DE102022202685A1 - Connector and method of making a connector - Google Patents

Abstract

A plug connector (1) is designed to produce an electrical plug connection with an associated plug-in connector in a plug-in direction (S). The plug connector (1) has an insulating body (20) made of an electrically insulating material and a plurality of electrically conductive contact pins (30) which are at least partially arranged in the insulating body (20). The insulating body (20) is at least partially arranged in a housing (10). The contact pins (30) are pressed watertight into the insulating body (20). A seal (40) seals a gap between the insulating body (20) and the housing (10) in a watertight manner.

Description

The invention relates to a plug connector and a method for producing a plug connector. The connector is used to establish an electrical connection with an associated plug-in connector in a plug-in direction.

Plug connectors for producing electrical plug connections are well known. In order to protect the plug connection and/or the plug connector from damage, it is also known to make plug connectors waterproof. Previously known plug connectors are usually designed to be waterproof in that electrically conductive contact pins arranged inside the plug connector are firmly cast with a casting compound into a housing of the plug connector. The casting compound serves as an insulator between the contact pins and, after hardening and/or drying, seals the contact pins inside the connector in a watertight manner from the insulator itself and the housing.

In order to shape the casting compound, such previously known connectors usually have stops and/or boundary surfaces in order to reduce and/or prevent leakage of the casting compound at least on one side or in several directions. These interfaces are often part of the finished connector and therefore require component space.

The invention is based on the object of enabling a waterproof plug connector with reduced component space requirements, in particular of enabling a plug connector which is shortened in the plugging direction and/or is waterproof.

This task is solved by the subject matter of the independent claims. Preferred embodiments are the subject matter of the dependent claims.

One aspect relates to a plug connector for producing an electrical plug connection with an associated plug-in connector in a plug-in direction. The connector has an insulating body made of an electrically insulating material and a plurality of electrically conductive contact pins that are at least partially arranged in the insulating body. The insulating body is at least partially arranged in a housing of the connector. The contact pins are pressed watertight into the insulating body and a seal seals a gap between the insulating body and the housing in a watertight manner.

The plug connector can be designed, for example, as a socket and/or as a plug connector that can be inserted into a socket. The connector can be designed as a male and/or female connector and have male and/or female plug contacts. The counterpart to the plug connector is the plug-in connector. The electrical plug connection can be produced in the plug-in direction between the plug connector and the plug-in connector, with electrical contacts of the plug-in connector and the plug-in connector making electrical contact. The connector can have a plurality of contact pins, for example 2 to about 50 contact pins, preferably from about 2 to about 20 contact pins, particularly preferably about 10 contact pins. The contact pins can be used to make electrical contact with the plug-in connector, i.e. the contact pins are arranged on the plug-in connector in such a way that they can be electrically contacted by electrical contacts of the plug-in connector in an inserted plug-in position.

The connector can in particular be designed as a circular connector, for example as an M8, M10, M12, M14 or M16 connector.

The insulating body is made of an electrically insulating material, for example made of a plastic, a rubber and/or ceramic. The insulating body can hold the contact pins in the correct position inside the housing of the connector and prevent electrical contact between the contact pins. Furthermore, the insulating body can reduce and/or prevent electrical contact between the contact pins and the housing of the plug connector. The insulating body can be designed as a prefabricated, e.g. solid insulating body, which is not introduced into the connector as a casting compound.

The contact pins can, for example, be made of a metal such as copper and are designed to conduct electrical signals and/or electrical power. The contact pins can be angled or at least partially straight. The contact pins can extend to one end of the plug connector, for example to a plug end, at which the plug connector mechanically contacts the plug-in connector when inserted.

The contact pins can extend to a contact end, which can be formed at an end of the plug connector opposite the plug end. The contact pins can contact other components inside the connector, such as a circuit board, soldering points and/or other contacts. The contacts can be at least at one end, for example as female Plug-in contacts can be formed and have an opening into which electrical contacts of the plug-in connector can engage. Alternatively, the contact pins at the plug end can be designed as male plug contacts. The contact pins can be designed as contact pins that are at least partially identical to one another, for example in pairs. Alternatively, the connector can have at least partially or completely different contact pins.

The housing can be at least partially made of a plastic and/or also made of an electrically insulating material. The housing can at least partially form an outer boundary of the plug connector, which at least partially limits the plug connector to the outside.

The insulating body can be designed in such a way that it can also limit the connector to the outside in certain areas. In particular, the insulating body can at least partially delimit the plug connector at a plug-in surface which is designed to mechanically contact the plug-in connector.

The insulating body of the connector is not cast around the contact pins, but is already formed as a prefabricated component before assembly. The insulating body is therefore already hardened and/or dried before assembly.

The insulating body can have openings into which the contact pins are pressed. These openings can be designed as recesses and/or through holes. The openings can, for example, completely penetrate the insulating body, thereby enabling electrical signal transmission through the insulating body along the contact pin. The insulating body can have at least one through hole as an opening, into which one of the contact pins is pressed in the assembled state. The insulating body can have exactly one associated opening for each contact pin, which can each be designed, for example, as a continuous opening and can completely penetrate the plug connector, for example from the plug end to the contact end.

The dimensioning of the inside diameter of at least one, preferably all, of the openings can be coordinated with the dimensioning of the outside diameter of the associated contact pin. More precisely, the at least one associated contact pin can have, at least in sections, an outer diameter which can be approximately the same size and/or even slightly larger than the inner diameter of the associated opening. When pressing the contact pin into the opening of the insulating body, a press fit can be produced, in which the contact pin and/or the insulating body can be slightly deformed, for example mechanically. This enables a watertight connection of the contact pin to the insulating body.

All contact pins are preferably pressed watertight into assigned recesses in the insulating body. This means that no water can pass through the insulating body along the contact pins along the plug-in direction and/or against the plug-in direction. The waterproofing can be IP68 waterproofing. The press fit can be formed around the contact pin radially to the plug-in direction, so that water cannot penetrate past any side surface of the contact pin in and/or against the plug-in direction.

Since the insulating body is arranged inside the housing, a gap can be present between the insulating body and the housing. This gap is at least partially sealed by the seal. Here too, the seal can provide waterproofing according to IP68. The seal can, for example, be made of a rubber material and seal the gap completely watertight in and/or against the insertion direction. Here, the seal can, for example, be approximately ring-shaped and surround the insulating body continuously and/or uninterrupted radially to the plug-in direction, while it can only be designed in sections in the plug-in direction.

Due to the double sealing along the contact pins and along the insulating body, water penetration of the connector from the plug end to the opposite contact end can be reduced and/or prevented.

Since the connector can be formed without a potting compound, the connector can be designed to be free of stop surfaces. This refers to stop surfaces for the casting compound. There are therefore no stop surfaces required as components which would have to form a casting compound of the insulating body and/or which would have to reduce and/or prevent the casting compound from leaking in at least one direction. As a result, the corresponding component expenditure is reduced and the component space requirement is reduced. The plug connector therefore enables a short component shape, ie a short and/or shortened component length, at least in the plugging direction. The total length in the plugging direction can be shortened by around 20%. The internal space can be reduced by around 30%. The invention therefore makes it possible to have one to provide waterproof and short connectors.

According to one embodiment, at least one of the contact pins has at least one widening approximately perpendicular to the insertion direction. This widening is arranged in a press fit in the insulating body. The widening can be designed as a thickening of the contact pin. The thickening can extend radially around the contact pin, in particular radially around a signal transmission direction of the contact pin. The signal transmission direction of the contact pin corresponds to the direction along which electrical signals and/or electrical power are transmitted along the contact pin in an insertion position. The signal transmission direction can approximately coincide with a longitudinal axis of the contact pin (e.g. arranged approximately parallel to the plug-in direction).

The contact pin can have several such widenings, for example at least 2, 3 or more widenings, which can be formed one behind the other on the contact pin in the signal transmission direction and/or plug-in direction. With the help of these extensions, the contact pin does not have to rest continuously against the recess in the insulating body, but rather it can only rest with the extension or extensions in the insulating body. This reduces the friction when pressing in the contact pins and thereby facilitates and/or improves the assembly of the connector. The watertight compression can be provided at least on the widening(s). Each of the contact pins preferably has at least one such widening.

In a further development of this embodiment, the respective widening is approximately conical around the respective contact pin. As an alternative to a conical shape, the widening can also be designed to taper in or against the plug-in direction and/or signal transmission direction. The taper and/or conical design can simplify insertion of the contact pin into and/or against the plug-in direction and/or signal transmission direction into the insulating body.

According to one embodiment, the seal completely surrounds the insulating body approximately radially to the plug-in direction and/or signal transmission direction. For example, the seal can be applied radially around the insulating body, for example as a sealing lip and/or as an O-ring and/or shaped rubber seal, which can be stretched around the insulating body. As a result, the insulating body is sealed all around radially to the plug-in direction and/or signal transmission direction.

According to one embodiment, the seal is designed as an O-ring, which completely surrounds the insulating body approximately radially to the plug-in direction and/or signal transmission direction. The O-ring can be applied to an approximately circular and/or oval and/or elliptical section of the insulating body. O-rings are standard components that are inexpensive to produce and easily available. They can have well-tested material properties. Therefore, a seal designed as an O-ring can be implemented particularly reliably and cost-effectively.

According to one embodiment, the insulating body and/or the plug connector is designed to be free of casting compound. This means that no component of the connector or at least the insulating body is cast. The insulating body is already prefabricated before assembly.

Not having to cast the contact pins makes it possible to omit stop surfaces for the casting compound and thereby reduce the component size and/or the component cost.

According to one embodiment, the insulating body is designed to be free of alignment elements. In known connectors, the insulating body often has an alignment element, for example a coding lug and/or a coding recess. The alignment element makes it possible to insert the insulating body with the contact pins into the housing in the correct orientation. This is particularly helpful for circular connectors with an insulating body, which has an approximately circular cross-section, at least in some areas. But an alignment element can also be helpful for square connectors with at least partially similar side surfaces. In this case, rotation of the insulating body and/or the contact pins relative to the housing can be prevented, as a result of which the contact pins would be arranged incorrectly inside the housing. The alignment element prevents such incorrect alignment of the contact pins inside the housing. In the connector according to the invention, any such alignment element of the insulating body is dispensed with. This also allows the component size, in particular the component length in the plugging direction, to be reduced. Although this may result in increased effort (e.g. through inspection) when inserting the insulating body into the housing, it does make it possible to reduce the overall component length of the connector.

According to one embodiment, the connector is waterproof according to IP68. IP68 is a protection class that indicates how resistant the connector is to the ingress of foreign objects and water. The fundamental one The meaning of protection class IP68 is known to those skilled in the art from the relevant standards.

According to one embodiment, the connector is designed as a circular connector. Here, the plug connector can be approximately cylindrical, with the cylinder axis being arranged parallel to the plug-in direction and/or signal transmission direction. A first cylinder end can be the plug end of the plug connector, which can at least partially mechanically contact the plug connector when inserted. In this inserted state, the contact pins contact electrically assigned contact pins (and/or similar contacts) of the plug-in connector. An opposite end may be formed as a contact end of the connector. However, the circular connector can also be designed at an angle, i.e., for example, as a cylinder bent and/or angled by approximately 90°. Such angled circular connectors are also generally known.

In principle, in the case of angled connectors, in particular in the case of angled circular connectors, the signal transmission direction can also be angled along the contact pins.

In one embodiment, the insulating body is approximately cylindrical in shape with a cylinder axis aligned approximately parallel to the plugging direction. More precisely, the insulating body can be approximately cylindrical, at least in sections, namely at least along a section adjacent to the plug end. An O-ring can be placed as a seal around the approximately circular cross section of the cylindrical insulating body.

According to one embodiment, the contact pins are approximately rod-shaped. The rod axes extend at least in sections in the insertion direction. At least along this section, the signal transmission direction is also approximately parallel to the plug-in direction. Rod-shaped here means that the contact pins can be approximately cylindrical, with them being significantly longer and/or larger along the cylinder axis than along the cylinder diameter. For example, the cylinder axis (and thus the length of the contact pin) can be at least approximately ten times as large as the cylinder diameter (and thus the thickness of the contact pin). The contact pins are therefore designed as elongated pins. The contact pins do not have to have a circular bar circumference, but rather they can be angular at least in sections and/or have projections and/or lugs.

According to one embodiment, the contact pins penetrate the insulating body from a contact end to a plug end in such a way that they can be electrically contacted at these two ends. At the plug end they can be contacted by assigned contact pins of the plug-in connector. For example, an electrical cable and/or a circuit board and/or another plug connection option can be arranged at the contact end.

According to one embodiment, the insulating body penetrates the housing from a contact end to a plug end. The insulating body insulates the contact pins along the entire length of the connector in the plugging direction. At the plug end, the insulating body can be designed, for example, to mechanically contact the plug-in connector, for example to provide and have a stop surface there.

According to one embodiment, the housing has an external thread with which it can be screwed to an external housing. This allows the housing to be screwed into and/or onto the external housing.

According to one embodiment, the housing has at least one outer seal for watertight sealing a connection between the housing and an external housing. The outer seal can be at least partially made of rubber, for example as an O-ring and/or a sealing lip. This also makes it possible to provide a seal between the housing of the plug connector and the external housing, into which the housing of the plug connector can be inserted and/or to which it can be attached.

• - Bereitstellen eines Isolierkörpers aus einem elektrisch isolierenden Material;
• - Einpressen mehrerer elektrisch leitender Kontaktpins in den Isolierkörper derart, dass die Kontaktpins wasserdicht im Isolierkörper angeordnet sind; und
• - zumindest teilweises Anordnen des Isolierkörpers in einem Gehäuse derart, dass eine Dichtung einen Zwischenraum zwischen dem Isolierkörper und dem Gehäuse wasserdicht abdichtet.

One aspect relates to a method for producing a plug connector for producing an electrical plug connection with an associated plug-in connector in a plug-in direction with the steps:

• - Providing an insulating body made of an electrically insulating material;
• - Pressing several electrically conductive contact pins into the insulating body in such a way that the contact pins are arranged in a watertight manner in the insulating body; and
• - at least partially arranging the insulating body in a housing such that a seal seals a gap between the insulating body and the housing in a watertight manner.

The method can be used in particular for producing a connector according to the aspect described above. That's why all comments on the connector also relate to the process and vice versa.

The insulating body is provided as a prefabricated, hardened component and not as a casting compound. The contact pins are inserted into the insulating body in such a way that they are arranged in a watertight press fit. Here you can ensure that neither the insulator nor the contact pin(s) are damaged during assembly.

According to one embodiment, when the insulating body is arranged in the housing with a predetermined orientation, it is held by a tool in such a way that the insulating body is installed in the housing with this predetermined orientation. The tool is therefore used to hold and/or position the insulating body in a well-defined manner relative to the housing. This makes it possible to dispense with an alignment element on the insulating body. This reduces the required component space. The oriented arrangement of the insulating body in the tool can be accomplished in different ways, for example by well-defined picking up of a pre-oriented insulating body using a robot gripper, image recognition and/or other previously known orientation aids and/or checking means.

In the context of this invention, the terms “substantially” and/or “approximately” may be used to include a deviation of up to 5% from a numerical value following the term, a deviation of up to 5° from a numerical value following the term Direction following the term and/or from an angle following the term.

Terms such as up, down, above, below, laterally, etc. refer - unless otherwise specified - to the reference system of the earth in an operating position of the subject of the invention.

• 1 eine perspektivische Darstellung einer Ausführungsform eines Steckverbinders;
• 2 eine perspektivische Darstellung des Steckverbinders ohne Gehäuse;
• 3 eine Schnittdarstellung durch den Steckverbinder;
• 4 einen Isolierkörper des Steckverbinders in einer Seitenansicht;
• 5 einen Kontaktpin des Steckverbinders in einer Seitenansicht; und
• 6 eine perspektivische Darstellung eines Klemmrings des Steckverbinders.

The invention is described in more detail below using an exemplary embodiment shown in the figures. Individual features shown in the figures can be implemented in other exemplary embodiments. Show it:

• 1 a perspective view of an embodiment of a connector;
• 2 a perspective view of the connector without a housing;
• 3 a sectional view through the connector;
• 4 an insulating body of the connector in a side view;
• 5 a contact pin of the connector in a side view; and
• 6 a perspective view of a clamping ring of the connector.

1 shows a perspective view of an embodiment of a plug connector 1. The plug connector 1 is intended and designed to enter into a plug connection along a plug-in direction S with an assigned plug-in connector not shown in the figures. In the embodiment shown in the figures, the plug connector 1 is designed like a socket, ie the plug-in connector can be plugged into the plug-in connector 1 in the opposite direction to the plug-in direction S. In other embodiments, the connector may have a different configuration.

The plug connector 1 extends in the plugging direction S from a contact end 3 to a plug end 2. At the contact end 3, the plug connector 1 can, for example, contact an electrical cable and/or a circuit board and/or a socket and/or another plug connector.

The plug connector 1 is designed as a circular plug connector, i.e. it is approximately tubular and/or hose-shaped, for example cylindrical. Its cylinder axis and/or hose axis can be aligned approximately parallel to the insertion direction S.

The plug connector 1 has a housing 10, which in the embodiment shown limits the plug connector 1 in all directions radially and/or perpendicular to the plugging direction S to the outside. The housing 10 can also at least partially limit the plug connector 1 in and/or against the plugging direction.

The housing 10 has a plug-in collar 13 at the plug end 2, which is widened in the radial direction in contrast to the rest of the housing body 11. The remaining housing body 11 extends approximately cylindrically from the contact end 3 to the plug-in collar 13.

At the plug end 2, the plug-in collar 13 and thus also the housing 10 have an insertion opening 12. In this insertion opening 12, the plug-in connector, not shown, can be inserted into the plug-in connector 1 in the opposite direction to the plug-in direction S. The insertion opening 12 is designed as a circular recess in the housing 10 against the insertion direction S. At the base of the housing opposite to the plug-in direction S is in the in 1 shown perspective view still an insulating body 20 visible. The insulating body 20 is formed inside the housing 10 and is described below in particular in connection with 2 , 3 and 4 described in more detail.

The housing 10 has at least one alignment element 14 at the insertion opening 12 and/or at the plug-in collar 13. In the embodiment shown, the plug connector 1 has two alignment elements 14 designed as grooves. These enable well-oriented insertion of the plug-in connector into the plug-in connector 1 and vice versa.

The housing 10 has an external thread 15 on an outer surface of the housing body 11. By means of this external thread 15, the connector 1 can be z. B. be screwed into an external housing, not shown, and/or attached to a mating thread.

On its outer surface, the housing 10 also has an additional alignment means, here in the form of a thread groove 16. At the position of the thread groove 16, the external thread 15 is formed with a recess, for example without thread grooves and / or elevations, so that the housing 10 This point can be held in a well-defined manner by a tool, for example.

The housing 10 can be made of a plastic and/or ceramic and, for example, made of an insulating material. The housing 10 serves at least partially as an external termination of the plug connector 1.

2 shows the connector 1 in the in 1 perspective view shown, but without the housing 10.

Shown here is in particular the insulating body 20, in which several contact pins 30 are arranged. The contact pins 30 protrude from the connector 1 at the contact end 3 (see also 1 ). The contact pins 30 are at least partially arranged inside the insulating body 20.

The figures show the plug connector 1 as a straight, i.e. not bent, plug connector 1. The contact pins 30 are straight and also not bent. The contact pins 30 are designed parallel to the plug-in direction S, which is why the signal transmission direction is also arranged approximately parallel to the plug-in direction S.

The insulating body 20 can have several recesses 23 for receiving, storing and/or positioning the contact pins 30. The recesses 23 can be designed as through openings which penetrate the insulating body 20 at least in sections parallel to the insertion direction S.

Since a straight, i.e. not kinked, plug connector 1 is shown in the figures as an exemplary embodiment, the recesses 23 are designed here as straight through holes that completely penetrate the insulating body 20 and are arranged parallel to the plugging direction S. Inside these recesses 23, the contact pins 30 are arranged so that one end of each contact pin 30 protrudes from the contact end 3 and the opposite end of the respective contact pin 30 is arranged adjacent to that end of the insulating body 20, which is arranged adjacent to the plug end 2.

In addition to several contact pins 30, which are designed to conduct electrical signals and/or electrical power, the connector 1 also has a ground pin 39, which in the embodiment shown is not arranged in the insulating body 20, but in a recess in the housing 10. The ground pin 29 can be used to establish contact with the electrical ground. Alternatively or additionally, the arrangement of the ground pin 29 can facilitate well-defined and/or well-positioned contact with an external component at the contact end 3.

The insulating body 20 is essentially cylindrical, with its cylinder axis being arranged approximately parallel to the insertion direction S. At one point on its outer diameter, the insulating body 20 has an elevation 22 which surrounds the insulating body 20 in a ring. A seal 40 is arranged on this elevation 22. The seal 40 can be designed as an O-ring and fit tightly against the insulating body 20. In the exemplary embodiment shown, the seal 40 lies closely against the elevation 22, with the seal 40 radially surrounding the elevation 22, specifically viewed radially in the plug-in direction S and/or signal transmission direction and/or extension direction and/or cylinder axis direction of the plug connector 1. When assembled, the seal 40 creates a watertight seal between the insulating body 20 and the housing 10 around the insulating body 20.

The connector 1 has a further sealing means, namely an outer seal 50. In the assembled state, the outer seal 50 is arranged inside a collar groove 17, which is in 1 is marked with an arrow and which is formed inside the plug-in collar 13. Here, the outer seal 50 can be used to create a watertight connection between the housing 10 and one external housing and/or connection box not shown in the figures.

Furthermore, the connector 1 has a clamping ring 60, which is clamped radially onto the insulating body 20 on the outside. The clamping ring 60 can have several clamping arms 61, which can ensure a secure clamping fit of the clamping ring 60 on the insulating body 20.

3 shows a cross section through the connector 1 along a plane parallel to the plugging direction S.

This sectional view shows in particular the collar groove 17 on the plug-in collar 13 of the housing 10, in which the outer seal 50 is arranged. The collar groove 17 is formed on a surface of the plug-in collar 13 facing away from the plug end 2 (in the exemplary embodiment: annular surface). As a result, the collar groove 17 is covered by the plug-in collar 13 when viewed against the insertion direction S.

The ground pin 39 is arranged inside a recess in the housing 10.

The cutting plane runs approximately in the middle through three contact pins 30, which are arranged inside the respectively assigned recesses 23. These recesses 23 penetrate the insulating body 20 completely from the plug end 2 to the contact end 3.

In the embodiment shown, the connector 1 has nine contact pins 30, of which only one is marked with a reference number in the figures for the sake of clarity. In other embodiments, the connector may have more or fewer contact pins 30. In the embodiment shown, all contact pins 30 are shaped identically. In other embodiments, the connector 1 can have several different contact pins 30.

Each contact pin 30 has at least one widening 33. In the embodiment shown, each contact pin 30 has exactly two widenings 33 spaced apart from one another in the signal transmission direction and/or plug-in direction S, see also 5 . The contact pins 30 are each pressed into the recesses 23 in the insulating body 20 in a watertight press fit. The contact pins 30 can be made so thick at least on the widening(s) 33 that a watertight press fit is formed between the insulating body 20 and the contact pins 30. This prevents water and/or dirt from penetrating through the recesses 23 of the insulating body 20.

The seal 40 can prevent water and/or particles from penetrating between the insulating body 20 and the housing 10 along the plug connector 1, for example in the plugging direction S. Seal 40 together with the press fit of the contact pins 30 in the insulating body 20 thus seals the plug connector 1 watertight in and/or against the plugging direction S, in particular according to IP68.

The seal 40 can be arranged inside an inner groove 18, which is formed from the radial inside in the housing 10 and which annularly surrounds a central axis of the plug connector 1, in particular a cylinder axis approximately parallel to the plug-in direction S. In the embodiment shown, the seal 40 is pressed between an inner surface of the inner groove 18 and an outer surface of the elevation 22 of the insulating body 20.

The contact pins 30 extend from a contact pin contact end 31, which delimits the contact pin 30 at the plug end 2, to a contact pin insertion end 32, which delimits the contact pin 30 at the contact end 3. The contact pin insertion ends 32 can protrude from the insulating body 20 and/or the plug connector 1 at the contact end 3.

Like in particular 3 shown, the connector 1 is designed to be free of casting compound. This means that the insulating body 20 is not cast here from a casting compound, but rather that it is designed as a prefabricated component into which the contact pins 30 are pressed. As a result, the plug connector 1 can be designed to be free of boundary surfaces and/or outflow protection and/or shaping elements for such a casting compound. This saves installation space and enables the length of the plug connector 1 to be reduced, in particular its length in the plugging direction S.

The insulating body 20 can also be designed to be free of alignment elements, which specify an orientation of the insulating body 20. In the exemplary embodiment shown, only the housing 10 can have such alignment elements, namely, for example, the ground pin 39 and/or the grooves of the alignment elements 14 and/or the threaded groove 16 (see also 1 ). The alignment element-free design of the insulating body 20 also reduces the overall installation space required by the insulating body 20. This also makes it possible to provide a plug connector 1 that is short in the plugging direction S.

The plug connector 1 is preferably short in the plugging direction S. This means that the plug connector 1 can be designed to be a maximum of about three times as long in the plugging direction S as it is wide in the radial, i.e. perpendicular to the plugging direction S is trained. The width refers to the extent of the housing 10, i.e. z. B. approximately the cylinder diameter of the housing body 11 without its extensions such as its plug-in collar 13. Preferably, the length from the plug end 2 to the contact end 3 (without the protruding contact pins 30 and / or the ground pin 39) can be a maximum of about twice as long as that Expansion of the housing body 11, again without plug-in collar 13, perpendicular to the plug-in direction S.

4 shows the insulating body 20 in a side view. The insulating body 20 is essentially formed by a cylinder body 21, the cylinder axis of which is arranged approximately parallel to the plugging direction S. From the plug end to the contact end 3, the cylinder body 21 has an approximately constant, i.e. approximately constant, cylinder diameter. The only exception is the annular elevation 22, which surrounds the cylinder body 21 in a ring. In the insertion direction S, the elevation 22 is provided with a stop surface 24 for the clamping ring 60.

Hidden in the side view are the several recesses 23, which can penetrate the insulating body from the plug end 2 to the contact end 3. In the assembled state, all of the recesses 23 are sealed by a contact pin 30 each. This insulating body 20 therefore has exactly as many recesses 23 as contact pins 30 will later be pressed into it. This results in the tightness of the insulating body 20 in and/or against the plug-in direction S in the assembled state.

5 shows one of the contact pins 30 in a side view. In the embodiment shown, the contact pin insertion end 32 is designed as a male plug contact, while the contact pin contact end 31 is designed as a female plug contact.

The contact pin 30 has at least one widening 33 designed, for example, as an elevation, preferably at least two widenings 33. The widenings 33 can have a taper, for example a taper in the insertion direction S towards the normal outer diameter of the contact pin 30. This taper, which can be conical, for example can, simplifies inserting the contact pin 30 into the recess 23 (cf. 3 ) in the direction of the taper, so in the exemplary embodiment, for example, in the plugging direction S. The widening 33 widens the outer diameter of the contact pin 30 in all radial directions to the plugging direction S in a ring and without gaps. This allows the widenings 33 to be pressed in the recesses 23 in a watertight manner.

In other embodiments, the connector can have differently designed contact pins 30, e.g. angled contact pin plugs designed as male on both sides, female on both sides, etc.

In particular, the contact pins can be angled and/or connected on one side to a circuit board and/or a cable.

6 shows the clamping ring 60 in a perspective view. The clamping ring 60 has an annular body 62, which can be placed around the outside of the insulating body 20 so that it radially surrounds the insulating body 20 from all sides. The ring body 62 is therefore designed as a closed ring body 62 and has no interruption.

Adjacent to the ring body 62, the clamping ring 60 has a plurality of clamping arms 61. With these, a clamping fit of the clamping ring 30 on the insulating body 20 can be achieved. In the assembled state, the clamping ring 60 is arranged between the housing 10 and the insulating body 20, see also 3 . The clamping arms 61 can prevent the clamping ring 60 from slipping out in the insertion direction S. Contrary to the plug-in direction S, the stop surface 24 on the elevation 22 of the insulating body 20 can prevent the clamping ring 60 from slipping down and/or slipping.

This means that the clamping ring 60 can be firmly fastened between the insulating body 20 and the housing 10 in the assembled state. The clamping ring 60 can be designed as an optional component, which simplifies the assembly of the insulating body 20 in the housing 10. In other embodiments, the plug connector 1 can be designed without a clamping ring.

If the insulating body 20, as shown, does not have any alignment means, such as a coding nose, it can be introduced into the interior of the housing 10 in a controlled manner. For this purpose, it can be held pre-oriented by a tool (not shown in the figures) so that it can be inserted into the housing 10 correctly aligned. There the insulating body 20 can be firmly connected to the housing by the clamping ring 60. In the embodiment shown, the insulating body 20 can first be inserted into the housing 10 against the insertion direction S until the elevation 20 abuts an internal narrowing of the housing 10. From the other side, the clamping ring 60 can then be pushed over the insulating body 20 up to the elevation 22 over the insulating body 20 until a firm connection between the insulating body 20 and the housing 10 is provided.

This allows a short connector 1 to be provided, which is designed to be waterproof and requires less installation space.

Reference symbol list

1

Connectors

2

Stuck end

3

End of contact

10

Housing

11

Case body

12

Insert opening

13

Stuck collar

14

Alignment element

15

External thread

16

thread groove

17

collar groove

18

Internal groove

20

insulating body

21

Cylinder body

22

survey

23

recess

24

stop surface

30

Contact pin

31

Contact pin contact end

32

Contact pin insertion end

33

widening

39

Ground pin

40

poetry

50

External seal

60

Clamping ring

61

Clamp arm

62

Ring body

S

Plugging direction

Claims (12)

Plug connector (1) for establishing an electrical plug connection with an associated plug-in connector in a plug-in direction (S), the plug-in connector (1) having: - an insulating body (20) made of an electrically insulating material; - a plurality of electrically conductive contact pins (30) arranged at least partially in the insulating body (20); and - a housing (10) in which the insulating body (20) is at least partially arranged; where: - the contact pins (30) are pressed watertight into the insulating body (20) and - A seal (40) seals a gap between the insulating body (20) and the housing (10) in a watertight manner. Plug connector (1). Claim 1 , wherein at least one of the contact pins (30) has at least one widening (33) approximately perpendicular to the plug-in direction (S), and this widening (33) is arranged in a press fit in the insulating body (20). Plug connector (1). Claim 2 , whereby the respective widening (33) is approximately conical around the respective contact pin (30). Plug connector (1) according to one of the preceding claims, wherein the seal (40) completely surrounds the insulating body (20) approximately radially to the plugging direction (S). Plug connector (1) according to one of the preceding claims, wherein the seal (40) is designed as an O-ring which completely surrounds the insulating body (20) approximately radially to the plugging direction (S). Plug connector (1) according to one of the preceding claims, wherein the insulating body (20) and/or plug connector (1) is designed to be free of casting compound. Plug connector (1) according to one of the preceding claims, wherein the insulating body (20) is designed to be free of alignment elements. Plug connector (1) according to one of the preceding claims, wherein the plug connector (1) is designed to be waterproof according to IP68. Plug connector (1) according to one of the preceding claims, wherein the plug connector (1) is designed as a circular plug connector. Plug connector (1) according to one of the preceding claims, wherein: - the insulating body (20) is approximately cylindrical in shape with a cylinder axis aligned approximately parallel to the plug-in direction (S); and/or - the contact pins (30) are approximately rod-shaped and the rod axes extend at least in sections in the plug-in direction (S); and/or - the contact pins (30) penetrate the insulating body (20) from a contact end (3) to a plug end (2) in such a way that they can be electrically contacted at these two ends; and/or - the insulating body (20) is the housing (10) of one Contact end (3) penetrates to a plug end (2); and/or - the housing (10) has an external thread (15) with which it can be screwed to an external housing; and/or - wherein the housing (10) has at least one outer seal (50) for watertight sealing of a connection between the housing (10) and an external housing. Method for producing a plug connector (1) for producing an electrical plug connection with an associated plug-in connector in a plug-in direction (S), with the steps: - Providing an insulating body (20) made of an electrically insulating material; - Pressing a plurality of electrically conductive contact pins (30) into the insulating body (20) in such a way that the contact pins (30) are arranged in a watertight manner in the insulating body (20); and - at least partially arranging the insulating body (20) in a housing (10) in such a way that a seal (40) seals a gap between the insulating body (20) and the housing (10) in a watertight manner. Procedure according to Claim 11 , wherein the insulating body (20) is held by a tool when placed in the housing (10) with a predetermined orientation in such a way that the insulating body (20) is installed in the housing (10) with this predetermined orientation.

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