DE102006005529B4 - Plastic container with at least one electrode made of electrically conductive plastic - Google Patents

Abstract

A plastic container (10; 110) having a container body (12; 112) and electrically conductive electrode means (28; 128) fixed to a wall of the container body (12; 112) such that at least a portion (34; 134) the electrically conductive electrode device (28; 128) is exposed in the interior (26; 126) of the container body (12; 112) for contacting by material filled or to be filled into the container body (12; 112), the electrically conductive electrode device (28; 128) is at least partially formed of electrically conductive plastic, characterized in that at least one electrode (30, 32; 130) of the electrode means (28; 128) passes through the wall of the container body (12; 112), wherein the container body (12; 112) plastic container body and the at least a portion (34, 36, 38, 134, 138) of the electrically conductive electrode means (28; 128) forming electrode plastic compatible have le or the same polymers, and wherein the container body (12; 112) has a holding section (40, 140) which surrounds the at least one electrode (30, 32, 130, 132) of the electrode arrangement (28, 128) in a fluid-tight manner without the interposition of separate sealing means.

Description

The present invention relates to a plastic container according to the preamble of claim 1.

A generic plastic container is from the US 5,626,053 known. This document discloses a plastic tank with a level gauge, the plastic electrodes either from inside a wall of the container body or an intermediate wall of the container (see 5 of the US 5,626,053 ) or in such a way on a separately formed from the container body lid (see 1 of the US 5,626,053 ) are mounted so that they protrude from above into the interior of the container body. In both cases, the plastic electrodes are connected via connecting wires or connecting cables with a read-out device arranged outside the container body.

Basically, the container body surrounds a certain volume of space into which material can be filled through an opening in the container body. In the case of electrically conductive materials, the material level in the container body can be detected by an electrically conductive electrode device. For this purpose, the electrode device must have at least two electrodes of different electrical potential, which are only electrically connected to one another by the material filled into the container body. Depending on whether or not the at least two electrodes of different potential are electrically conductively connected to one another by the filled material, a minimum filling level in the container body can be detected with a corresponding arrangement of the electrode device relative to the container body.

If the electrode device is mounted on the container body in such a way that it dips differently depending on the level of the material filled into the container body, the electrical resistance existing between the electrodes changes with the filling level, so that when the minimum filling level is exceeded in the container body, from which a contacting of the electrode device is effected by the filled material, can be closed by measuring the electrical resistance between the electrodes to the material level in the container body.

Such plastic containers are used, inter alia, in the automotive industry as a resource container, in particular as a spray water container for the windshield and windshield wiper cleaning or as Kühlwasserausgleichsbehälter.

Electrode devices known in the art include metallic electrodes, which are generally elongate and project into the interior of the container body.

A disadvantage of this known from the prior art solution is, first, that it comes through the flow of current between the metallic electrodes of the known electrode devices over the operating time to an electrolysis, which in turn led to deposits of deposited by the electrolysis components of the filled into the container body Materials leads. The result is changing operating characteristics of the electrode device with increasing deposition and undesirably increasing the reliability of the detection result with the operating time.

In addition, the known electrode devices are often attached to the container body so that they pass through from the outside in, resulting in a considerable effort for the sealing of the container body at the enforcement sites. Even if the metal electrodes are injection-molded in a container body produced by injection molding during its manufacture, this compound is not tight over the entire expected life of the plastic container, so that additional seals, such as O-rings, must be used to increase the sealing effect. For this purpose, appropriate sealing seats are provided on the metallic electrodes.

It is therefore an object of the present invention to provide a technical teaching, as plastic container of the type mentioned with much less effort while improving the quality of reliability, tightness and service life can be produced.

This object is achieved by a generic plastic container with the features of the characterizing part of claim 1.

It has been shown that, compared with the case of metallic electrodes, the electrolysis-related deposits on the electrodes when using the same filled in the container body materials of electrically conductive plastic fail or even can be completely avoided. As a result, the detection result of the electrode device, in which electrically conductive plastic is exposed in the container body interior for contacting the material filled in the container body, over the entire service life of the plastic container reliable, small changes designed and thus of higher Accuracy than in the metallic electrodes of the prior art.

According to the invention, it is provided that the electrode device is fastened to a wall of the container body in such a way that the electrode device passes through a wall of the container body, since the contacting of electrodes by material filled into the container body can take place at the portion of the electrode device located in the interior of the container body, and When a voltage is applied to the electrodes of the electrode means between them, a current which may flow is conveniently detected at the portion of the electrode means located outside the container body.

For this purpose, it can be provided, in particular, that the electrode device has a connection section made of electrically conductive plastic, which is designed for contacting by an electrical line. Particularly preferably, this connection section is formed integrally with at least one electrode of the electrode device. In contrast to the metallic electrodes of the prior art, in which an elaborate, usually machining machining is required, in the case of electrodes made of conductive plastic, the connection section can already be formed during the initial shaping of the electrode device or its respective electrode.

In the case of the arrangement of the electrode device passing through a wall of the container body, a further advantage of the use of an electrode device, which is formed at least in sections from electrically conductive plastic, clearly comes into play. Compared to the plastic-metal material pairing used in the prior art between container body and electrode device, the material properties of the plastic-plastic material pairing used in a plastic container according to the present invention are less different, so that the provision of additional sealing devices, such as O-rings and like, can be dispensed with. Rather, regardless of the manufacturing method used for producing the plastic container between the container body and the electrically conductive plastic of the electrode device can come to diffusion processes or to fusion processes, which can lead at least partially to a cohesive connection of the electrically conductive plastic of the electrode device with the plastic of the container body , Even if this is not the case, however, the difference between the respective thermal expansion coefficients of the electrically conductive plastic and the plastic of the container body is substantially lower than in the metal-plastic material pairing used in the prior art, so that thermally induced relative movements between electrode device and container body lower than in known plastic containers, which increases the tightness of an interspersed by electrode container body.

At least one electrode, preferably all electrodes, of the electrode device of the plastic container according to the invention are preferably designed as elongate components which extend along an electrode longitudinal axis. This has the advantage that the container body, as described above, can be penetrated by at least one electrode, preferably by all the electrodes, and on the electrodes themselves a sufficiently long section is available, at which they can be enclosed by the plastic of the container body , The longer the area surrounding the electrodes can be formed in the direction of the electrode longitudinal axis, the better the container body at the enforcement of the electrode device due to the increasing sealing surface without the use of additional from the container body and the electrode assembly separately formed sealing means, such as sealing rings, against leakage be sealed.

The elongated electrode preferably has the above-described connection section in the region of its longitudinal end lying outside the container body, so that a sufficiently long electrode can be produced with the lowest possible requirement for electrically conductive plastic.

It may be thought to form only a few portions of an electrode of the electrode device made of electrically conductive plastic. However, it is simpler and cheaper to form such an electrode essentially completely of electrically conductive plastic. In this case, the electrode can be formed as needed in the desired shape by suitable Urformwerkzeuge. "Substantially complete" is not intended to exclude that small amounts of other materials, such as contact shoes on the terminal portions and the like, may be provided on the electrode of the electrode device in question.

The above-mentioned diffusion processes or merging processes between the material of the container body and the electrically conductive plastic of the electrode device, which lead to increased tightness of a container body of the plastic container penetrated by at least one electrode, are particularly easily effected according to the invention by the container body forming the container body. Plastic and the at least one section of the electric conductive electrode means forming electrode-plastic compatible or the same polymers.

With a view to achieving the best possible sealing of the container body penetrated by at least one electrode at the point of penetration, the electrically conductive plastic comprises a polymer matrix and electrically conductive particles incorporated therein, wherein the plastic of the polymer matrix and the container body Plastic compatible or even identical.

In principle, the electrode device may comprise only a single electrode component which is exposed in the container body, if the latter has galvanically separated electrode elements of different electrical potential. However, such an electrode component is less preferred, since its production is very complicated. A preferred embodiment of a plastic container according to the present invention comprises two spaced-apart electrically conductive electrodes, both of which are at least partially made of electrically conductive plastic and both are arranged on the container body, that in each case at least a portion of the electrically conductive electrodes in the interior of the container body is exposed.

In principle, the plastic container described above can be produced by any desired manufacturing method. Thus, for example, the electrodes of the electrode device and the container body can be manufactured in separate manufacturing processes and retrofitted with each other. However, such a production method would not make optimum use of the essential advantages of the plastic container according to the invention.

Furthermore, it may be thought to manufacture the electrodes of the electrode device separately from the container body and insert it into a master mold for the production of the container body. The plastic molding compound forming the container body could then flow around the electrodes provided, wherein the plastic molding compound is usually thermally softened to form the container body and due to the elevated temperature of this molding compound, the previously mentioned advantageous diffusion processes or merging processes between the provided plastic electrodes and they could use enclosing plastic container body section.

It should be emphasized at this point again emphatically that an essential advantage of the present invention is the fact that on the container body, a holding portion is formed which one electrode or preferably all electrodes of the electrode assembly without an intermediate arrangement of separately formed sealing means, in particular sealing rings and the like, surrounds fluid-tight. "Fluid-tight" should mean gas-tight or / and liquid-tight. Since the plastic containers described in the present application are usually formed for receiving and storing liquid, liquid tightness at the holding portion of the container body is sufficient.

However, it is particularly preferred to produce the container body and at least one electrode, preferably all electrodes, substantially simultaneously or in a short time sequence by a multi-component injection molding process, preferably by a two-component injection molding process. In this case, a stable cohesive connection between the at least one electrode of electrically conductive plastic and the plastic of the container body can be achieved particularly easily, in particular when the plastics used for the electrodes and for the container body are based on the same or at least one compatible polymer base.

The electrodes of the electrode device can have any cross-sectional shape.

The above-described preferred production method (multi-component injection molding method) therefore likewise represents a solution according to the invention of the object on which the present invention is based.

The present invention will be explained in more detail below with reference to the accompanying drawings. It shows:

1 a first embodiment of a plastic container of the present invention and

2 a second embodiment of a plastic container of the present invention.

In 1 is a first embodiment of a plastic container according to the invention generally with 10 designated. In the in 1 The example shown is the plastic container 10 to a splash tank for a windscreen washer system of an automobile. The plastic container 10 comprises a container body 12 from a lower shell 12a and a sealingly connected to this upper shell 12b ,

The container body 12 has a drain opening 14 and a filling opening 16 on. There is also an additional opening 18 provided, which can be used for example for material and / or pressure equalization.

The filling opening 16 is with a thread 20 provided, in which an unillustrated lid can be screwed to the filling opening 16 to close. The remaining openings 14 and 18 are as Schlauchsteckstecknutzen 22 respectively. 24 designed. In the interior 26 of the container body 12 extends an electrode assembly 28 with two electrodes 30 and 32 made of electrically conductive plastic. The electrodes 30 and 32 are identical, so it is sufficient in the following, only in 1 left electrode 30 representative of the electrode as well 32 to describe.

The electrode 30 extends into the in 1 shown example along an electrode longitudinal axis ELA rod-shaped.

The electrode 30 includes a detection section 34 which of her in the interior 26 of the container body 12 located longitudinal end 30a to slightly above the longitudinal center of the electrode 30 enough. At this closes in the direction of the electrode longitudinal axis ELA a connection region 36 along which the electrode 30 of material of the lower shell 12a of the container body 12 is surrounded sleeve-shaped. In the longitudinal direction of the electrode longitudinal axis ELA to the connecting portion 36 subsequent longitudinal end region 38 that extends to the outside of the container body 12 located longitudinal end 30b the electrode 30 ranges, is formed as a connection portion on which an electrical contact at the end of an electrical line for contacting the electrode 30 is pluggable.

The electrodes 30 and 32 as well as the lower shell 12a and the upper shell 12b of the container body 12 comprise the same polymer material. This will only be for the container body 12 unfilled and for the electrodes 30 and 32 used filled with electrically conductive particles.

Along the connecting section 36 are on the lower shell 12a molded sleeves 40 cohesively with the electrodes 30 and 32 connected and thus ensure a good seal of the lower shell 12a at the point where these are from the electrodes 30 and 32 is interspersed. The pods 40 represent a previously mentioned holding portion of the container body 12 The cohesive connection is the almost simultaneous production of lower shell 12a and electrode means 28 produced by a per se known two-component injection molding process. By diffusion processes and / or merging operations on the after the injection molding process still warm electrodes 30 and 32 and pods 40 it comes between these to form a sealing compound layer. However, even if this compound layer is not formed completely or even not at all, the two-dimensionally seal at the electrodes 30 and 32 adjacent sleeves 40 the lower shell 12a against leakage, since the electrodes 30 and 32 as well as the lower shell 12a by the use of the same or at least one compatible thermoplastic polymer material substantially the same or at least very similar material properties, in particular thermal expansion coefficients have, so that during thermal load changes hardly a sealing endangering relative movements between the electrodes 30 and 32 and the pods 40 occurs.

About the connection sections 38 and 39 the electrodes 30 respectively. 32 can by means of a not shown in the container body 12 integrally molded socket 42 plugged in an electrical voltage to the electrodes 30 and 32 be created, which then have a different electrical potential. By measuring the electrical resistance between the electrodes 30 and 32 (For example, by measuring the voltage drop between them) can at least on the presence of a minimum filling quantity in the container body 12 getting closed. Be the electrodes 30 and 32 wetted by electrically conductive liq, the detected resistance decreases to a finite value.

In 2 a second embodiment of the present invention is shown. Same components as in 1 are denoted by the same reference numerals, but increased by the number 100 , For an explanation of these components is expressly to the description in connection with 1 directed.

The embodiment of 2 is different from that in 1 essentially by the shape of the electrodes 130 and 132 the electrode assembly 128 , The electrode 130 is in 2 formed angled. Also the electrodes 130 and 132 be together with the lower shell 112a produced in a two-component injection molding process.

Also the electrode 132 intersperses the lower shell 112a of the container body 112 , being like the electrode 130 is formed angled. Your connection section is in 2 through the connection section 138 the electrode 130 covered.

Claims (7)

Plastic container ( 10 ; 110 ) with a container body ( 12 ; 112 ) and with an electrically conductive electrode device ( 28 ; 128 ), which in such a way on a wall of the container body ( 12 ; 112 ), that at least one section ( 34 ; 134 ) of the electrically conductive electrode device ( 28 ; 128 ) for contacting through into the container body ( 12 ; 112 ) filled or fillable material inside ( 26 ; 126 ) of the container body ( 12 ; 112 ), wherein the electrically conductive electrode device ( 28 ; 128 ) is at least partially formed of electrically conductive plastic, characterized in that at least one electrode ( 30 . 32 ; 130 ) of the electrode device ( 28 ; 128 ) the wall of the container body ( 12 ; 112 ), wherein the container body ( 12 ; 112 ) forming container body plastic and the at least one section ( 34 . 36 . 38 ; 134 . 138 ) of the electrically conductive electrode device ( 28 ; 128 ) comprise plastic-compatible or similar polymers, and wherein the container body ( 12 ; 112 ) a holding section ( 40 ; 140 ) having the at least one electrode ( 30 . 32 ; 130 . 132 ) of the electrode assembly ( 28 ; 128 ) surrounds fluid-tight without intermediate arrangement of separate sealant. Plastic container according to claim 1, characterized in that the electrode device ( 28 ; 128 ) formed of electrically conductive plastic connection portion ( 38 . 39 ; 138 ), which is designed for contacting by an electrical line. Plastic container according to claims 1 and 2, characterized in that the at least one electrode ( 30 . 32 ; 130 . 132 ) extends along an electrode longitudinal axis (ELA), wherein a first longitudinal end (FIG. 30a ; 130a ) of the electrode ( 30 ; 130 ) internally ( 26 ; 126 ) of the container body ( 12 ; 112 ) and a second, opposite the first longitudinal end ( 30b ; 130b ) of the electrode ( 30 ; 130 ) outside the container body ( 12 ; 112 ) and the connection section ( 38 ; 138 ) in the region of the second electrode longitudinal end ( 30b ; 130b ) is trained. Plastic container according to one of the preceding claims, characterized in that the at least one electrically conductive electrode ( 30 . 32 ; 130 . 132 ) of the electrode device ( 28 ; 128 ) is formed substantially entirely of electrically conductive plastic. Plastic container according to one of the preceding claims, characterized in that the electrically conductive plastic comprises a polymer matrix and electrically conductive particles incorporated therein, wherein the plastic of the polymer matrix and the container body plastic are compatible or identical. Plastic container according to one of the preceding claims, characterized in that the electrode device ( 28 ; 128 ) two spaced apart electrically conductive electrodes ( 30 . 32 ; 130 . 132 ), both of which are at least partially made of electrically conductive plastic and both of which on the container body ( 12 ; 112 ) are arranged, that in each case at least one section ( 34 ; 134 ) of the electrically conductive electrodes ( 30 . 32 ; 130 . 132 ) internally ( 26 ; 126 ) of the container body ( 12 ; 112 ) is exposed. Method for producing a plastic container ( 10 ; 110 ) according to one of the preceding claims, wherein the container body ( 12 ; 112 ) and the at least one electrode ( 30 . 32 ; 130 . 132 ) are produced by a multi-component injection molding process, preferably by a two-component injection molding process.

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