EP0364978A1 - Transition coupling for rail vehicles - Google Patents

Abstract

The transition coupling for rail vehicles has an automatic coupling head 7 which is displaceable relative to a coupling arm 1 and can be locked by a locking mechanism 4, 21 in its rear position, which can be adjusted against the force of a spring device 24. Furthermore, a coupling member 12 is provided which is longitudinally displaceable relative to the coupling head 7 and can be locked in its rear position by a further locking mechanism 15, 20. In the respective front positions, if there is longitudinal coupling play, simple coupling of the coupling head 7 to an automatic matching coupling head or manual coupling of the coupling member 12 to a hook coupling on a matching vehicle is possible. The locking mechanisms 15, 20 and 4, 21 can be operated by turning a hand lever 22; they automatically engage at the appropriate turned position of the lever 22 under the gravitational load of the same as soon as the coupling head 7 or the coupling member 12 are in the respective rear position. During engagement, the locking mechanisms 15, 20 and 4, 21 respectively slightly exceed a dead-centre position. For easy, manual disengagement, the engagement points of the locking mechanisms can be displaced in an at least roughly frictionless manner past the dead-centre position by common movement of the engaging parts of the locking mechanisms. During tensile loading of the coupling head or the coupling member 12, the further disengagement operation is thus effected by auxiliary labour with only a slight expenditure of force. <IMAGE>

Description

The invention relates to a transition train coupling for rail vehicles for coupling both with an automatic mating coupling head and with a manual hook coupling, with an automatic coupling head which is longitudinally displaceable relative to a coupling arm and which, from a front position which can be set automatically in the absence of a mating coupling head, by means of pressure load when starting at a mating coupling head a rear position is displaceable, with a first, effective between the coupling arm and the coupling head locking mechanism, which engages automatically when the rear position of the coupling head is reached and holds the coupling head in this position and which is provided with a manually operated release device for disengaging, with one Relative to the coupling head, slidably mounted, hook or eye-like coupling element for coupling with a hook coupling, and with a second, between the coupling head and the dome rgan effective locking mechanism, which automatically engages after the coupling element has been moved back from its front into its rear position and holds the coupling element in the rear position and which is also provided with a manually operable release device for disengaging.

From DE-OS 37 10 030 it is already known for a train coupling to mount an automatically coupling coupling head in a longitudinally displaceable manner on a coupling arm. Here, a button is also provided, which disengages the locking mechanism when there is no gene coupling head, so that the coupling head is automatically moved under spring force from its rearward position to the front position, in which an unimpeded coupling from side buffers is also possible on track curves. The locking mechanism also has a manual release device, by means of which it can be adjusted by hand from its latching position to the disengaging position, so that the coupling head can also reach its front position when a mating coupling head is present, which makes it easier to uncouple the coupling heads, for example, by creating a longitudinal coupling play becomes. With coupling heads under tension, this tension penetrates the locking mechanism, and frictional forces can occur in it, which can make manual disengagement of the locking mechanism considerably more difficult.

From DE-OS 36 00 843 a transition coupling for rail vehicles is also known, in which in an automatic coupling head a rod-like coupling element at its front end carrying a coupling eye or a coupling hook is mounted for longitudinal displacement. The coupling element can be pulled out manually against the spring force from the coupling head to its front position, in which it can easily be coupled to a hook coupling of an opposing vehicle; in the event of a lack of tensile load due to the hook coupling coupled with it, the coupling element is drawn into the coupling head by the spring force mentioned and reaches its rearward position in which it is locked by means of an automatically engaging locking mechanism. To facilitate subsequent decoupling operations, the locking bar is equipped with a manually operated release device provided by which it can be triggered. The coupling element can then be pulled into its front position while forming a longitudinal coupling play, the longitudinal coupling play facilitates manual uncoupling. Since the locking mechanism is traversed by tensile forces which are exerted on the coupling element by the hook coupling, the actuation of the release device and thus the triggering of the locking mechanism can be severely hampered by frictional forces in the locking mechanism when the coupling element is under such tensile stress.

The above-mentioned tensile forces can result from side buffers partially compressed in the rearward position of the coupling head or coupling member.

It is an object of the invention to provide a transition pull coupling of the type mentioned at the outset, which thus comprises a combination of the above-mentioned known devices, with the simplest possible system for manual release of the locking mechanism.

This object is achieved according to the invention in that a single, common manual operating device is provided for disengaging for both release devices. With this single, common manual control device, the construction effort required can be kept low.

According to patent claim 2, it is expedient according to the further invention for a transitional pull coupling designed in this way if the manual operating device has a manual lever on each side of the vehicle. With only one hand lever on each side of the vehicle, the release devices can be actuated easily and securely.

If, according to the further invention, the transition pull coupling is designed according to the features of claim 3 in such a way that the locking mechanism have dead center positions which are immediately before their snap-in positions, at the beginning of manual ones Disengaging the locking engagement points is at least approximately frictionless, if necessary by moving the engaged locking parts together until the dead center position, manual disengagement of the locking is easy and with little effort even with tensile stress on the part of the mating coupling or Side buffer standing transition train coupling possible.

According to the further invention, the further patent claims show advantageous and expedient further training options for the transition pull coupling.

• Fig.1 den Aufbau der Übergangszugkupplung in schematischer Seitenansicht,
• Fig.2 die Koppelung des Tasters mit dem ersten Gesperre in schematischer Ansicht von vorne etwa entsprechend der Schnittlinie A-A in Fig.1 und
• Fig.3 eine Aufsicht auf die wesentlichen Teile des Tasters nach Fig.2 in dort angedeuteter Blickrichtung B.

In the drawing, an embodiment of a transition pull coupling designed according to the invention is shown, and shows

• 1 shows the structure of the transition pull coupling in a schematic side view,
• 2 shows the coupling of the button with the first locking mechanism in a schematic view from the front approximately according to the section line AA in FIG. 1 and
• 3 shows a top view of the essential parts of the push button according to FIG.

According to FIG. 1, a coupling arm 1 has a bearing eye 2 at its rear end, which is shown in FIG. 1 in a position rotated by 90 ° and by means of which it is pivoted on a rail vehicle by a vertical bolt. The storage can be designed such that the coupling arm 1 can also be deflected up and down by limited distances. The coupling arm 1 extends essentially forward in the vehicle longitudinal direction, at its front end it carries an essentially right-angled cantilever locking part 3 with a rear stop surface 4. On the coupling arm 1, an automatic coupling head 7 is mounted longitudinally displaceably by means of indicated guides 5 and 6, the guides 5 and 6 have a vertical play 8. The coupling head 7 is of a type suitable for automatic pulling couplings, for example it corresponds in a manner not shown to the Willison type, each with a pulling and pushing claw and a conventional locking gear. In the coupling head 7, a rod-like coupling element 12 is mounted in a longitudinally displaceable manner by means of guides 9 and 10 with a vertical play 11. The coupling element 12 has at its front end, which can be pulled out of the coupling head 7 against a spring (not shown), an eyelet 13 which is shown rotated by 90 ° in FIG. 1 and which can be hooked into the coupling hook of a manual hook coupling of a vehicle to be coupled. Instead of the eyelet 13, a hook can also be provided, in which the coupling chain of the hook coupling of the vehicle to be coupled can be hung. At its rear end, the coupling element 12 carries a locking part 14 with a forwardly facing stop surface 15; the locking part 14 is in a position set back to the locking part 3, such that the stop surfaces 4 and 15 face each other at a great distance. Approximately midway between the locking parts 3 and 14, a horizontal Ouerwelle 16 is rotatably mounted in the coupling head 7, on which a two-armed locking lever 17 is fastened such that it can be rotated in the coupling head 7. The two lever arms of the locking lever 17, which are at an almost extended angle to one another, form pawls 18 and 19, the pawl 18, which in the rotational position shown points approximately horizontally backwards, on the lever arm end face one stop-like pawl surface 20 and the other, essentially forwards and only slightly Downward facing pawl 19 also carries a pawl surface 21 on the lever arm end face. In the illustrated rotational position of the locking lever 17, the pawl surface 20 and the stop surface 15 opposite each other, they form the first locking mechanism 15, 20, while the pawl surface 21 is below and in front of the stop surface 4, with which it forms the second locking mechanism 4.21. The cross shaft 16 carries on both sides of the coupling head 7 a hand lever 22, which run parallel to each other and of which only one is shown in Figure 1; in the illustrated rotational position of the locking lever 17, the hand lever 22 is inclined backwards-upward, it is in a position II. In a manner to be described later, the hand lever 22 is in a position I pointing approximately horizontally backwards and in the opposite direction of rotation into a rotational position III and further, after exceeding a vertical rotational position, adjustable into a rotational position IV pointing obliquely forward-up; it can be seen that gravity tries to turn the lever 22 from position III to position II and further to position I while keeping it stable in position IV.

The pawl 19 has in the lower region of the pawl surface 21 a stop 23 which projects in the extension direction of the pawl 19 and which can cooperate positively with the underside of the locking part 3 in order, as will be described later, to displace the coupling arm 1 while displacing the vertical play 8 from as shown in Fig.1, the top on the bottom of the coupling arm 1 in the guide 5 and 6, respectively.

Obliquely below and backwards of the coupling head 7 there is a suspension device 24, which is supported at its lower, rear end against a vehicle frame part 25 and, on the other hand, against the coupling head 7 by means of an arm 26 which projects obliquely forward and upward. The suspension device 24 has a spring 28 clamped between a rear spring plate 27 of the arm 26 and the vehicle frame part 25 and an additional spring 30 intercepted by a tie rod 29 in the position according to FIG. 1 at a certain distance in front of the spring plate 27 against the vehicle frame part 25.

In FIG. 1, a lever 31 is also indicated, which belongs to a scanning device for the presence of a mating coupling head, which is not shown in FIG. 1 but can be more precisely removed from FIGS. 2 and 3. According to FIG. 2, the upper end of the lever 31, which can be pivoted essentially in a transverse plane, is articulated to a button 32 which, depending on the presence of a mating coupling head from its left-hand position shown in dashed lines in FIG. 2, with a mating coupling head present horizontally and transversely to the longitudinal direction of the coupling in the position shown in solid lines is movable in the absence of a counter coupling head. For this purpose, the button 32 is to be arranged on the coupling head 7 in dependence on its coupling profile in such a way that it projects in the position shown in FIG , which in the coupled state is occupied by part of the mating coupling head, in the example by its impact claw. For its guidance, the push button 32 according to FIG. 3 can be articulated on a further, essentially horizontal lever 33, the other end of which can be rotated about a vertical bolt 34 of the coupling head 7. A compression spring 35 loads the pushbutton 32 in the direction of movement to its position shown in solid lines in FIGS. 2 and 3 in the absence of a counter coupling head; the other end of the compression spring 35 is supported against an abutment 36 of the coupling head 7. In the absence of a mating coupling head, the lever 31 extends approximately vertically downward, its lower end is rotatably articulated by means of a pin 37 on the upper end of a further lever 38, the lower end of which is articulated by means of a pin 39 on the pawl 19 near its pawl surface 21. To the side of the lever 38 there are guide surfaces 40 of the coupling head 7, which only permit vertical displacements of the lever 38. The guide surfaces 40 can also be arranged on the pawl 19. The two levers 31 and 38 thus together with the guide surfaces 40 constitute a toggle linkage 41 which, when a counter coupling head is removed by stretching the two levers 31 and 38, the pawl 19 in the lowering direction of its pawl surface 21 turns. The locking part 3 is, as can also be seen from FIG. 2, when the toggle linkage 41 is stretched to the side of the lever 38 and thus above the pawl surface 21;

In the illustration according to FIG. 1, the coupling head 7 is located on the coupling arm 1 in its front, uncoupled position which is ready for the coupling n with a counter coupling head. The first locking mechanism formed from the stop surface 4 and the latch surface 21 is disengaged, the latch surface 21 is located below and in front of the stop surface 4. The suspension device 24 holds the coupling head 7 in this position by means of its spring force. The button 32 is, as already mentioned, in the position shown in solid lines in FIGS. 2 and 3, the toggle linkage 41 is stretched. The coupling element 12 is located in its rearward, retracted position relative to the coupling head 7, the stop surface 15 engages behind the pawl surface 20, the second locking mechanism 15, 20 is thus engaged and precludes advancement of the coupling element 12 relative to the coupling head 7. The hand lever 22 is in the position II, further rotation under the aforementioned gravity or spring action into the position I is excluded by the pawl 19 resting against the lower limit of the locking part 3.

If a mating coupling head (not shown) runs from the front, i.e. from the left, according to FIG. 1 to the coupling head 7 during a coupling process, the coupling head 7 is pressed back relative to the coupling arm 1 to the right against the force of the spring 28 of the suspension device 24 when the coupling process is completed until, in the rear position of the coupling head 7, the pawl surface 21 comes behind the stop surface 4, the pawl 19 thus comes out of engagement with the underside of the locking part 3. The hand lever 22 can now rotate under the action of gravity or spring from the position II to the position I, with the transverse shaft 16 the locking lever 17 is also rotated. During this rotation, the pawl surface 20 remains in front of the stop surface 15, the second locking mechanism 15, 20 thus remains in engagement, while the pawl surface 21 is rotated behind the stop surface 4 by the rotation of the pawl 19, the first locking mechanism 4, 21 thus engages and in reaches its blocking position. By the first locking mechanism 4, 21, the coupling head 7 is thus locked in its rearward position relative to the coupling arm 1, which, as described in detail in the aforementioned DE-OS 37 10 030, eliminates the coupling longitudinal play after the automatic buffering process, which is unimpeded by the side buffer .

If the coupling head 7 is pushed back relative to the coupling arm 1 via the mentioned rear position with the first locking mechanism 4, 21 just engaged, then at the beginning of this further return movement in the suspension device 24 the spring plate 27 comes to rest against the front end of the additional spring 30 or its Tie rod 29, so that in the further return movement of the coupling head 7, the additional spring 30 must be compressed in addition to the spring 28 and thus there is an increased resistance to this further moving back of the coupling head 7. This further, increased resistance causes a counter coupling head of the same design to be pushed back up to its rear position on its coupling arm 1 against a non-increased resistance, so that its first locking mechanism can engage. Only if the side buffers compressive pressure forces occur between the coupled vehicles, does the coupling head 7 move out of its rearward position relative to the coupling arm 1 against the summed and thus increased force of the spring 28 and the additional spring 30 further backwards. After the pressure force mentioned has subsided, the springs 28 and 30 of the suspension device 24 advance the coupling head 7 until the pawl surface 21 strikes the stop surface 4.

During the start of the mating coupling head, the button 32 according to FIG. 2 is moved from the position shown in solid lines to the position shown in dashed lines, the toggle linkage 41 coming into its knocked-out position by tilting the lever 31 and the aforementioned rotary movement of the hand lever 22 from the position 11 supports the position I by lifting the front end of the pawl 19.

If the mating coupling head is removed from the coupling head 7 in a subsequent decoupling process, the compression spring 35 moves the push button 32 back from the position shown in broken lines to the position shown in solid lines, the toggle linkage 41 stretching again and the pawl 19 following by turning the locking lever 17 in this way presses below that the pawl surface 21 disengages from the stop surface 4, that is, the first locking mechanism 4, 21 disengages. When the locking lever 17 rotates, the hand lever 22 is raised from its position I to the position II. After disengaging the locking mechanism 4, 21, the spring 28 of the suspension device 24 presses the coupling head 7 from its rearward position into the front position shown in FIG. 1, relative to the coupling arm 1, so that the position ready for coupling is automatically obtained.

During the above-described processes, the coupling element 12 remains in its rearward position relative to the coupling head 7.

If, starting from the vehicle shown in FIG. 1, is to be coupled with a vehicle having a hook coupling, the hand lever 22 is to be raised from position II to position III, the pawl surface 20 being pivoted away from the stop surface 15 by turning the pawl 18 upwards and the second locking mechanism 15, 20 is thus disengaged. The first locking mechanism 4, 21 remains disengaged; to enable the downward rotation of the pawl 19 can on the mounting of the pin 37 by the rotational movements of the Lever 31 switchable, in the position with no counter coupling head disengaged driving device can be provided, which uncouples the toggle linkage 41 in such a way that with the button 32 remaining in its height, the latch surface 21 can pivot downward. Instead, a Lanlochführung can be provided on the bolt 37 or 39. After the locking mechanism 15, 20 has disengaged, the coupling element 12 can be pulled forward against a spring force (not shown) relative to the coupling head 7, as a result of which, as described in detail in the aforementioned DE-OS 36 00 843, manually in a simple manner Hook coupling of the opposite vehicle can be coupled. The clutch play between the coupled vehicles after this coupling process is automatically switched off as soon as the vehicles are brought closer to each other until the side buffers come into contact during subsequent driving processes or by a printing process following the coupling process: under its spring load, not shown, or under low pressure loads of rarely the The hook coupling moves the coupling element 12 backwards relative to the coupling head 7 until it reaches the rear position shown in FIG. 1 and the hand lever 22 automatically rotates from its position III under the force of gravity or spring to the position 11. When the hand lever 22 rotates, the pawl 18 reaches with its pawl surface 20 in front of the stop surface 15, as a result of the second locking mechanism 15, 20 engaging, the coupling element 12 is again locked in its rearward position relative to the coupling head 7.

For the subsequent uncoupling, the hand lever 22 is to be raised again to position III, the locking mechanism 15, 20 being disengaged by turning the pawl 18. The coupling element 12 can then be moved forward relative to the coupling head 7, as a result of which it reaches a position that can be easily uncoupled from the hook coupling. After release of the coupling element 12, the spring force (not shown) already mentioned pulls the coupling element 12 back into the coupling head 7 into the rear position after it has been reached the hand lever 22 automatically returns from position III to position II under the force of gravity or spring loading and the locking mechanism 15, 20 engages again by pivoting the pawl surface 20 in front of the stop surface 15.

During the coupling processes described by means of the coupling element 12, the coupling head 7 remains in its front position, shown in FIG. 1, relative to the coupling arm 1. The position II of the hand lever 22 is determined by the toggle linkage 41 or the contact of the pawl 19 on the lower surface of the locking part 3.

From Fig. 1 it can be seen that when the ratchet 15, 20 is engaged, the coupling member 12 rests on the underside of the guides 9, 10, so that the vertical play 11 is located inside the guides 9 and 10 above the coupling member 12. The pawl 18 is in such a rotational position that the contact center between the pawl surface 20 and the stop surface 15 is located just below a horizontal plane through the axis of the transverse shaft 16; the locked ratchet 15, 20 is thus in a position that has exceeded a dead center position in the direction of latching: in the event of tensile stresses on the coupling element 12, for example by a coupled hook coupling, this causes the engagement center of the ratchet 15, 20, which is lower than the axis of the transverse shaft 16, to engage it in the latching direction Locked torque on the pawl 18, an automatic, unwanted disengagement is excluded. If the locking mechanism 15, 20 is to be disengaged manually by turning the hand lever 22 into the position III under the mentioned stress, this would be without the special design of the guides 9, 10 with the vertical play 11 only by overcoming the high friction between the abutting surface pressed against one another 15 and pawl surface 20, so possible with great effort and thus very difficult. Due to the special design of the guides 9 and 10 with vertical play 11, however, the manual lifting of Hand lever 22 from position II in the direction of position III under the frictional engagement of the pawl surface 20 with the stop surface 15 lifting at least the rear part of the coupling element 12 in the context of the vertical play 11, the center of engagement between the ratchet surface 20 and the stop surface 15 through the horizontal plane the axis of the cross shaft 16 is raised; in this lifting process, at most low frictional forces in the guides 9 and 10, but no high frictional forces in the locking mechanism 15, 20 are to be overcome. During this lifting process, the dead center position of the locking mechanism 15, 20 in the direction of its release is exceeded, the tensile stress of the coupling element 12 causes, via the stop surface 15 on the pawl surface 20, a force component acting in its lifting direction, which causes the pawl 18 to be turned up and thus the pivoting movement of the hand lever 22 supported in the direction of position III and thus enables the frictional forces between the engaging pawl surface 20 and stop surface 15 to be overcome with little effort. In summary, when the hand lever 22 is raised from position II to position III when the coupling element 12 is under tension, the dead center position of the locking mechanism 15, 20 is initially exceeded at least almost frictionlessly by lifting the center of engagement of this locking mechanism and then the locking mechanism 15, 20 with auxiliary support solved by the force loading the coupling element 12 with little effort.

The locking mechanism 4, 21 is designed in a similar manner in such a way that it can also be easily manually disengaged under load: when the locking mechanism is engaged, that is, if the pawl surface 21 is behind the stop surface 4, the stop 23 lies against the locking part 3 from below and lifts the coupling arm 1 relative to the coupling head 7 in such a way that it is located in the guides 5 and 6 in its upper position, in such a way that the vertical play 8 is located below the coupling arm 1, in deviation from the illustration in FIG. With tensile stresses of the coupling head 7 by a Counter coupling head and correspondingly pressed pawl surface 21 and stop surface 4 is their contact center just above the horizontal plane through the axis of the transverse shaft 16, that is in a position beyond the dead center position of the locking mechanism 4, 21 in the latching direction. The tensile load on the coupling head 7 results with respect to the pawl 19 a force component acting in its direction of rotation for engaging the locking mechanism 4, 21, so that the locking mechanism 4, 21 cannot unintentionally disengage. The hand lever 22 is, as already mentioned above, in its position I and also loads the locking mechanism 4, 21 due to its heavy or spring loading in the latching direction.

If the hand lever 22 is moved from its position I in the direction of the position II to disengage the locking mechanism 4, 21, the pawl 19 initially conveys its pawl surface 21 to the stop surface 4 and thus the locking part 3 and the coupling arm 1 relative to the coupling head 7 by frictional engagement downwards with, the contact center of the locking mechanism 4, 21 being shifted below the above-mentioned horizontal plane through the axis of the transverse shaft 16 and thus this transgression of the dead center position is in turn almost frictionless and therefore possible with little effort, during this shifting the coupling arm 1 gets into the Lower position shown in the guides 5 and 6, the vertical play 8 is shifted from below to above the coupling arm 1. After the dead center position has been exceeded in this way, the tensile force loading of the coupling head 7 in the locking mechanism 4, 21 results in a force component acting in its release direction, which tries to turn the pawl 19 further counterclockwise according to FIG. 1 and thus the rotary movement of the hand lever 22 to position II supported. The friction between the pawl surface 21 and the stop surface 4 can therefore be overcome with only a small amount of force on the hand lever 22, the locking mechanism 4, 21 can thus be easily released altogether manually by turning the hand lever 22 into the position II.

In a modification of the described embodiment, it may be sufficient if only the guide 5 or 10 closer to the lock has a vertical play 8 or 11 and the other guide 6 or 9 enables less rotation.

In a modification of the exemplary embodiment described above, it is possible to couple the lever 38 on the toggle linkage 41 with the omission of the bolt 39 and its optionally provided elongated hole guide or the coupling device on the bolt 37 by means of a simple stop coupling to the front end of the pawl 19. Taking into account the elimination of the support for the rotary movement of the clinker 19 for engaging the locking mechanism 4, 15 during the return movement of the button 32 during coupling operations with a mating coupling head, this ensures that the hand lever 22 while the pawl 19 is lowered from the lever 38 without influencing the toggle linkage 41 in the disengaged ratchets 4, 21 and 15, 20 corresponding rotary position III is adjustable.

For maneuvering, it can be useful if neither the coupling head 7 is locked relative to the coupling arm 1 nor the coupling member 12 relative to the coupling head 7 in the respective rear position. Such a function can be adjusted by setting the hand lever 22 to the IV position: in this position of the hand lever 22, both locking mechanisms 4, 21 and 15, 20 are disengaged and the hand lever 22 together with the locking lever 17 and thus the pawls 18 and 19 is released Gravity or spring force held in position IV. Regardless of forward or backward movements of the coupling head 7 and / or the coupling element 12, the locking mechanism 4, 21 and 15, 20 remain disengaged, so the longitudinal coupling play is retained both when coupling with a mating coupling head and with a hook coupling. By moving the hand lever 22 back into position III and, in the corresponding positions of the coupling head 7 or the coupling element 12 into positions II or further I, the locking mechanisms 15, 20 and 4, 21 can be switched back into their latchable or locked state.

From the above description it can be seen that the transition pull coupling with a very simple construction enables safe and easy coupling and uncoupling with the existing longitudinal coupling play, automatic deactivation of the coupling longitudinal play in the coupled state and auxiliary power-assisted switching on of the coupling longitudinal play even with couplings under tensile force and also a switch-off option for offers the automatic elimination of the longitudinal coupling play.

Of course, it is possible to deviate from the exemplary embodiments described above by providing the directions of movement and pivoting of individual or all parts of the transition pull coupling in a position rotated about the longitudinal direction of the coupling, for example in a position rotated by 90 ° in the horizontal planes.

Reference symbol list

• 1 clutch arm
• 2 bearing eye
• 3 blocking part
• 4 stop surface
• 5 leadership
• 6 leadership
• 7 coupling head
• 8 vertical play
• 9 leadership
• 10 leadership
• 11 vertical play
• 12 dome
• 13 eyelet
• 14 blocking part
• 15 stop surface
• 16 cross shaft
• 17 locking lever
• 18 jack
• 19 jack
• 20 jack surface
• 21 jack surface
• 22 hand lever
• 23 stop
• 24 suspension device
• 25 vehicle frame part
• 26 arm
• 27 spring washers
• 28 spring
• 29 tie rods
• 30 additional spring
• 31 levers
• 32 buttons
• 33 levers
• 34 vertical bolts
• 35 compression spring
• 36 abutments
• 37 bolts
• 38 levers
• 39 bolts
• 40 guide surface
• 41 toggle linkage

Claims (12)

1.Transition cable coupling for rail vehicles for coupling both with an automatic counter coupling head and with a manual hook coupling, with an automatic coupling head (7) which is longitudinally displaceable relative to a coupling arm (1) and which can be adjusted from a front position that is automatically adjustable in the absence of a counter coupling head by means of pressure load when starting is displaceable to a mating coupling head into a rear position, with a first locking mechanism (4, 21) which acts between the coupling arm (1) and the coupling head (7) and which engages automatically when the coupling head (7) reaches the rear position and the coupling head (7) holds in this position and which is provided with a manually operable release device for snapping on, with a hook or eye-like coupling member (12) mounted longitudinally displaceable relative to the coupling head (7) for coupling with the hook coupling, and with a second one between the coupling head (7 ) and the coupling element (12) effective locking mechanism (15, 20), which engages automatically after the coupling element (12) has been moved back from its front position to its rear position and holds the coupling element (12) in the rear position and which is also operated manually actuatable release device is provided for disengagement, characterized in that a single, common manual actuation device (22, 16, 17) is provided for disengagement for both release devices. 2. transition pull coupling according to claim 1, characterized in that the manual control device (22, 16, 17) has a hand lever (22) on each side of the vehicle. 3. transition coupling according to claim 1 or 22, characterized in that the locking mechanism (15, 20; 4, 21) have dead center positions which are immediately before their locking positions, the locking engagement points being at least approximately frictionless, if appropriate, at the start of manual disengagement processes by moving the engaged locking parts (14, 18; 3, 19) together until they can be shifted beyond the dead center position. 4. transition pull coupling according to claim 3, characterized in that the locking engagement points of the two locking mechanisms are independently displaceable. 5. transition pull coupling according to claim 3 or 4, wherein the locking mechanism as a substantially perpendicular to the tensile stress of the coupling head (7) or the coupling member (12) detachable ratchet mechanism (15, 20; 4, 21) with manually movable pawl (18, 19) is formed, characterized in that a with the pawl (18, 19) cooperating locking part (14; 4) of the pawl ratchet (15, 20; 4, 21) in the direction of movement of the pawl (18, 19) for disengaging from a normal position to Exceeding the dead center position can be deflected against an elastic force. 6. Transitional pull coupling according to claim 5, characterized in that the manual operating device has a hand lever (22) which can be rotated by means of a transverse shaft (16) in the coupling head (7) and which is connected to a two-armed locking lever (17), the one in or against the direction of the tensile stress adjustable lever arms pawls (18; 19) with stop-like pawl surfaces (20; 21) located on the lever arm end faces, a rear pawl surface (20) having a stop surface (15) on one Locking part (14) of the coupling element (12) and a front pawl surface (21) a stop surface (4) on a locking part (3) of the coupling arm (1) can be compared that the hand lever (22) in a first, locked two ratchets (4th , 21 and 15, 20), a second, latched locking mechanism (15, 20) only for the coupling element (12), a third, disengaged two locking mechanisms (4, 21 and 15, 20) and a fourth, deactivated locking mechanism (4, 21 and 15, 20) corresponding rotational position (I to IV) is adjustable, and that the hand lever (22) with the locking lever (17) is held by spring or gravity in the first rotational position (I), in the second and third rotational position ( II and III) is loaded in the direction of rotation to the first rotational position (I) and is self-retaining in the fourth rotational position (IV). 7. transition cable coupling according to claim 6, characterized in that the coupling element (12) and the coupling arm (1) are each mounted at least in the region of the locking parts (3; 14) on the coupling head (1), whereby they move against the direction of movement to disengage with them cooperating latch surfaces (20, 21) are loaded by gravity or spring force. 8. Transitional pull coupling according to claim 6 or 7, characterized in that a stop (23) is arranged on at least one pawl surface (21), which holds the locking part (3) in the normal position in the locked position in a form-fitting manner. 9. transition pull coupling according to claim 6, with a on the coupling head (7) mounted button (32) which moves forward when removing a mating coupling head from a rear to a front position and thereby releases the first locking mechanism (4, 21), characterized in that the button (32) rotates the locking lever (17) in the direction of disengagement of its front pawl surface (21) from the stop surface (4) of the coupling arm (1) during its advancement. 10. transition cable coupling according to claim 9, characterized in that a toggle linkage (41) is provided, which couples the button (32) with a near the front pawl surface (21) located point of the locking lever (17) and which by means of sliding guide (40) its knee (37) stretches when the button (32) is advanced. 11. transition coupling according to one or more of the preceding claims, wherein the coupling head (1) is displaceable against an elastic force, characterized by a force threshold located immediately behind its rearward position, which increases the elastic force. 12. transition pull coupling according to claim 11, wherein the coupling head (7) against a spring (28) is displaceable, characterized in that the force threshold is given by striking the coupling head (7) on an intercepted additional spring (30).

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