit A contains the return line RLA each a controlled valve V4A or V1A. Valves V4B and V1B are controlled in the same way switched into the return line RLB.

The two ink supply circuits A and B have one thing in common Expansion tank 16 for the as a sliding medium serving insulating medium associated with the return lines RLA and RLB connected via a line 14A and 14B, respectively which is controlled by a controlled valve V2A, V3A or V2B, V3B in the parallel arrangement shown on the two Sides of the dosing pump PA or PB to the relevant one Return line RLA or RLB is connected. The expansion tank 16 has a slidable for volume change Piston that can be pressurized with compressed air on its back is.

The detergent system C already mentioned contains one of one Supply container 18, which also has a volume change displaceable pistons to which compressed air can be applied has line 20 leading to the valve 12C. Parallel to the Line 20 is on the container 18 as a potential isolation serving pigable insulating line 22 connected, the first at its end facing the container 16 Pig station 24 and at a source 26 of detergent (e.g. thinner) end facing a second pig station 25 contains.

To explain the mode of operation, let us first assume that the workpiece e.g. a car body, with from to the paint supply circuit A through the valve 12A Paint material is coated. With this state of the system the first newt M1A is at rest in the first Pigging station MS1A. That for painting and for a practical Reserve quantity (still) required paint volume is located in line section 28 between the first pig station MS1A and the second newt M2A, which is in accordance with the the coating volume decreasing on the first pig station too moved. The rest of the supply line ZLA between the rear of the newt M2A and the second newt station MS2A and the whole connected to the feed line RLA return lines are filled with the insulating medium, that of the dosing pump PA with the current one Paint requirements corresponding, usually variable Delivery rate towards the second pig station MS2A and from there is pumped into the supply line ZLA and as a push medium via the pig M2A that located in line section 28 Presses paint material into the atomizer Z. in this connection Valves V1A and V3A are open while the valves V2A and V4A are closed. The PA metering pump is therefore fed from the expansion tank 16 during the coating, i.e. the amount of paint applied is by means of a sliding medium replaced from the expansion tank 16.

The atomizer Z and the paint material in the line section 28 are under high voltage during the coating operation, while the color changers FWA and FWB are constantly grounded. The one that is particularly necessary with low-resistance paint material Potential isolation takes place via supply circuits A and B. The required hose length of the lines between the two pig stations correspond to the maximum required Paint volume (including reserve quantity) plus the double the required insulation distance, each by line sections filled with insulating medium initially between the paint column introduced at the second pig station and the first pig station, then between the paint column and two newt stations and finally between the second pig station and the paint column are formed, wherein the latter insulating section during the coating is getting bigger.

As the insulating and metering the charge flow at the atomizer Sliding medium can be any flowable, preferably liquid medium can be used that is electrical non-conductive, compatible with paint, as incompressible as possible and is suitable for delivery by a dosing pump.

While atomizer Z is supplied from circuit A, is the parallel supply circuit B ready for pressing the Paint material for a subsequent coating process, who can join immediately and without wasting time if not an interim rinse because of a color change of the atomizer is required.

At the initial state of the system for preloading circuit B the two newts of this circle are in the second Newt station MS2B. The entire paint supply circuit B is included the insulating medium serving as a sliding medium. By Open one of the color control valves F1, F2, Fx of the color changer FWB also flows through the desired color varnish open valve 30 of the pig station MS2B between the two Newts M2B and M1B while starting the dosing pump PB and opening the valves V2B and V4B with the valve closed V1B insulating medium in a corresponding volume before the Pig M1B removed and pumped into the expansion tank 16 becomes. The quantity of insulation medium removed is therefore determined by the flowing paint replaced while the newt M1B moved towards the first pig station MS1B. The inflowing The amount of colored lacquer is adjusted accordingly by the dosing pump PB measured their delivery rate, and if the desired Volume is filled, the color control valve of the Color changer FWB, valve 30 and valve V2B closed, while valve V1B is opened and valve V4B remains open. As a result, the newt M2B also sets in Direction to the first pig station MS1B in motion. The between required amount of paint clamped in the two pigs becomes an atomizer due to the flow rate of the insulating medium Z transported. The pressing process is finished when the the first pigs M1B have reached the pig station MS1B. The behind this pig of paint ready is over the atomizer Z placed on high voltage potential. The one for electrical isolation the necessary insulation gap exists at this time between the newt M2B and the second newt station MS2B.

If there is a color change between two coating processes, so here in the preloaded supply circuit B provided coating material has a different color than the coating material previously taken from circle A, is for example in the coating break between the Removing an already painted workpiece and feeding it of the next workpiece (body gap) the high voltage switched off and the paint channel 10 of the atomizer rinsed, in typical rotary atomizers over its main needle. The detergent is through line 20 of the detergent system C by moving the piston of the supply container 16 fed to the atomizer Z. The pig of the detergent system C is in the first during coating operation Pig station 24 and is flushed by the piston of the supply container 16 into the second pig station 25 pressed. The container 16 can then be refilled and then the pig with compressed air into its first pig station 24 be pushed back, so that again the required Isolation distance between the pig stations 24 and 25 exists.

A major advantage of the invention is that when changing colors only the areas of the color changer FWA or FWB, the newt stations MS1A, MS2A or MS1B, MS2B and the Atomizer Z need to be rinsed.

Already while rinsing the atomizer Z or if none Flushing process is required during the coating operation with paint material removal from the circle B begins in Circle A returns the two pigs M1A and M2A with the any remaining paint reserve between them to the second pig station MS2A. For this purpose the direction of rotation the PA metering pump vice versa. The pump now delivers open valves V1A and 4A and closed valves V2A and V3A towards the newt station MS1A and from there in Direction to the second newt station MS2A until finally in circuit A the initial state for preloading the circuit again A results in the manner described above for circle B.

After the rinsing process, the previously preloaded circuit B the lacquer material is pressed over the main needle of the atomizer and in the manner already described for circle A. be sprayed. So while the newt M1B is in the Pig station MS1B is located, the pig M2B through the insulating medium promoted towards atomizer Z. The dosage of the paint material acted upon by the pig again via the metering of the insulating medium by the metering pump PB, with the valves V1B and V3B opened and the Valves V2B and V4B are closed and the applied Paint quantity again through the sliding medium from the expansion tank 16 is replaced.

The aforementioned return transport of the two newts of the district A in its second pig station MS2A is during the coating operation of circle B completed. The returned Paint reserve quantity can be in the second pig station MS2A a valve 32 (shown in MS2B) and a return line disposed of or in a conventional manner in the usual ring line the system will be pigged back. Then will the color changer FWA rinsed when a new color is selected has been. If the same color is needed again, the process flow can Immediately start preloading circuit A.

If the color changer has to be rinsed, this can also be done already take place as soon as the required amount of color in the associated feed line is located.

To secure the necessary for electrical isolation Isolation gaps are for each of the two paint supply circuits A and B each have two initiators IN1A and IN2A and IN1B and IN2B provided as shown in one of the respective Minimum insulation distance corresponding distance from the two pig stations are arranged and for example on the appearance of the newts in the relevant areas appealing Generate monitoring signals. If you have more similar Initiators can be positioned variably in front of the entrance of the first Arranging the pig station MS1A or MS1B is one Self-optimization of the paint reserve quantity possible, i.e. this Quantity can depend on what results in the coating practice absolutely necessary minimum can be reduced.

As already mentioned, the insulating medium is said to be electrical non-conductive, incompressible and compatible with paints Be a sliding medium. In cases where there is conductivity change the insulation medium used over time can, especially by mixing with the paint material, continuous or periodic monitoring of the Insulating medium useful with regard to its conductivity his. This can be done by direct conductivity measurement or indirectly, for example by measuring the turbidity of the insulating medium. When a critical value is reached the insulation medium can be removed from the system and against fresh material can be exchanged. This change can be meaningfully connected to a rinsing process.

Known in the system described here can Pigging bodies are used when these cover the inner walls of the Strip off the respective hose or pipe without leaving any residue. To achieve an additional cleaning effect but it should be useful in circles A and B and / or in To use the C Newts flushing system in a tandem arrangement where the pig between the front and rear sealing edges a space open to the inner walls of the line to take up a Line detergent contains detergent. That for hose cleaning in circles A and B between the sealing edges z. B. the pigs M2A and M2B transported detergent can for example filled in the second pig station MS2A or MS2B and later in one of the two newt stations of the relevant circle can be rinsed out again.

A convenient embodiment of such a pig (e.g. of the newt M2B in FIG. 1) in tandem is in FIG. 2 shown. Accordingly, the tandem pig essentially exists of two preferably the same, generally cylindrical Pig parts 2 and 2 ', respectively, which are made by a relatively thin flexible Link 4 in a defined by the connecting glid Distance A are connected. In principle can there are two pigs of a known type which are used for Mechanical formation of a space with a defined filling volume are interconnected. That from, for example Stainless steel wire or rod made of elastomeric material Link 4 is on the mutually facing End faces of the pig parts 2, 2 'attached or with them made in one piece. Each pig part 2 or 2 'has a cylindrical Middle part 6 and at the ends of each a peripheral edge part 7 or 8, the one over the entire circumference at the Inner wall of the line L adjacent sealing edge or sealing or Wiping lip has, as is known in the case of newts is. Inside the middle part 6 of each of the two pig parts 2, 2 'there may be a permanent magnet M or M' on which the above-mentioned initiators for pig detection and generation of signals, e.g. moving the newt, can address. The one of the two pig parts 2, 2 ' The space 9 formed has that between the facing one another End faces of the axially inner peripheral edge parts 8 or 8 ', the circumference of the connecting member 4 and the inner wall of the Line L defines the filling volume for that of the pig the line L flushing or cleaning medium to be pushed. at an outer diameter corresponding to the inner diameter of the line L. D the sealing edge on the pipe or lip of the parts 7, 8 and an outer diameter d of Link 4 should be significantly smaller than D, in particular less than half as large, while the distance A is preferably not greater than 10 times the diameter D.

There are also advantages if you instead of yourself expedient pigs of the system described other media separators used and the coating material the feed lines feeds via different valve stations or extracts. Furthermore, the reduction achievable by the invention can the rinsing effort required for a color change can also be advantageous in coating systems which have no electrical isolation between the atomizer and a color changer or the like is necessary.

Insofar as it is necessary for electrical isolation the line groups described (at least by piggable hoses formed lines) made of electrical non-conductive material.

Claims (15)

Method for supplying a coating member (Z) for the series coating of workpieces such as vehicle bodies with coating material, which comes from a supply device (FWA, FWB) to the coating member (Z) through a feed line (ZLA, ZLB), which is fed between one in the The first pig station (MS1A, MS1B) located near the coating member (Z) and a second pig station (MS2A, MS2B) near the supply device (FWA, FWB),
wherein the coating material is conveyed between the pigs (M1A, M2A; M1B, M2B) in the predetermined volume for a coating process together with a separate medium through the feed line (ZLA, ZLB),
in particular for electrostatic coating with low-resistance coating material, which is fed from an earthed supply device (FWA, FWB) to the coating element (Z) which is connected to high voltage during coating and is conveyed with an insulating medium through the supply line (ZLA, ZLB),
characterized in that the coating material is conveyed to the coating member (Z) by a metering pump (PA, PB) through which only the separate medium serving as a sliding medium flows. A method according to claim 1, characterized in that the pushing medium is conveyed from the metering pump (PA, PB) through the feed line (ZLA, ZLB) towards the first pig station (MS1A, MS1B) and from there through to the second pig station ( MS2A, MS2B) leading return line (RLA, RLB) is returned. A method according to claim 1 or 2, characterized in that when the coating material is introduced between the two pigs (M1A, M2A; M1B, M2B) a corresponding volume of the pushing medium is conveyed into an expansion tank (16). Method according to one of the preceding claims, characterized in that the supply and return lines of the supply circuit (A, B) are filled with insulating medium,
that the coating material is introduced at the second pig station (MS2A, MS2B) between the two pigs (M1A, M1B; M2A, M2B),
that the coating material enclosed between the pigs is conveyed through the feed line (ZLA, ZLB) until the front pig (M1A, M1B) in the conveying direction reaches the first pig station (MS1A, MS1B), at which point the length of the line section filled with insulating material sufficient between the rear pig (M2A, M2B) and the second pig station (MS2A, MS2B) for potential separation between the coating member (Z) and the supply device (FWA, FWB),
and that the coating material is then conveyed from the metering pump (PA, PB) via the insulating medium and the rear pig (M2A, M2B) to the coating member (Z), while the front pig (M1A, M1B) in the first pig station (MS1A, MS1B) remains. Method according to one of the preceding claims, characterized in that the two pigs (M1A, M2A; M1B, M2B) from the metering pump (PA, PB) conveying the pushing medium with the direction of rotation reversed in relation to the coating operation through the feed line (ZLA, ZLB) into the second pig station (MS2A, MS2B). Method according to one of the preceding claims, characterized in that during the coating of a workpiece with coating material from the supply line (ZLA) of a first supply circuit (A), a second supply circuit (B) with similar supply and return lines (ZLB, RLB) and pig stations ( MS1B, MS2B) and a metering pump (BB) is prepared for a subsequent coating process, the coating medium of the second supply circuit (B) being conveyed through its feed line (ZLB) until the front pig (M1B) has reached its first pig station (MS1B) , Method according to one of the preceding claims, characterized in that the metering pump (PA, PB) conveys the sliding medium with a throughput which changes during the coating in accordance with the amount of coating material currently required in each case. Method according to one of the preceding claims, characterized in that a pig (M1A, M2A, M1B, M2B) is used which between the front and rear sealing edges (8, 8 ') an intermediate space (9) open to the inner walls of the conduit for receiving a die Line cleaning detergent contains, and that the detergent is filled in one of the pig stations (MS2A, MS2B, 24, 25) in the space (9) and washed out after use in one of the pig stations. Method according to one of the preceding claims, characterized in that the electrical conductivity of the insulating sliding medium is measured or determined continuously or periodically and the sliding medium is exchanged for fresh material when a predetermined conductivity value is exceeded. Supply system for the in particular electrostatic series coating of workpieces such as vehicle bodies with, in particular, low-resistance coating material, which comes from a supply device (FWA, FWB) to the coating member (Z) through a feed line (ZLA, ZLB) which is fed between one in the vicinity of the coating member (Z) the first pig station (MS1A, MS1B) and a second pig station (MS2A, MS2B) located near the supply device (FWA, FWB),
characterized in that the end of the feed line (ZLA, ZLB) located at the first pig station (MS1A, MS1B) is connected to the end of the feed line located at the second pig station (MS2A, MS2B) by a return line (RLA, RLB) which contains a metering pump (PA, PB) through which only a separate medium serving as a sliding medium for the coating material flows. Supply system according to Claim 10, characterized in that a line (14A, 14B) leading to an expansion tank (16) for the sliding medium branches off from the return line (RLA, RLB). Supply system according to claim 11, characterized in that the line (14A, 14B) leading to the expansion tank (16) via a controllable valve (V2A, V3A, V2B, V3B) on both sides of the metering pump (PA, PB) to the return line (RLA, RLB) is connected, and that the return line contains controllable valves (V1A, V4A, V1B, V4B) between the metering pump and the two scraper stations (MS1A, MS2A, MS1B, MS2B). Supply system according to one of claims 10 to 12, characterized in that two identical supply circuits (A, B), each with the two pig stations (MS1A, MS2A; MS1B, MS2B), the supply and return lines (ZLA, RLA; ZLB, RLB) and the dosing pump (PA, PB) are connected in parallel to the coating element (Z). Supply system according to claim 13, characterized in that a common expansion tank (16) for the insulating medium is connected to both supply circuits (A, B). Supply system according to one of claims 10 to 14, characterized in that a separate detergent system (C) is connected to the coating member (Z) for rinsing during a color change, which has a detergent supply line (22) which can be pigged between two pig stations (24, 25) as an insulating section for potential isolation during the coating process.

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