EP1045732B1 - Device for isolating an electro-conductive flowing medium - Google Patents

Abstract

Disclosed are a method and a device for isolating an electro-conductive flowing medium with different electrical potential on two points (13 and 15) along the flow path in a potential separation device. The invention is characterized in that the electro-conductive flowing medium is conveyed in the interior (18') of a freely projecting support (17') having at least one outlet (29). The support moves from a first or separating position and a coupling position for overflowing and vice versa. The outlet (29) is closed once the coupling position has been reached and remains closed thereafter.

Description

The invention relates to a potential isolating device for an electrical conductive liquid, especially for an electrically conductive paint, with the Features a to f (preamble) of claim 1.

Such a potential separation device for processing a lacquer is out EP-A 434 535 known. It is used in an electrostatic painting system, in which water-dilutable paints are processed, e.g. in motor vehicle manufacturing. There is paint material at electrostatic painting at a high voltage potential lying atomizer supplied via a line. If this Lacquer material is electrically conductive, must be ensured be that it is not through the paint feed line an electrical short comes because the other end the paint supply line is below ground potential. Out for this reason, must be secured against inspection High voltage area the paint supply line and the associated Paint containers also at high voltage potential be placed. This in turn means that this container during operation not from an earth potential horizontal supply line can be refilled. The paint shop must therefore during the refill process to be interrupted.

If a continuous supply of the paint material from a high voltage potential container for the atomizer to be guaranteed, the container must be suitable Form be filled discontinuously with lacquer material. This will also be the case in the existing paint shops actually practiced. In many cases this still comes complicating the fact that usually conductive paints like for example water-based paints in several different ones Shades must be kept ready, which then over a automatic color changer for high voltage Atomizers must be supplied. In the event that between the color changer and the atomizer should be used, it is considered impossible is to automatically rinse all parts quickly, if the potential isolators during painting only small distances between the different Have potential-carrying components and if possible should be compact.

Considered for the sake of the required insulation the prevailing potential between the high voltage and Components lying on the ground are during painting relatively high distances under high voltage Comply with the area above 200 mm or you can in the high voltage free, grounded operation between their inputs and Outputs are not switched so that an automatic Quick color change or rinsing cycle carried out can be.

In the known potential separating device (EP-A 434 535) there is the partition from a disc-shaped section, which is in a radial plane extends, as well as from a to the extent of this section tubular section which extends axially and in which the housing side Outlet opening arranged and the associated closure piece is guided, the has a correspondingly large diameter. When passing the paint the closure piece is lifted off the radial wall section, so that one of limited large end faces on the closure piece and on the partition Chamber is created through which the paint to the intake opening and the outlet opening flows in the tubular partition extension and in the separator housing. Accordingly, the paint flows over large areas within the housing, which makes the required sealing much more difficult, especially if with a electrically insulating liquid is worked in the chamber in which the Nozzle needle is in the disconnect position. However, this is with the known Potential separating device is not provided, which at least protects against breakdown reduced in the case of a compact training.

However, it is known from US-A 5 632 816 for a potential isolating device for an electrically conductive liquid or for an electrically conductive lacquer associated end pieces of the flow path for the electrically conductive To arrange the flow medium in an electrically insulating liquid. This is at the same time connected with a constant flushing, whereby the insulating effect of the Isolation valve is ensured.

The invention has for its object to a potential isolating device create a safe insulation with appropriate training and handling from points of the flow path located at different electrical potential guaranteed.

This object is achieved according to the invention with the characteristic features g to i of claim 1 solved.

The use according to the invention of an electrically insulating liquid within the separator ensures a high level even with a compact design Punch security. Furthermore, the closure piece for the housing side The outlet opening and the ring channel enclosing this closure piece with comparatively small diameters are executed, which is advantageous to smaller areas covered by paint and better sealing options leads. Electrically conductive liquid comes with contacting walls not in contact, so there is also a low risk of contacting one Finally, surface-forming film made of electrically conductive liquid into one Short circuit leads. Overall, the invention thus enables high security requirements sufficient potential isolating device of small size, the easy to handle and with a high switching speed as well as practical leaves.

Appropriate refinements and developments of the invention result from the subclaims.

Fig. 1:

im Schnitt eine Potential-Trenneinrichtung im geöffneten Zustand;

Fig. 2:

einen Schnitt wie in Fig. 1 kurz vor dem Schließen des Strömungsweges und

Fig. 3:

eine Einzelheit aus den Fig. 1 und 2 in größerem Maßstab bei geschlossenem Strömungsweg

The invention is described below with reference to an embodiment shown in the drawing. Show:

Fig. 1:

on average a potential isolating device in the open state;

Fig. 2:

a section as in Fig. 1 shortly before closing the flow path and

Fig. 3:

a detail of FIGS. 1 and 2 on a larger scale with a closed flow path

A potential isolation device connected as a potential isolation valve 1 comprises according to that shown in FIGS. 1 to 3 Embodiment a multi-part housing 2, which mainly consists of an insulating material. It comprises a centrally arranged, cylindrical housing part 3 and its interior closing, each end at both ends 4, 5 arranged covers 6, 7. In the Housing 2 are at a distance from each other and at a distance partition walls 8 arranged by the covers 6 and 7 and 9. The partitions 8 and 9 form chambers on the one hand 10, 11 and 12 inside the housing 2 and also serve for storing and guiding components, with the help of a Flow medium from a first point 13 of a flow path 14 to a second point 15 with one depending on the electrical Switching state other electrical potential can flow. The components are used for connecting and to interrupt the flow path 14 of the electrically conductive Flow medium.

According to the embodiment shown in the figures is the first 13 forming Component around the free end 16 of a nozzle needle 17. The nozzle needle 17 has a longitudinal channel 18 and is, for example to a low electrical potential having line connected. Then points accordingly also the flow medium located in the nozzle needle 17 a low electrical potential.

Furthermore, a drive 19 is associated with the nozzle needle 17, with whose help the nozzle needle 17 relative to the second location 15 of the to be connected or from each other releasing components is movable. This drive 19 includes Pistons 20 and 21, which can be acted upon via connections 22 and 23 are that the nozzle needle 17 in at least two Directions is movable, as can be seen from the Fig. As Pressure medium is supplied via lines 27 and 27a Compressed air.

The free end 16 of the nozzle needle 17 (FIG. 1) is located in the middle one, which is always filled with insulating liquid Chamber 11 and is on the front side according to the embodiment closed. The flow path 14 or the longitudinal channel 18 ends in the nozzle needle 17 on at least one radially directed Exit opening 29, as in particular also from the representation of Fig. 3 emerges. An annular channel 30 is the or the radially directed Assigned outlet openings 29 and forms one housing-side receiving opening and leads to an outside directed outlet opening 31. The annular channel 30 is located itself in the intermediate wall 8 and is arranged there in such a way that he with open potential isolation valve 1 according to FIG. 1 of a closure piece 32 is covered. This closure piece 32 is movable relative to the nozzle needle 17 and in whose axis is arranged and is determined, for example, by the pressure force a spring 33 is applied in the closing direction (FIGS. 1 and 2). On its end face facing the nozzle needle 17 the closure piece 32 has a recess 34, into which a centering piece 35 at the free end 16 of the nozzle needle 17 when closing the potential isolation valve 1 initially engages, as shown in Fig. 2. If then the nozzle needle 17 from the position shown in FIG. 2 still moved further in the axial direction towards the cover 6 the closure piece 32 moves into that in FIG. 3 shown position to the left until it releases the ring channel 30. At the same time, the outlet openings 29 move of the longitudinal channel 18 of the nozzle needle 17 from the position of Fig. 2 to the left until they are in front of the ring channel 30 (Fig. 3).

1 and 2 are the outlet openings 29 axially on the nozzle needle 17 displaceably arranged sleeve 50 covered. This sleeve 50 is acted upon by a compression spring 51 and also has a stop 52 on. Immediately before the outlet openings 29 reach the ring channel 30, the stop hits 52 on a resistor so that the sleeve 50th despite a further movement of the nozzle needle 17 in the axial Can no longer move to the left (Fig. 3) and the outlet opening 29 releases. Now the flow medium or the electrically conductive liquid the nozzle needle 17 to the housing-side outlet opening 31 flow, the nozzle needle 17 an end of the flow path 14 forms while the second end of the flow path 14 is arranged on the housing side.

The nozzle needle 17 is a hollow valve needle or a free one cantilevered carrier 17 ', in the interior 18' the electrical conductive flow medium flows. This carrier 17 ' moves itself between a first or separation position and a docking position according to FIG. 3, in which the electrostatic conductive liquid can flow. Basically moved the carrier 17 'back again as soon as the Overflow process is finished. The outlet openings 29 on free end of the carrier 17 'are only in the docking position opened and otherwise with the serving as a closure piece Sleeve 50 on the side of the movable nozzle needle 17th closed. The housing side is comparable arranged annular channel 30 with the aid of the closure piece 32 always closed when the nozzle needle 17 in the Separation position is and it is only open when the Nozzle needle 17 has reached the docking position. This is essential as a result that the electrically conductive liquid that flows without contact with boundary walls when opening and closing the potential isolating device move relative to each other.

The flow path 14 is on the housing side of the ring channel 30 and the associated outlet opening 31, wherein it is further understood that the direction of flow for the electrically conductive flow medium also opposed can be directed.

According to the embodiment shown in the figures also a piston 36 located in the chamber 10 the closure piece 32 and is assigned via a line 37 supplied with a pressure medium.

There is also an axially directed relief bore 39 in the closure piece 32, so that the centering piece 35 when the nozzle needle 17 is docked into the recess without a gap 34 can intervene.

Finally, there are also sealing elements 40 (FIG. 2) in all pistons and the closure piece 32 and between the covers 6, 7 and the various built-in parts as well required to seal the nozzle needle 17 and in the Fig. A face is particularly important sealing element 41 arranged on the sleeve 50, that after leaving the docking position shown in FIG. 3 on the facing end face of the centering piece 35 abuts.

Furthermore, according to the exemplary embodiment, grasp two at a distance mutually arranged sealing elements 42 and 43 die Sleeve 50 in the docked state. The ring channel side Sealing element 42 also serves as a wiping element and a located between the two sealing elements 42 and 43 Annular channel 44 in the intermediate wall 8 leads to the already above-mentioned line 28 and the connection 25. If necessary imported electrically conductive liquid collect here and be derived through the connection 25.

Have a fundamentally similar function and meaning those shown in the figures associated with the closure piece 32 Sealing elements and the one between them Ring channel and its leading line.

All other sealing elements shown in the figures should not explained here in more detail. Basically the same applies to the division of the housing 2 into different housing parts, thus ensuring the intended function is. In principle, this is the case even in certain cases possible, the potential isolation valve 1 according to the invention to operate an electrically insulating liquid because the degree of insulation achievable through the design is very high. The invention is therefore not to the exemplary embodiment specifically shown in the figures limited, rather modifications are still possible, without deviating from the basic idea of the invention.

The invention exists for use in a painting installation essentially a potential isolation valve, that between an earthed paint supply line and a Work tank or between the work tank and an atomizer connected to high voltage can. Its lacquer entrance, which is connected to earth potential, will over the liquid insulation medium from the high voltage lying paint exit at such a short geometric distance arranged that this distance in the case of a bilateral switching state at ground potential in the shortest possible time Time by docking the supply line to the Paint exit can be bridged. Therefore it is possible that various potential isolation valves connected in series, including intermediate work containers, in an automatic color change or rinse cycle can be integrated, one between a grounded Paint supply hose and the atomizer completely open and automatically flushable cable routing switched can be. The potential isolation valve designed as a hollow needle valve includes a paint supply lance, the Example of earth potential with exclusion of air in the chamber filled with the liquid insulating medium in a small amount Distance to one of either high voltage or earth potential lying docking station slidably arranged and with a preferably pneumatically operated feed device be introduced into the docking station can. The docking station in turn forms a valve that closed the way to a downstream work container lasts as long as the paint supply lance is not docked and with the docking of this lance in one Way opens that the paint material present in the hollow needle valve reliably separated from the surrounding insulation medium remains and a transfer of paint material into the Isoliermedium or of Isoliermedium in the paint material is excluded. The docking station encloses this introduced hollow needle valve air and liquid tight, wherein the hollow needle valve is only in the docked, from one outer sleeve of the docking station enclosed state opens.

The piston carrying the paint supply lance / nozzle needle 17 also cleans the inner wall during its movements the chamber of deposits receiving it. The piston therefore serves at the same time in its docking and undocking movement as a circulation pump for the insulating medium.

Basically, it is the longitudinal channel 18 in the Nozzle needle 17 around the interior 18 'of a cantilever Carrier 17 'from a separation position into a docking position is movable so that the electrically conductive Liquid can flow over. The ring channel 30 serves as a housing opening and is only in the docking position opened, as well as this for the outlet opening 29 on the freely projecting carrier 17 'or on the Nozzle needle 17 applies.

The manufacture of the various parts is basically based on known materials, some also insulating Find materials.

Claims (6)

1. Potential isolating device for an electrically conductive liquid, particularly for an electrically conductive paint, comprising

   a) a housing (2) which has at least one intermediate wall (8, 9) and chambers (10, 11, 12) divided off by this,

   b) a receiving opening at the housing side and an outlet opening (31) at the housing side,

   c) a movable closure member (32) which is associated with the outlet opening (31) at the housing side and which is guided in an intermediate wall (8),

   d) an axially movable nozzle needle (17) which has a longitudinal channel (18) and at its free end (16) at least one radially directed outlet opening (29),

   e) a movable closure member (50) for the radially directed outlet opening (29) at the nozzle needle (17) and

   f) a drive (19) for axial displacement of the nozzle needle (17) between a retracted separating position and an advanced throughflow position,
   characterised in that

   g) the outlet opening (31) at the housing side extends through a radially extending portion of the intermediate wall (8), in which also the closure member (32) associated with the outlet opening (31) is guided,

   h) an annular channel (30), from which the outlet opening (31) goes out, is formed in the guide surface for the closure member (32) and forms the receiving opening, and

   i) the free end (16) of the nozzle needle (17) in the separating position is disposed in a chamber (11) which is filled with an electrically insulating liquid.
2. Potential isolating device according to claim 1, characterised in that the closure member (22) guided in the intermediate wall (8) is cylindrical.
3. Potential isolating device according to claim 1 or 2, characterised in that the nozzle needle (17) engages by its end, which is remote from the outlet opening (29), through the housing (2) at the end face.
4. Potential isolating device according to one of claims 1 to 3, characterised in that the housing (2) has respective end chambers (10, 12) for mounting and guidance of pistons (21, 36) and therebetween the chamber (11) with the electrically insulating liquid, wherein the pistons (21, 36) serve as drive.
5. Potential isolating device according to one of claims 1 to 4, characterised in that a further annular channel (44) for collecting any electrically conductive liquid which has been carried in is provided in the radial portion of the intermediate wall (8) axially adjacent to the annular channel (30) serving as receiving opening.
6. Potential isolating device according to one of claims 1 to 5, characterised in that the electrically insulating liquid is disposed at times on both sides of the radial portion of the intermediate wall (8).

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