KR20130110899A - Connector of the connection of at least two receptor modules for a liquid medium - Google Patents

Abstract

PURPOSE: A connector for connecting two or more receiving elements for a fluid medium is provided to simply and cost-efficiently prevent damage to receiving elements or pipe connectors. CONSTITUTION: A connector (1) for connecting two or more receiving elements for a liquid medium comprises a first connection end (3) and a second connection end (4). A fluid medium flows between the first and second connection ends. A pressure equilibrium chamber (5) is formed between the first and second connection ends. A compressive insert (6) is arranged inside of the pressure equilibrium chamber. One or more longitudinal channels for connecting the first and second connection ends are formed between the inner wall (7) of the pressure equilibrium chamber and the compressive insert. When the fluid medium is expanded, the compressive insert is compressed to the center of the pressure equilibrium chamber.

Description

CONNECTOR OF THE CONNECTION OF AT LEAST TWO RECEPTOR MODULES FOR A LIQUID MEDIUM}

The present invention is a connector for connecting at least two receiving elements for a fluid medium, for example for connecting two pipelines for a fluid medium, the connector having a first connecting end and a second receiving element for connecting the first receiving element. And a second connecting end for the connection of the liquid medium, wherein the fluid medium can flow through the connector between the first connecting end and the second connecting end. At this time, the fluid medium may flow from the first connecting end toward the second connecting end or vice versa from the second connecting end toward the second connecting end. A receiving element for a fluid medium means, in the sense of the present invention, a pipeline or a tank for a fluid medium or a dosing element for a fluid medium, in particular for the transport of the fluid medium. Here, the pipeline also means a hose line or a plastic hose. In the following, when a connector according to the present invention is used to connect at least one pipeline, the connector will also be referred to as a pipe connector. It is suitable for the pipeline to be inserted at the first connection end or the second connection end of the pipe connector and preferably locked thereto.

Pipe connectors of the type described above are known in the field in various embodiments. In particular, in the case of pipelines and pipe connectors for the transport of water or aqueous medium, there is a problem that the fluid medium freezes under volume expansion at low temperatures. Pressures based on or accompanying such volume expansion can damage or even completely destroy the pipelines and pipe connectors.

In practice, various measures have already been proposed to solve such problems. However, most of these measures are not satisfactory.

In automobiles, the so-called SCR (Selective Catalytic Reduction) method is used to reduce the nitrogen content in the exhaust gas. Aqueous urea solutions are used within the scope of such SCR methods. In particular, the above-mentioned problems also occur in such urea aqueous solutions. The urea aqueous solution freezes under volume expansion, similar to water at low temperatures, and the corresponding pressure rise can damage or completely destroy the pipelines, connectors, etc. of the SCR system. In SCR systems, it is known from the actual site to draw and empty the pipeline guiding the medium after the vehicle stops. This eliminates freezing of the aqueous medium in the pipeline. Such a process is complex and prone to defects.

The technical problem of the present invention is to provide a connector or a pipe connector of the type mentioned at the beginning which can avoid the above-mentioned problems. In that regard, the invention relates in particular to a connector for connecting receiving elements for aqueous urea solution in the scope of an SCR system.

To solve such a technical problem, the present invention provides a connector for connecting receiving elements for at least two fluid media, for example a pipe connector for connecting pipelines for two fluid media, in particular for urea solution, wherein the connector is provided with a first connector. A first connecting end for connecting the receiving element and a second connecting end for connecting the second receiving element, wherein the fluid medium can flow through the connector between the first connecting end and the second connecting end,

The connector having a pressure balance chamber between the first connection end and the second connection end, wherein a compressible insert is disposed in the pressure balance chamber,

At least one longitudinal channel, preferably a plurality of longitudinal channels, for fluid communication between the first connecting end and the second connecting end between the compressive insert and the inner wall of the pressure balancing chamber, the compressive insert being in contact with the inner wall of the pressure balancing chamber Longitudinal channels are provided,

The compressible insert can be compressed upon volume expansion of the fluid medium due to temperature, in particular a connector that can be compressed towards the center of the pressure balance chamber.

At least one longitudinal channel is provided for fluid communication between the first connecting end and the second connecting end in the sense of the present invention, through which the fluid medium passes through the longitudinal channel from the first connecting end to the second connecting end and It means you can flow in reverse. Volume expansion of the fluid medium attributable to temperature means, in particular, volume expansion during the freezing of the fluid medium.

One configuration within the scope of the invention is that the connector according to the invention consists of plastic or is made of plastic in general. According to a preferred embodiment of the present invention, the housing of the connector consists of polyamide, preferably of glass fiber reinforced polyamide. However, the housing of the connector may in particular be made of polyphthalamide (PPA) or glass fiber reinforced polyphthalamide or fluoroplastic or glass fiber reinforced fluoroplastic. The material for the housing of the connector is suitably selected on the premise that a material joint connection with the plastic pipeline to be connected with the housing is possible. The material joint connection is then realized by a welding method and in particular by rotary welding. The connector is preferably a so-called quick connector.

One configuration within the scope of the invention is that the fluid medium, in particular the aqueous urea solution, flows through the connector in the longitudinal direction. The connector is suitably composed of cylindrical sections which are arranged one after another in their longitudinal direction as a whole. It is preferred that the first connecting end, the pressure balancing chamber, and the second connecting end are arranged in the longitudinal direction of the connector. It is advisable that the longitudinal axis extending in the longitudinal direction of the connector extends through the first connection end and / or through the pressure balance chamber and / or through the second connection end, very preferably of the first connection end. Extending through the center and / or through the center of the pressure balancing chamber and / or through the center of the second connecting end.

The pressure balancing chamber is suitably formed in a cylindrical shape, and the compressible insert is also preferably formed in a cylindrical shape or a generally cylindrical shape. The pressure balance chamber is made of plastic, preferably glass reinforced plastic. With regard to the preferred materials selected for the pressure balancing chamber, reference may be made to the materials described above for the housing of the connector. It is recommended that the pressure balance chamber, preferably made of plastic, be assembled into a number of parts, suitably two parts, wherein the parts of the pressure balance chamber are connected to each other by a welding method.

As already mentioned above, according to a very preferred embodiment of the present invention, the fluid medium is urea solution or urea solution. It is recommended that the connector according to the invention or the receiving elements connected thereto are used in an SCR system. In such an SCR system, the solution according to the invention has proved to be very effective.

One configuration within the scope of the present invention is that the compressible insert disposed in the pressure balance chamber can be reversibly modified. It is desirable for the compressive insert to compress upon volume expansion due to freezing of the fluid medium, and for the subsequent volume reduction due to sea ice, the compressive insert regains its original shape. The compressible insert is suitably made of an elastic material, in particular an elastic plastic material.

According to a particularly preferred embodiment of the present invention, the compressible insert consists of a plastic foam, preferably a closed cell plastic foam. According to a very preferred embodiment of the invention, the compressible insert consists of a plastic foam of rubber, particularly very preferably a plastic foam of EPDM (ethylene-propylene-diene rubber). One configuration within the scope of the present invention is that plastic foams, in particular closed cell type plastic foams, with compressive inserts up to 50% by volume, preferably up to 65% by volume and very preferably up to 80% by volume, And preferably is made of closed cell type plastic foam of rubber or EPDM. It has proven effective that the compressible insert consists of closed cell type EPDM plastic foam up to 90% by volume or more, preferably up to 95% by volume. It is recommended that the surface of the compressive insert be formed closed or formed by a closed sheath.

According to a preferred variant of the invention, the material of the compressible insert has a density of 0.5 to 0.7 g / cm 3, in particular of 0.55 to 0.65 g / cm 3. According to a highly recommended embodiment of the present invention, the compressible insert is formed compactly. Here, compact means that the compressible insert has no hollow space or no large hollow space. When the compressible insert consists of a plastic foam, in particular a closed cell type plastic foam according to a very preferred embodiment, the compressible insert has no hollow space or large hollow space other than the pores or cells of the foam.

It is recommended that the compressible insert have a hardness (hardness measured according to DIN 53505) of 2 to 25 Shore A, preferably 3 to 20 Shore A, very preferably 4 to 18 Shore A. According to an embodiment of the invention in which the effect has been demonstrated, the compressible insert has a residual pressure deformation of 0 to 55%, preferably 20 to 50%, very preferably 25 to 47% (DIN 53572, 22 hours, 70 ° C., 50% strain).

According to a preferred embodiment of the invention, the compressible insert is in contact with the pretension on the inner wall of the pressure balancing chamber locally. One configuration within the scope of the present invention is that the longitudinal channels are arranged distributed over the circumference of the compressible insert, wherein the longitudinal channels are separated from each other by the longitudinal bridges. According to a recommended variant, the longitudinal bridge protrudes from the inner wall of the pressure balance chamber. Contact with the inner wall of the pressure balance chamber (preferably with pretension) has proven to be effective. The longitudinal channels are suitably provided or embedded in the inner wall of the pressure balancing chamber. It is preferred that the longitudinal channels distributed over the circumference of the inner wall or the circumference of the compressible insert have the same spacing or generally the same spacing from each other. The longitudinal bridges are equal in width or substantially equal in width. One configuration within the scope of the invention is that the longitudinal channels and the longitudinal bridges extend in the longitudinal direction of the connector or in the direction of the longitudinal axis L of the connector. It is recommended that the longitudinal channels and the longitudinal bridges be arranged in parallel or substantially parallel to the longitudinal axis L of the connector. At least two, preferably at least three, very preferably at least four longitudinal channels are preferably provided.

As already mentioned above, according to a preferred embodiment of the present invention, the pressure balancing chamber and / or the compressive insert are formed in a cylindrical shape. According to a variant embodiment, the longitudinal bridges separating the longitudinal channels from one another protrude from the cylindrical inner wall of the pressure balancing chamber. One configuration that falls within the scope of the present invention is that the compressible insert is coaxially disposed within the pressure balance chamber and has a common longitudinal axis with the pressure balance chamber and the compressive insert centered at the center.

A very preferred embodiment of the present invention provides that the pressure balancing chamber has an annular inner wall and a first end wall and a second end wall over its inner circumference, and between the compressible insert and the first end wall and / or with the compressive insert and the second end wall. Transverse channels are provided for fluid communication with the longitudinal channels between the end walls. It is then preferred that the first end wall belongs to the first connecting end of the connector and the second end wall belongs to the second connecting end of the connector. It is suitable that the pressure balancing chamber is formed in a cylindrical shape, in which the inner wall forms a cylindrical casing, and both end walls form the surfaces of the cylinder. It is in the sense of the present invention that the first and / or second end wall is provided with transverse channels for fluid communication with the longitudinal channels, in the sense of the present invention that the fluid medium can flow through the transverse channels into the longitudinal channels or be lengthwise. It can flow from the directional channels to the transverse channels. One configuration within the scope of the present invention is that a plurality of transverse channels are provided in the first end wall as well as in the second end wall. The transverse channels are those which extend across the longitudinal channels, preferably perpendicularly or generally perpendicular to the longitudinal channels. According to a preferred variant, the transverse channels are arranged in the end wall in the form of stars or crosses. The number of transverse channels disposed in the end wall preferably matches the number of longitudinal channels between the inner wall and the compressible insert. One configuration within the scope of the present invention is that the lateral channels are directly connected with the longitudinal channels. Depending on the flow direction of the fluid medium, the fluid medium may flow through the lateral channels of the first end wall into the longitudinal channels and from the longitudinal channels to the lateral channels of the second end wall, or vice versa. It can flow.

A preferred embodiment of the invention is that the fluid line at the first connection end directly connected to the pressure balance chamber and / or the fluid line at the second connection end directly connected to the pressure balance chamber is less than half the inside diameter D of the pressure balance chamber. It is characterized in that it has an inner diameter (d) which is preferably less than 1/3, more preferably less than 1/4 and very preferably less than 1/5. The inner diameter d of the fluid lines is then measured perpendicular to its longitudinal axis or to the flow direction. The inside diameter D of the pressure balance chamber is measured perpendicular to the longitudinal axis of the pressure balance chamber, preferably perpendicular to the cylindrical axis of the pressure balance chamber, in particular in the region of the longitudinal bridges. One configuration within the scope of the invention is that at least one fluid line, preferably two fluid lines, are connected directly with the longitudinal channels via the transverse channels.

The ratio of the length l of the compressible insert (measured in the direction of the longitudinal axis of the compressive insert or the pressure balance chamber) to the outer diameter A of the compressible insert is 1.1 to 1.5, preferably 1.25 to 1.35. The outer diameter A of the compressible insert is then measured perpendicular to the longitudinal axis in the region of the longitudinal channels. The ratio of the outer diameter A of the compressible insert in the region of the longitudinal channels to the height h of the longitudinal channels is 20 to 50, preferably 25 to 45, more preferably 30 to 40, very preferably 32 to 38 is recommended. Here, the height h of the longitudinal channels means the distance from the inner wall of the pressure balancing chamber to the compressible insert in the region of the longitudinal channels. It is recommended that the ratio of the outer diameter (A) of the compressible insert to the width (b) of the longitudinal channels is 1.5 to 3.5, preferably 1.8 to 2.8, more preferably 2.0 to 2.6, very preferably 2.1 to 2.5 It is The width of the longitudinal channels is then measured across the length l of the compressible insert. It is recommended that the longitudinal channels extend over the entire length l of the compressible insert, in particular linearly, preferably parallel to the longitudinal axis of the compressible insert or the pressure balance chamber.

A pipe connector assembly having at least one pipeline and at least one pipe connector of the type described above connected to an end of the pipeline is also a subject of the present invention. According to a preferred embodiment, at least one pipeline is provided and at each end of the pipeline a pipe connector according to the invention of the type described above is connected. That is, a pipeline connects two pipe connectors according to the invention. Another arrangement within the scope of the present invention is that another pipeline is respectively connected to different ends of both ends of the pipe connector. Providing pipe connectors on both sides of each end of the pipeline has proven to be very effective in solving technical problems or in terms of effective freezing prevention of the pipeline.

A preferred embodiment of the present invention is characterized in that the pipe connector has a pipeline accommodating portion at one end and is configured such that the accommodating portion is connected to the material joint, in particular a welding method, preferably a rotation welding method. . In that regard, one configuration within the scope of the present invention is that the sections to which the pipe connector and at least the material of the pipeline are intended to connect are made of plastics, the plastics being identical or at least suitable for the material joint connection. However, connecting the pipeline to the connecting end may be implemented by pushing the pipeline onto a fir-tree profile or by crimping.

According to a recommended variant, the pipe connector has a female coupling receptacle for receiving a male adapter or plug of the pipeline at one connection end. Basically, however, such a connecting end may have a male coupling member or an adapter. In that case, it is preferably a quick coupling adapter of type SAE J2044.

The present invention provides that the expansion of the volume of the fluid medium due to temperature in the connected receiving elements or pipe connectors can be canceled simply, functionally and reliably and effectively by the connector according to the invention or by the pipe connector assembly according to the invention. It is based on the recognition that Damage or destruction of the receiving elements or the pipe connector can be effectively prevented by the measures according to the invention. It should be emphasized that the connector according to the invention or the pipe connector assembly according to the invention can be used very effectively, especially in an SCR system with an aqueous urea solution. It should also be emphasized that the performance according to the invention can be obtained by means of relatively simple and cost-effective measures.

1 is a side cross-sectional view of a pipe connector according to the present invention.
2 shows a cross section through the AA of the subject according to FIG. 1;
3 is a cross-sectional perspective view of the pressure balance chamber of the subject according to FIG. 1;

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings showing only one embodiment.

The accompanying drawings show a connector 1 for connecting receiving elements for a fluid medium. The fluid medium not shown is preferably an aqueous urea solution in this embodiment, and the connector 1 shown is suitably used in the framework of an automotive SCR system in this embodiment. In the embodiment according to FIG. 1, a pipeline 2 is connected to the first connection end 3. A pipe line 2 (not shown in FIG. 1) may also be connected to the second connection end 4. However, it is also possible here to connect other receiving elements in the form of tanks not shown or quantitative elements not shown. Between the first connecting end 3 and the second connecting end 4 a fluid medium, preferably urea solution, can flow through the connector 1.

According to the invention, the connector 1 has a pressure balance chamber 5 between the first connection end 3 and the second connection end 4, and in the pressure balance chamber 5 a compressible insert 6. Is placed. The compressible insert 6 is preferably made of a closed cell type EPDM plastic foam in this embodiment. At this time, the compressible insert 6 is formed compactly. Here, compact means that no hollow spaces are formed in the compressible insert 6 except for the pores or cells of the plastic foam. It is advisable in this embodiment that the pressure balancing chamber 5 be formed in a cylindrical shape. Compressible inserts 6 inserted into or disposed in the pressure balancing chamber 5 are also generally cylindrical in shape.

In FIG. 2, the compressive insert 6 contacts the inner wall 7 of the pressure balancing chamber 5 locally, in particular in the area of the longitudinal bridges 8 protruding from the inner wall 7. It can be recognized. Also in FIG. 2, a plurality of longitudinal channels for fluid communication between the first connecting end and the second connecting end 3, 4 between the inner wall 7 of the cylindrical pressure balancing chamber 5 and the compressible insert 6. It can be seen that the fields 9 are provided. In addition, the compressive insert 6 preferably contacts the inner wall 7 of the pressure balancing chamber 5 with pretension in the region of the longitudinal bridges 8 in this embodiment. If there is volume expansion of the fluid medium due to temperature (particularly if the fluid medium freezes while expanding the volume), the compressible insert 6 can be compressed towards the center of the pressure balance chamber 5. At this time, it is advisable to allow the compressible insert 6 to be reversibly deformable.

FIG. 2 shows that four longitudinal channels 9 are arranged in this embodiment at equal intervals over the periphery of the compressible insert 6, with the longitudinal channels 9 of the inner wall 7. It is shown separated from each other by four longitudinal bridges 8. The longitudinal channels 9 and the longitudinal bridges 8 preferably extend parallel to the longitudinal axis L of the connector 1 in this embodiment. Since the compressible insert 6 is coaxially inserted into the pressure balance chamber 5, the compressive insert 6 and the pressure balance chamber 5 have a longitudinal axis L centered at the same center.

The pressure balancing chamber 5 in this embodiment has an annular inner wall 7 spanning on its inner circumference on the one hand and on the other hand the first end wall 10 and the second connection belonging to the first connecting end 3. It has a second end wall 11 which belongs to the end 4. The inner wall 7 thus forms a cylindrical casing, and the end walls 10, 11 form the surfaces of the cylindrical hollow space of the pressure balancing chamber 5. Transverse channels 12 for fluid communication with the longitudinal channels 9 between the compressible insert 6 and the first end wall 10 and between the compressive insert 6 and the second end wall 11. ) Is prepared. The lateral channels 12 are molded in the end walls 10, 11 and are preferably arranged perpendicular to the longitudinal channels 9 in this embodiment. In addition, in the present embodiment, four transverse channels 12 are arranged crosswise in each end wall 10, 11. The lateral channels 12 are directly connected with the corresponding longitudinal channels 9.

In this embodiment (see FIG. 1), the first fluid line 13 attached to the first connecting end 3 is directly connected with the pressure balancing chamber 5, and the first fluid line 13 attached to the second connecting end 4 is provided. It is preferred that the two emulsion lines 14 are connected directly to the pressure balance chamber 5. The longitudinal axis of such fluid lines preferably in this embodiment coincides with the centered longitudinal axis L of the connector 1. Both fluid lines have an inside diameter d which, in the present embodiment, is recommended to be less than one quarter of the inside diameter D of the pressure balancing chamber 5. Here, the inside diameter D of the pressure balancing chamber 5 is measured in the region of the longitudinal bridges 8. In addition, the fluid lines 13, 14 are connected with the longitudinal channels 9 via the lateral channels 12. The longitudinal channels extend in this embodiment over the entire length l of the compressible insert 6, in particular linearly, preferably parallel to the longitudinal axis L of the connector 1. .

In addition, the outer diameter of the compressible insert 6 measured in the region of the longitudinal channels 9 is indicated by "A". The height h of the longitudinal channels 9 corresponds to the distance from the inner wall 7 of the pressure balancing chamber 5 to the compressible insert 6 in the region of the longitudinal channels 9. The width of the longitudinal channels 9 measured across the length 1 of the compressible insert 6 is indicated by “b”.

The connector 1 shown in the accompanying drawings is preferably formed as a quick connector in this embodiment. In particular, the second connecting end 4 is configured to receive a plug or adapter of the receiving element or the pipeline. The second connecting end 4 has an outer spacer element 15, two seal elements 16, 17 formed as an O-ring, and an inner spacer element disposed between both seal elements 16, 17. 18) is provided (see FIG. 1). In addition, a retaining element 19 is provided for locking the plug or adapter not shown.

In FIG. 1, it can be seen that the pipeline 2 shown here is inserted into the receiving portion of the first connecting end 3. The pipeline 2 is material jointed to the first connection end 3, and the material jointed connection is preferably made by a rotation welding method. For that purpose, the first connection end 3 and the pipeline 2 are suitably made of plastics suitable for the material joint connection.

In addition, in FIG. 1, it can be seen that the second connecting end 4 is configured in the form of a female coupling accommodating portion for accommodating the male adapter or plug of the pipeline 2. Basically, the second connecting end 4 can also be provided with a male coupling member, in particular a male coupling member in the form of an adapter of type SAE J2044.

Further, it can be seen from FIG. 1 that the pressure balancing chamber 5 is preferably composed of two parts in this embodiment. It is advisable that the two parts 20, 21 of the pressure balancing chamber 5 are connected to one another, in particular welded together, by material bonding in the connection region 22. In that regard, one configuration within the scope of the present invention is that the two parts 20, 21 of the pressure balancing chamber 5 are made of plastics suitable for material joint connection.

1: connector 3: first connection end
4: second connection end 5: pressure balancing chamber
6: compressible insert 7: inner wall
8: longitudinal bridge 9: longitudinal channel
12: Transverse Channel 13: First End Wall
14: parts of the second end wall 20, 21: 5

Claims (15)

A connector 1 for connecting at least two receiving elements for a fluid medium, for example a pipe connector for connecting two pipelines for a fluid medium,
The connector 1 has a first connecting end 3 for connecting the first receiving element and a second connecting end 4 for connecting the second receiving element,
A fluid medium can flow through the connector 1 between the first connecting end 3 and the second connecting end 4,
The connector 1 has a pressure balance chamber 5 between the first connection end 3 and the second connection end 4, with a compressible insert 6 disposed in the pressure balance chamber 5,
The compressible insert 6 is in contact with the inner wall 7 of the pressure balancing chamber 5 locally, with a first connecting end 3 between the inner wall 7 of the pressure balancing chamber 5 and the compressible insert 6. At least one longitudinal channel 9 is provided for fluid communication between the second connecting end 4,
The connector, which is characterized in that the compressible insert (6) can be compressed, in particular towards the center of the pressure balance chamber (5), in the volume expansion of the fluid medium due to temperature. The connector of claim 1, wherein the fluid medium is urea solution. The connector according to claim 1 or 2, characterized in that the compressible insert (6) can be reversibly deformed. 4. The connector according to claim 1, wherein the compressible insert (6) consists of a plastic foam, preferably a closed cell type plastic foam. 5. The connector as claimed in claim 1, characterized in that the compressible insert (6) consists of a plastic foam of rubber, preferably of plastic foam of EPDM. Connector according to one of the preceding claims, characterized in that the compressible insert (6) is formed compactly. 7. The compressive insert 6 has a hardness (DIN 53505) and / or 0% to 55%, preferably 2 to 25 Shore A, preferably 3 to 20 Shore A. Preferably with 20% to 50% residual compressive strain (DIN 53572, 22 hours, 70 ° C., 50% strain). 8. The connector according to claim 1, wherein the compressible insert (6) is in contact with the inner wall (7) of the pressure balancing chamber (5) locally. The fluid between any of the first connection end 3 and the second connection end 4 between the inner wall 7 and the compressible insert 6 of the pressure balancing chamber 5. A connector, characterized in that a plurality of longitudinal channels (9) are provided for communication. 10. The longitudinal channels 9 are arranged distributed over the circumference of the compressible insert 6, the longitudinal channels 9 being longitudinal in the inner wall 7 of the pressure balancing chamber 5. A connector, which is characterized in that it is separated from each other by bridges (8). The pressure balancing chamber (5) according to any one of the preceding claims, having an annular inner wall (7) and a first end wall (13) and a second end wall (14) over its inner circumference. At least one longitudinal channel 9, preferably a plurality of lengths, between the compressible insert 6 and the first end wall 13 and / or between the compressible insert 6 and the second end wall 14. Connector, characterized in that at least one transverse channel (12), preferably a plurality of transverse channels (12), is provided for fluid communication with the directional channels (9). 12. The second of claim 1, which is connected to the fluid line 13 and / or to the pressure balance chamber 5 of the first connection end 3, which is connected to the pressure balance chamber 5. The fluid line 14 of the connecting end 4 is less than half of the inside diameter D of the pressure balancing chamber 5, preferably less than 1/3, more preferably less than 1/4, very preferably 1 /. And an inner diameter (d) of less than five. 13. The at least one fluid line (13, 14) is connected to at least one longitudinal channel (9) via at least one transverse channel (12), preferably a plurality of transverse channels. A connector, characterized in that it is connected with the longitudinal channels (9) via (12). 14. The pressure balancing chamber (5) according to any one of the preceding claims, wherein the pressure balancing chamber (5) is assembled into a plurality of parts (20, 21), preferably two parts (20, 21). (20, 21) is a connector, characterized in that connected to each other by material bonding. Pipe connector 1 according to any one of claims 1 to 12, preferably at least one of claims 1 to 12, connected to at least one pipeline 2 and an end of the pipeline 2. A pipe connector assembly, comprising two pipe connectors according to claim, wherein a pipe connector (1) is respectively connected to each end of the pipeline (2).

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