WO2023099173A1

WO2023099173A1 - Locking mechanism for a modular plug connector, and modular plug connector

Info

Publication number: WO2023099173A1
Application number: PCT/EP2022/081735
Authority: WO
Inventors: Oliver Schneider
Original assignee: Lisa Dräxlmaier GmbH
Priority date: 2021-11-30
Filing date: 2022-11-14
Publication date: 2023-06-08
Also published as: DE102021131376B3

Abstract

The invention relates to a locking mechanism (102) for a plug connector (100). The locking mechanism (102) has two locking elements (104), at least one gearing mechanism (106), and an actuating lever (108). The locking elements (104) are arranged on opposite sides of a housing (110) of the plug connector (100) and are movably mounted on the housing (110) transversely to a plug-in direction (112) of the plug connector (100), wherein the gearing mechanism (106) is arranged on the housing (110) between the locking elements (104), and the actuating lever (108) is rotatably mounted on the housing (110) about a rotational axis (114). The locking elements (104) and the actuating lever (108) are coupled to the gearing mechanism (106), and the gearing mechanism (106) is designed to convert a rotational movement (114) of the actuating lever (108) about the rotational axis (114) into locking movements (118) of the locking elements (104) running in the opposite direction.

Description

Lisa Dräxlmaier GmbH Landshuter Str. 100 D-84137 Vilsbiburg

LOCKING MECHANISM FOR A MODULAR CONNECTOR AND MODULAR CONNECTOR

technical field

The present invention relates to a locking mechanism for a modular connector and a modular connector.

State of the art

The present invention will be described in the following mainly in connection with connectors for vehicles.

A plug connector can have a large number of contact elements. The contact elements can be aligned essentially parallel to one another in a plug-in direction of the connector. Each contact element can be arranged at one end of a stranded wire and snapped into its own contact cavity of the connector. The strands of several or all contact elements can be bundled into a cable. The cable may be part of a vehicle wiring harness.

The contact elements are guided laterally by the plug connector and fixed axially in the plug-in direction. When the connector is mated with a mating mating piece, the contact elements are also mated with their respective mating pieces. When mating, the plug connector can snap into a plugged-in position on the mating piece, for example by means of a latching device. To do this, the connector is moved axially into the counterpart until the latching device engages, for example audibly.

Description of the invention

It is therefore an object of the invention to provide an improved locking mechanism for a modular plug connector, as well as an improved modular plug connector, using means that are as simple as possible in terms of design. An improvement here can concern, for example, a simplified merging of the plug connector with its opposite.

The object is solved by the subject matter of the independent claims. Advantageous developments of the invention are specified in the dependent claims, the description and the accompanying figures.

In the approach presented here, a connector is locked simultaneously in two places by an actively operable locking mechanism. For locking, a lever arranged on the connector is moved manually or automatically from a plugged-in position into a locking position. The actuating lever acts mechanically on two opposing locking elements. When locking, the locking elements bring about a form fit and/or force fit to a counterpart of the plug connector. When the operating lever is in the locked position, the connector is securely mated to the mating connector. The position of the operating lever can be visually checked at any time. For example, a loose connector can be detected immediately.

Due to the opposing locking elements, the resultant opposing locking forces cancel each other out. In this way, a one-sided force on the connector can be avoided during locking.

The locking mechanism presented here can be used particularly advantageously on a modular connector, since an insertion direction of Can match plug modules of the connector with a direction of movement of the locking elements substantially. As a result, both the plug connector and the locking mechanism can be equipped or assembled in an automated manner in a particularly good manner. In particular, the locking elements can be components of a housing of the plug connector and, in the installed state, can close assembly openings or openings for equipping the housing with the connector modules.

According to a first aspect of the invention, a locking mechanism for a connector is presented, the locking mechanism having two locking elements, at least one gear and an actuating lever, the locking elements being arranged on opposite sides of a housing of the connector and on the housing transversely to an insertion direction of the connector are movably mounted, the gear being arranged between the locking elements on the housing and the actuating lever being mounted on the housing so as to be rotatable about an axis of rotation, the locking elements and the actuating lever being coupled to the gear, the gear being designed to cause a rotary movement of the actuating lever to convert the axis of rotation into opposite locking movements of the locking elements.

In particular, the connector can be modular. The housing can be designed in particular to accommodate at least two connector modules arranged next to one another in a transverse direction.

According to a second aspect of the invention, a modular plug connector is presented, the plug connector having a housing that is divided in a transverse direction and composed of two housing shells, in which at least two connector modules arranged next to one another in the transverse direction are arranged, with at least one of the connector modules per housing shell on one on an inner side of the housing shell arranged in a longitudinal direction and the plug modules are connected to one another via a longitudinally arranged double linear guide of a connector for connecting the plug modules, wherein the housing shells are connected to one another at least in the transverse direction via the plug modules and the connector. The connector may have a locking mechanism according to the first aspect of the invention. In particular, the locking movement can run in the longitudinal direction.

A connector can enable a pluggable connection in at least one electrical line. The connection can be connected and disconnected again. An electrically conductive contact can be produced by electrical contact elements arranged in the plug connector or in a counterpart. Contact elements can be, for example, contact pins or contact pins or contact blades or contact lugs. To establish the connection, the connector can be plugged into the counterpart in a plugging direction, plugged onto the counterpart or plugged over the counterpart. To separate the connection, the plug connector can be pulled off the mating piece in the opposite direction to the insertion direction. The connector can be referred to as a plug. The counterpart can be referred to as a socket, socket or header. The connector can be arranged at one end of a particularly flexible cable or cable harness. Cores or strands of the cable can be connected to the contact elements.

A locking mechanism can mechanically lock the connector when making the connection to the mating part. For this purpose, the locking mechanism can be operated manually or automatically. The locking mechanism can be operated via an operating lever. The actuating lever can drive a gear of the locking mechanism. The gear can act on locking elements of the locking mechanism. In the locked state, the locking mechanism can prevent the connector from being pulled off the counterpart. In the locked state, the locking mechanism can produce a form fit and/or force fit of the locking elements to the counterpart. The form fit and/or force fit can prevent a relative movement between the plug connector and its counterpart, particularly in the plugging direction.

A transmission can have a gear ratio. The gear ratio can represent a ratio between an actuation force of the actuation lever and a locking force of the locking elements. The actuating force required on the actuating lever to lock the connector can be Gear ratio be smaller than the locking force of the locking elements. The transmission ratio of the forces can be inversely proportional to a transmission ratio of the paths.

A housing can enclose components of the connector and provide protection against external influences. In particular, the housing can protect a transition area between the wires or strands and the contact elements. The housing can protect the components from moisture, splashing water and/or dust, for example. The transition area can be arranged inside the housing. The housing can be a structural part of the connector. The housing can have bearing points for the locking mechanism. The housing can have linear guides on its inside for plugging in connector modules. The guides can be referred to as linear guides. The guides can be aligned in a longitudinal direction transverse to the plug-in direction of the connector.

The housing can be composed of two housing shells. The housing shells can have a parting plane spanned by the insertion direction and the longitudinal direction. One linear guide can be arranged in one of the housing shells.

The connector modules can be components of the connector. The connector modules can be configured differently. For example, the connector modules can accommodate different numbers and/or line cross sections of contact elements. The connector modules can have chambers for accommodating the contact elements. In particular, the chambers can be aligned in the plug-in direction of the connector. The connector modules can have two oppositely aligned receptacles for linear guides in a transverse direction oriented transversely to the longitudinal direction and transversely to the plug-in direction. The two receptacles can be shaped identically. The connector modules can therefore be pushed onto two linear guides in the longitudinal direction. Several connector modules can be pushed one behind the other in the longitudinal direction onto a linear guide. The connector modules can be automatically pushed onto the linear guides of the housing. A double linear guide can be pushed into the free receptacle of a connector module arranged on the opposite side in order to connect two connector modules side by side in the transverse direction connect. The connector modules can also be pushed onto the double linear guide first. The double linear guide can be arranged in the parting plane. As a result, two rows of connector modules aligned in the longitudinal direction can be arranged in the housing. The rows may be juxtaposed in the transverse direction. Different connector modules can be arranged in the two rows. If a total length of a row is less than a nominal size, a dummy module can be inserted in the row to increase the length to the nominal size. The empty module can also be arranged between two connector modules.

The double linear guide arranged in the transverse direction between the rows of connector modules can be part of a connector. The connector can mechanically connect the housing shells to one another via the connector modules.

The linear guides and/or the double linear guide can be designed as a dovetail guide. A dovetail guide can allow linear movement along the longitudinal direction and transmit forces transverse to the longitudinal direction. A dovetail guide can have two guide surfaces aligned at an angle to one another. The dovetail guide may have a trapezoidal cross-section. A seat for the dovetail guide can have a corresponding trapezoidal cutout. Due to the inclined guide surfaces, the dovetail guide has an undercut, particularly in the transverse direction, for the transmission of forces in the transverse direction. Forces in the insertion direction can also be absorbed via the guide surfaces of the dovetail guide.

The connector can have at least two locking slides aligned parallel to the double linear guide for locking the contact elements of the connector modules. The locking slides can be pushed into the connector modules at the same time as the double linear guide. The connector modules can have at least one recess for the locking slides, which is aligned in the longitudinal direction. When pushed in, the locking slides can engage in recesses in the contact elements and prevent axial movements of the contact elements in the connector modules by means of a positive fit. In particular, the connector can have four locking slides that are pushed into the connector modules on both sides. As a result, the contact elements can be locked in both connector modules from both sides. The transmission can be a toothed wheel transmission with a toothed wheel rotatable about the axis of rotation and two toothed racks. The operating lever can be coupled to the gear wheel. The locking elements can each be coupled to one of the toothed racks. The racks can mesh with the gear on opposite sides of the gear. A linear locking movement can be achieved by means of a gear train with toothed racks. The opposing locking movements result from the opposing engagement in the gear wheel. The transmission ratio of the gear depends on a meshing radius of the gear. The transmission ratio can be constant over the actuation movement.

The gear can be a lever gear with two connecting rods. The actuating lever can be coupled to both coupling rods. The locking elements can each be coupled to one of the coupling rods. The connecting rods can be coupled to the actuating lever on opposite sides of the axis of rotation. The opposite locking movements result from the coupling with the actuating lever on different sides of the axis of rotation. The locking elements can be rigidly connected to the coupling rods. This results in a slightly curved locking movement of the locking elements. Likewise, the locking elements can be mounted so as to be linearly movable and can be connected to the coupling rods via joints. In both cases, the transmission ratio of the lever mechanism changes depending on the position of the operating lever. The lever mechanism can be designed as a toggle lever mechanism. To reach a locking position, a dead center of the toggle mechanism can be exceeded. Then the toggle mechanism can be self-locking. The transmission ratio of the forces can have a maximum in the area of the dead center.

The gear can be a slotted link gear with two, in particular spiral-shaped, slides that can be rotated about the axis of rotation and two sliding blocks. The actuating lever can be coupled to the slides. The locking elements can each be coupled to one of the sliding blocks. Each sliding block can intervene in one of the slides. The links can be arranged on opposite sides of the axis of rotation. A gate can be a slot with a curved shape in particular. The backdrops form sloping levels on which the sliding blocks when the operating lever is actuated slide off The sliding blocks can be rotatably mounted on the locking elements. Then the sliding blocks can rest against the respective link with a sliding surface. Likewise, the sliding blocks can be rigidly coupled to the locking elements. The sliding blocks can then have essentially linear contact surfaces with the links.

The locking mechanism can have two gears arranged on opposite side surfaces of the housing. The locking elements and the actuating lever can enclose the housing up to the side surfaces. The gears can be coupled in the area of both side surfaces with both locking elements and the actuating lever. The gears can be the same. The operating lever can operate both gears in parallel. The gears can drive simultaneous locking movements on both sides of the housing. Simultaneous locking movements can prevent the locking elements from tilting on the housing. With two gears, the operating force can be evenly distributed into the housing. As a result of the actuating lever encompassing the housing, asymmetrical loading of the housing when the locking mechanism is actuated can be avoided. Two gears can be dimensioned smaller than a single gear.

The housing can be composed of two housing shells each having one of the side faces. The actuating lever can be mounted separately in the two housing shells so that it can rotate. The actuating lever can press the housing shells together by means of a prestressing force. The housing shells can be mirror-symmetrical to the parting plane. The housing shells can be connected to one another at the parting plane. The connector can be built symmetrically to the parting plane. The connector can have one of the gears per housing shell. The locking elements can encompass the two housing shells and connect the housing shells to one another via their bearings. The locking elements stabilize the overall connection of the housing.

The actuating lever can engage in a locking position on the housing or on one of the locking elements. Alternatively or additionally, the actuating lever can be moved as a toggle lever beyond a dead center of the transmission until it engages. Through a latching of the actuating lever in a locking position, an unintentional opening of the locking mechanism can be prevented. However, the locking mechanism can be opened at any time by disengaging the actuating lever.

The locking elements can be mounted on the housing so that they can move linearly perpendicularly to the plug-in direction. The locking elements can be mounted on the housing by at least one further linear guide. The further linear guide can be arranged on an outside of the housing. For example, the further linear guide can be designed as a dovetail guide.

The locking elements can each have at least one locking pin aligned transversely to the insertion direction. The locking pin can be moved into a recess of the counterpart by the locking movement. The locking pin and/or the recess can have an inclined plane aligned obliquely to a direction of the locking movement for converting the locking movement into a plugging movement directed in the plugging direction. Alternatively, the counterpart for each of the locking elements can have a corresponding locking pin, while the locking elements each have a corresponding recess. Locking pins engaging in corresponding recesses can produce a form fit between the plug connector and the counterpart due to the locking movements. A mating force for connecting the contact elements to their corresponding counterparts can be generated via the inclined planes. The incline of the locking in the counterpart supports the locking or closing movement and reduces the effort required.

Brief character description

An advantageous exemplary embodiment of the invention is explained below with reference to the accompanying figures. Show it:

1 shows a representation of a connector with a locking mechanism according to an embodiment; 2 shows a representation of a connector with a counterpart according to an embodiment;

3 shows a representation of a modular connector according to an embodiment; and

4 shows a representation of a modular connector with a locking mechanism according to an embodiment.

The figures are schematic representations and only serve to explain the invention. Elements that are the same or have the same effect are provided with the same reference symbols throughout.

Detailed description

1 shows an illustration of a connector 100 with a locking mechanism 102 according to an embodiment. The locking mechanism 102 has two locking elements 104, a gear 106 and an actuating lever 108. The locking mechanism 102 is movably mounted on a housing 110 of the plug connector 100 .

The locking elements 104 are arranged on opposite sides of the housing 110 . The locking elements 104 are movably mounted on the housing 110 transversely, preferably perpendicularly, to a plug-in direction 112 of the connector 100 . The actuating lever 108 is mounted on the housing 110 so that it can rotate about an axis of rotation 114 . The axis of rotation 114 is aligned transversely, preferably perpendicularly, to the insertion direction 112 . The gear 106 is arranged between the locking elements 104 on the housing 110 and coupled to the actuating lever 108 and the locking elements 104 . The transmission 106 is designed to convert a rotational movement 116 of the actuating lever 108 about the axis of rotation 114 into two opposing, essentially linear locking movements 118 of the locking elements 104 . The locking movements 118 are aligned transversely, preferably perpendicularly, to the insertion direction 112 and transversely, preferably perpendicularly, to the axis of rotation 114 . In one exemplary embodiment, the transmission 106 is designed as a gear transmission 107 . The gear train 107 has a gear wheel 120 and two toothed racks 122 . Gear 120 is coupled to operating lever 108 . The toothed racks 122 are each coupled to one of the locking elements 104 . The toothed racks 122 engage in the gear wheel 120 on opposite sides of the axis of rotation 114 and thus generate the locking movements 118 in opposite directions.

Here the gear wheel 120 is connected in one piece to the actuating lever 108 and is mounted on an outside of the housing 110 such that it can rotate about the same axis of rotation 114 . The toothed racks 122 are connected in one piece to the locking elements 104 and are movably mounted with the locking elements 104 on the outside of the housing 110 .

In one exemplary embodiment, the locking mechanism 102 has two gears 106 . The gears 106 are located on opposite sides of the housing 110 . The actuating lever 108 is approximately U-shaped and is rotatably mounted on the axis of rotation 114 on both sides of the housing 110 . The locking elements 104 are also approximately U-shaped and are movably mounted on both sides of the housing 110 . The actuating lever 108 and the locking elements 104 are each coupled to a gear 106 on both sides.

In one embodiment, the two transmissions 106 are of the same type. Here both gears 106 are pinion gears 107, each with a gear 120 and two racks 122.

In one exemplary embodiment, the actuating lever 108 has a latching device 124 . The latching device 124 latches in a locking position of the actuating lever on the housing 110 and/or one of the locking elements 104 and prevents the actuating lever 108 from moving back into a plugged-in position.

2 shows an illustration of a connector 100 with a counterpart 200 according to an embodiment. The connector 100 essentially corresponds to the connector in FIG. The counterpart 200 has a base plate 202 and a peripheral edge 204 . A multiplicity of electrical contact elements 206 are arranged in a plurality of groups 208 in the base plate 202 . The groups 208 have different contact elements 206 . The groups 208 are spaced from each other by gaps. The contact elements 206 are aligned in the insertion direction 112 and penetrate the base plate 202.

The edge 204 runs around the base plate 202 substantially perpendicularly to the base plate 202 . The housing 110 of the connector 100 is aligned with the rim 204 and is guided laterally by the rim 204 . The rim 204 is arranged on an inside of the housing 110 . The connector 100 is plugged over the counterpart 200 here.

The rim 204 has two recesses 210 . The recesses 210 are arranged on opposite sides of the base plate 202 . The recesses here are square openings through the edge 204 with a slope along a side of the recess 210 facing away from the base plate 202.

The recesses 210 are counterparts to the locking pins 212 of the locking mechanism 102 of the plug connector 100. The locking pins 212 are moved into the recesses 210 by the locking movements 118 of the locking elements 104. The locking pins 212 slide off the slopes and pull the connector 100 onto its counterpart 200.

When the locking pins 212 are arranged in the recesses 210, they create a form fit between the connector 100 and the counterpart 200.

The locking elements 104 are pressed against the edge 204 by the locking movements 118 and thus produce a non-positive connection between the plug connector 100 and the counterpart 200 .

3 shows an illustration of a modular connector 100 according to an embodiment. The connector 100 essentially corresponds to the connector in FIG. 1. The connector 100 has a housing 110 composed of two housing shells 300 . One of the housing shells 300 is here for Showing an inside 302 of the housing 110 not shown. Each housing shell 300 has a linear guide 304 on the inside 302 . The linear guide 304 extends in a longitudinal direction 306 of the housing 110 transversely to the plug-in direction 112 along the housing shell 300.

For each housing shell 300, several connector modules 308 can be pushed one behind the other in a row onto a linear guide 304. The connector modules 308 each have a plurality of contact chambers 310 for contact elements. Before being pushed onto the linear guide 304, the connector modules 308 are equipped with the contact elements and stranded wires, which are not shown here. When pushed on, the strands are arranged in a cable outlet 312 of the housing shell 300 .

The connector modules 308 have lateral receptacles 314 for sliding onto the linear guide 304 . A connector module 308 has two similar receptacles 314 . The receptacles 314 are arranged on opposite side faces of the connector modules 308 . In this way, the connector modules 308 can be connected both to one housing shell 300 and to the other housing shell 300 .

A double linear guide 316 of a connector 318 is pushed into the respective free receptacle 314 . The connector 318 thus connects plug modules 308 arranged next to one another in a transverse direction 320 oriented transversely to the longitudinal direction 306 . If several connector modules 308 are arranged as rows one behind the other, the connector 318 connects the rows to one another in the transverse direction 320 . Since the connector modules 308 are connected to this housing shell 300 via the linear guide 304 of the respective housing shell 300 , the connector 318 connects the two housing shells 300 to one another via the connector modules 308 .

In one exemplary embodiment, the connector modules 308 have a coding 322 on end faces pointing in the longitudinal direction 306 . Here the coding 322 is implemented via four bolts 324 protruding from the plug module 308 in the longitudinal direction 306 . The bolts 324 correspond to corresponding recesses in the connector modules 308 on the end face opposite the bolts 324 . The row of connector modules 308 can already be pushed onto the linear guide via the bolts 324 and recesses 304 can be assembled. If the coding 322 does not match, the connector modules 308 cannot be plugged together to form the row.

In one embodiment, connector 318 includes at least two locking slides 326 . The locking slides 326 are arranged parallel to the double linear guide 316 and are pushed into corresponding recesses in the connector modules 308 . The locking slides 326 lock the contact elements in their contact chambers axially in the insertion direction 112.

In one embodiment, the linear guides 304 are designed as dovetail guides 305 . The dovetail guides 305 are designed as a trapezoidal projection protruding from the respective housing shell 300 and extending in the longitudinal direction 306 . The receptacles 314 are accordingly designed as trapezoidal recesses made from the respective connector module 308 and extending in the longitudinal direction 306 . As a result, the dovetail guides 305 and the receptacles 314 each have two guide surfaces which are oriented obliquely to the transverse direction 320 and obliquely to the insertion direction 112 and on which the dovetail guides 305 and the receptacles 314 lie flat against one another.

FIG. 4 shows an illustration of a modular connector 100 with a locking mechanism 102 according to an embodiment. The connector 100 essentially corresponds to the connector in FIG. 3, the locking mechanism 102 essentially corresponds to the locking mechanism in FIG. 1. In contrast to FIG. 1, the actuating lever is not shown here.

Here, a pair of connector modules 308 arranged next to one another in the transverse direction 320 is pushed into the housing 110 in the longitudinal direction 306 . The connector modules 308 are pushed onto the linear guides 304 of the housing shells 300 and are connected to one another in the transverse direction 320 by the double linear guide 316 of the connector 318 . The connector 318 thus connects the two housing shells 300 via the connector modules 308. The connector 318 here has four locking slides 326 arranged in parallel. The locking slides 326 are pushed into recesses of the plug modules 308 on both sides of the plug modules 308 and lock the contact elements of the plug modules 308 axially. The locking slides 326 are connected to one another via webs 400 running in the transverse direction 320 . The webs 400 stiffen the locking slides 326 in the transverse direction 320 and prevent the locking slides 326 from migrating in the transverse direction 320.

The locking elements 104 are essentially U-shaped and enclose the two housing shells 300. The locking elements 104 are movably mounted on both housing shells 300 in external linear guides 304 of the housing shells 300 in the longitudinal direction 306 and hold the housing shells 300 together in the transverse direction 320. The locking elements 104 have been pushed into the outer linear guides 304 after the connector modules 308 have been pushed onto the inner linear guides 304 of the housing shells 300 and the connector modules 308 have been connected by the double linear guide 316 of the connector 318 . The locking elements 104 thereby close openings in the housing 110 in the longitudinal direction 306 through which the connector modules 308 have been pushed onto the inner linear guides 304 . The locking pins 212 of the locking elements 104 protrude into an interior of the housing 110.

In other words, the system of a modular connector is presented.

The connector is configured to receive various modules equipped with electrical contacts in a housing. The connector can be assembled automatically. The housing is sealed against the ingress of water droplets.

The modules are pushed in and picked up laterally in two halves of the housing. The secondary locking of the individual contacts takes place via a slide. The housing cover is also the locking mechanism for the header using a tooth system. The individual modules are coded to ensure that they cannot be confused. The approach presented here makes it easier to securely mount modules in a housing. Automated assembly is possible. The construction of the housing and the locking mechanism enables a seal to the header.

The plug has two half-shells for modular accommodation and a side lock. The cable exit is on the side, but can also be implemented via a cover ring. The modules are mounted on a rail system. Locking (CPA) is via sliders on the outside and in the middle. The side locking in the circuit board cover is done with the side covers. The lock is driven by racks and sprockets on the bracket.

The modules are coded using coding pins and coding holes. The modules can be coded via a number of coding pins and coding holes and/or via positions of the coding pins and coding holes.

For assembly, the modules with contacts and stranded wires (not shown) are pushed into the half-shells via the dovetail guide. The half-shells are then brought together and connected with a locking pin. The locking pin is also the secondary locking mechanism for the contacts.

Then the side covers and the locking bracket are mounted with the sprocket. The side covers have teeth for the locking mechanism and a locking bolt for the header. The half-shells are fixed using the locking bracket. CPA is done with the latch bracket and housing and is not shown here for simplicity.

The header has locking slots with guide bevels.

Since the devices and methods described in detail above are exemplary embodiments, they can be modified to a large extent in the customary manner by a person skilled in the art without departing from the scope of the invention. In particular, the mechanical arrangements and the size ratios of the individual elements to one another are merely exemplary REFERENCE LIST

100 plug-in or

102 locking mechanism

104 locking elements

106 gears

107 gear transmission

108 operating lever

110 housing

112 mating direction

114 axis of rotation

116 rotary motion

118 locking movement

120 gear

122 rack

124 locking device

200 counterpart

202 base plate

204 edge

206 contact element

208 group

210 recess

212 locking pin

300 case shell

302 inside

304 linear guide

305 dovetail guide

306 longitudinal direction

308 connector module

310 contact chamber

312 cable outlet

314 recording 316 double linear guide

318 connectors

320 transverse direction

322 coding 324 bolt

326 locking slide

400 footbridge

Claims

EXPECTATIONS

1. Locking mechanism (102) for a connector (100), wherein the locking mechanism (102) has two locking elements (104), at least one gear (106) and an actuating lever (108), the locking elements (104) on opposite sides of a housing (110) of the plug connector (100) are arranged and are movably mounted on the housing (110) transversely to an insertion direction (112) of the plug connector (100), the gear (106) between the locking elements (104) on the housing (110) is arranged and the actuating lever (108) is mounted on the housing (110) so that it can rotate about an axis of rotation (114), the locking elements (104) and the actuating lever (108) being coupled to the gear (106), the gear (106 ) is designed to convert a rotational movement (114) of the actuating lever (108) about the axis of rotation (114) into opposite locking movements (118) of the locking elements (104).

2. Locking mechanism (102) according to claim 1, in which the gear (106) is a toothed gear (107) with a gear (120) rotatable about the axis of rotation (114) and two toothed racks (122), the actuating lever (108) having is coupled to the gear (120) and the locking elements (104) are each coupled to one of the racks (122), the racks (122) on opposite sides of the gear (120) meshing with the gear (120).

3. Locking mechanism (102) according to claim 1, in which the gear (106) is a lever gear with two coupling rods, the actuating lever (108) being coupled to both coupling rods and the locking elements (104) each being coupled to one of the coupling rods, wherein the coupling rods are coupled to the actuating lever (108) on opposite sides of the pivot axis (114).

4. Locking mechanism (102) according to claim 1, in which the gear is a link gear with two links rotatable about the axis of rotation (114) and two sliding blocks, wherein the actuating lever (108) is coupled to the links and the locking elements (104) each are coupled to one of the sliding blocks, one sliding block each engaging in one of the links and the links being arranged on opposite sides of the axis of rotation (114).

5. Locking mechanism (102) according to one of the preceding claims, with two gears (106) arranged on opposite side surfaces of the housing (110), the locking elements (104) and the actuating lever (108) encompassing the housing (110) up to the side surfaces and the gears (106) are coupled to both locking elements (104) and the actuating lever (108) in the region of both side surfaces.

6. Locking mechanism (102) according to claim 5, in which the housing (110) is composed of two housing shells (300) each having one of the side surfaces and the actuating lever (108) is rotatably mounted in both housing shells (300), the actuating lever ( 108) presses the housing shells (300) together by means of a prestressing force.

7. locking mechanism (102) according to any one of the preceding claims, wherein the actuating lever (108) engages in a locking position.

8. locking mechanism (102) according to any one of the preceding claims, wherein the locking elements (104) perpendicular to the direction of insertion (112) are mounted linearly movable on the housing (110).

9. Locking mechanism (102) according to one of the preceding claims, in which the locking elements (104) each have at least one locking pin (212) aligned transversely to the plug-in direction (112) and which, as a result of the locking movement (118), moves into a recess (210) of a counterpart (200) is moved in, with the locking pin (212) and/or the recess (210) forming an inclined plane aligned obliquely to a direction of the locking movement (118) for converting the locking movement (118) into one in the insertion direction (112) directed plug-in movement.

10. Modular connector (100) with a locking mechanism (102) according to any one of claims 1 to 9, wherein the connector (100) in a transverse direction (320) has a divided housing (110) composed of two housing shells (300), in which at least two connector modules (308) arranged next to one another in the transverse direction (320) are arranged, with at least one of the connector modules (308) per housing shell (300) pushed onto a linear guide (304) arranged on an inner side (302) of the housing shell (300) in a longitudinal direction (306) and the plug modules (308) via a double linear guide (316) of a connector (318) arranged in the longitudinal direction (306) for connecting the connector modules (308) to one another, the housing shells (300) being connected to one another at least in the transverse direction (320) via the connector modules (308) and the connector (318), the locking movement (118) being in the longitudinal direction ( 306) runs.