WO2004089727A1 - Module pertaining to a compartment element safety cell for a means of transport - Google Patents

Abstract

The invention relates to a module pertaining to a safety cell of a means of transport, for example a motor vehicle, a boat or an aeroplane or the like. Said module is characterised in that it consists of at least one frame constructed from at least three closed, interpenetrating rigid frame planes (1, 2, 3, 5), said at least three frame planes (1, 2, 3, 5,) being connected in a positively locking manner and forming three intersecting planes that are at an angle to each other, preferably a right angle. At least one of the frame planes (1, 2, 3, 5) is horizontally arranged and embodied as a load-carrying plane, and preferably vertical sections (4, 4') of the frame planes (1, 2, 3, 5) form the outer edges of the module. The inventive module is also characterised in that at least one pressure ring or ellipse (6, 6 , 6′′) embodied as a force carrier is arranged in the plane of at least one of the frame planes (l, 2, 3, 5) in a rigid and positively locking manner, and/or two interpenetrating struts are interconnected in a positively locking manner and are at an angle to each other, preferably a right angle.

Description

Module of a space element safety cell for traffic and Trans ^p ortmittel

The invention relates to a module of a security cell of a means of transport or transportation, for example a motor vehicle, a ship or aircraft and the like. like.

The invention set forth in DE 42 04 826 AI relates to intermediate pieces as rod extrusions between hollow profiles. This is intended to ensure increased absorption or the transfer of forces between the hollow profiles. The main focus of this invention is the reinforcement in the connections, in no case is there a closed safety cell, it is spoken of hollow profiles arranged offset in the vertical direction.

The invention set forth in DE 42 08 408 AI is a tension element attached to the passenger compartment, which is designed in particular for lateral or oblique side impacts, the forces being passed on as deflection points via deflection points. Under no circumstances is there a self-contained safety system that encompasses the entire vehicle.

In DE 39 33 417 AI it is proposed according to the invention to produce a reinforcement in the form of sheet metal layers arranged one above the other with intermediate layers of glass fiber mats and / or binders made of plastic.

The safety cell described in DE 34 20 771 AI only refers to an increased expansion of a passenger cell. The corresponding carriers are not connected to one another in a form-fitting manner, furthermore there is no self-contained system according to the invention. Under no circumstances can the energy generated in the event of an impact be dissipated directly;

The end wall arranged in DE 41 16 832 AI between the front end and the passenger compartment serves in particular to increase the torsional rigidity and also to avoid the transmission of disturbing resonances into the passenger compartment. DE 34 27 537 AI proposes an increase in the buckling stiffness, particularly in the case of windshields of a convertible which run at a steep incline, in the form of a servo device which extends in the event of danger.

WO 91/12164 AI only shows a U-shaped reinforcement extending into the chassis on the door opening of a convertible vehicle. The U-shaped part only serves to reinforce the body.

Constructions known to date use side members with front and rear end parts in the crumple zones, some with reinforcements or with built-in predetermined breaking points. An attempt was also made to create a way of absorbing energy by adding, filling and / or foaming the cavities with various filling materials. In the known constructions, the side members either end directly in front of the passenger compartment or are arranged at offset angles. As is known, in order to avoid damage to persons, the carriers had to be further processed in order to install the corresponding predetermined breaking points.

Furthermore, as is known from the Swiss patent CH 577 909 A5, components were developed which consist of hollow bodies which were at least partially filled with different filling materials, preferably with plastic foam, in order to achieve optimum energy absorption through their plastic deformation in cross section. These components can preferably between the fasteners of the bumper, the steering system, the roof pillar u. Like. Be attached. The known device is intended to absorb the energy by deforming the foamed hollow body in the event of an impact in the longitudinal direction. These hollow bodies are preferably installed in shock absorbers as well as fenders. With the help of these built-in components, however, it is only possible to absorb shocks at a relatively slow speed. A forwarding of the generated energy is not planned. The plastic material intended for filling is only available for uniform wrinkling of the wall, the energy absorbed in the event of a strong impact, accident and / or impact, apart from collisions during parking and or in city traffic, still ends up with all the forces behind the filling material the walls of the hollow body in a stress peak and the subsequent, uncontrollable and dangerous discharge. The proposed system does not envisage effective energy absorption, distribution, dissipation or consumption.

From DE 101 51 085 Cl a structure of a ship's hull is known, which is realized in a half-timbered construction. If the ship is viewed from the bow in FIG. 7 a and this view is based on at least two of the cubes arranged one behind the other in the direction of view, a skeleton frame can be seen which - among other things - also consists of at least three closed ones penetrating, rigidly constructed frame planes constructed frame, which are at least three frame planes non-positively connected and form three mutually intersecting planes, each enclosing a right angle, vertical sections of the frame planes forming the outer edges of the module and one plane of the frame planes two mutually penetrating, non-positively connected struts and enclosing a right angle are provided.

Two of the closed frame levels are those levels that form the diagonals of the visible square when viewed from the bow. The third frame level is formed by the closed frame on which the two cubes meet. The mutually penetrating struts are also arranged in this frame plane.

The disadvantage of this arrangement is that none of the planes under consideration is arranged horizontally and thus can be used as a load-bearing plane, e.g. for ship cargo.

Unlike the present invention, however, in this construction, a module-a "cube nώτn ^~ the side faces arranged intersecting-Strebenr Furthermore, the frame structure is built up as described successively, the use of a module according to the invention is not disclosed.

All the inventions known to date have in common that only partial solutions were offered to increase security. On the one hand, only carriers are provided which are connected in the form of stepped angles, and on the other hand from components which are only installed in parts of the vehicle, the shock absorber, the fenders. Also can in the base plate installed in most vehicles does not reduce the energy absorbed. In the event of an impact, forces are released which, apart from mechanical deformation, lead to a massive risk to the people inside. After it has passed through parts of the vehicle, the energy consumed in the accident is in front of the passenger compartment without any further possibility of dissipation. There it is passed on to the air inside and hits the passenger, absolutely unchecked, which, depending on the severity of the impact, can lead to massive damage. Obviously, the initially high, generally harmful deformation peak or the formation of dangerous non-periodic voltage peaks that occur with a correspondingly high impact force, which is transmitted directly to the passenger inside via the base plate.

Due to the formula P = m.v, it is not possible to quantify the loads that impact a person during an impact due to the lack of guide values and countless, extremely varied factors in the event of an impact. Only a qualitative assessment can be made, which is based on basic laws, the existing calculations of the propagation of waves and vibrations in known materials being used as the basis, in order to avoid the disadvantages of the previously used production systems and to correspond to the current state of the art should.

The aim of the present invention is to create a module of a safety cell that is simple and economical to manufacture and structurally uncomplicated, in order to improve the previous safety standard and to distribute the resulting, unperiodic peak voltage into a periodic impulse energy or - converting it to new ones , derive, feed back, and thereby minimize, in order to increase the security of the people and / or goods inside the security cell. This avoids the disadvantages of conventional systems.

This object is achieved according to the invention in that each module in each case consists of at least three closed, penetrating, flexurally stiff frame levels, which are non-positively connected to at least three frame levels and form three mutually intersecting levels that together form a preferably include a right angle, at least one of the frame planes being arranged horizontally and designed as a load-bearing plane and preferably vertical sections of the frame planes forming the outer edges of the module, and that in the plane of at least one of the frame planes at least one pressure ring designed as a force carrier or - ellipse is rigid and non-positively arranged and / or two struts penetrating each other, non-positively connected and preferably including a right angle are provided.

The inventive design of the module, which can be manufactured in a structurally simple manner, enables a substantial increase in the safety of the people and / or cargo located in the passenger compartment. This makes it possible to increase safety in the event of accidents when using the safety cell produced according to the invention in the motor vehicle area, and when used in shipbuilding and aircraft construction an increase in the bending stiffness and stability is achieved. The distribution of the acting forces as well as the impact forces via the non-positive connections and derivation in the closed system leads to the return of the absorbed ones

Energy, which has the positive effect of the reduction. This enables maximum strength and thus economy to be achieved with a minimum of material and weight. The modules produced according to the invention are also essentially characterized in that they can be of any size, shape or dimension. This results in the simplest way of producing almost all forms of geometry.

If necessary, the modules of the security cells produced according to the invention can be designed as stable, rigid and form-fitting skeleton elements to be put together and one above the other. If necessary, a combination of the above-mentioned embodiments is possible in a simple manner in order to increase the static and economic requirements, for example in shipbuilding to achieve large loading areas and in aircraft construction to increase the stability or bending stiffness. To achieve large areas, the invention provides for a combination of the modules to be carried out one above the other and next to one another. It is also possible to dispense with the use of intermediate elements, so that almost any size horizontally can be created, which are only interrupted by the essentially vertical sections of the individual room elements. This is an advantage, for example for shipbuilding or wide-body aircraft. With the modular system according to the invention, any construction forms and heights can thus be implemented without great effort.

The height of the room elements and the position or arrangement of the central horizontal sections can be changed as required. The connection of individual room elements can essentially take place in any geometric shape, for example rectangular, polygonal or circular shapes can be selected for ceiling tiles, which results in any design and design freedom and thus, by arranging a plurality of room elements, different floor plan shapes one above the other or side by side can be designed so that the system can be used for any purpose and useful construction in an unprecedentedly inexpensive way, both for the passenger, cargo or ferry building industry.

When executing the modules according to the invention, care must be taken to ensure that no maximum bending moments or maximum transverse and / or shear forces may occur in the connection points or connection points or in the module components, with static calculations and production achieving the required stability and strength properties Need to become.

Furthermore, in the module according to the invention, by designing each spatial element as a closed frame plane, a corresponding reduction in the decisive bending moments can be achieved, for example by providing a central, essentially vertical section which is designed in the form of non-positive and rigid, preferably cross-wise connected struts . Another advantage of the system according to the invention is the simplification of the static calculations due to the symmetry, parallelism and connection design of the elements forming the module.

The fact that, according to the invention, each spatial element in each case consists of at least three interpenetrating elements which preferably form a right angle, If at least two-story, closed frame levels are formed, the result is a structurally simple and easy-to-produce basic shape which, by combining a plurality of essentially prismatic space elements, enables the formation of a wide variety of body shapes or combinations of body frames and a wide variety of floor plans, dimensions and / or enables shapes that represent a skeleton, for example the body or the combined frame body for vehicles, in particular for motor vehicles.

To further improve the module of the safety cell proposed according to the invention, a device for deflecting the impact force is proposed, the resultant force vectors reducing and redirecting - or deriving - the impact energy of the impact force by creating an instantaneous and almost simultaneously acting force at right angles to the acting force attacking impact energy from the passenger compartment, preferably downwards. This device can preferably be mounted in the front area of the vehicle in the engine compartment in the upper part of the chassis and consists of a shock-absorbing mechanism, securing elements for repair, a movable, parallel part of the module, a fixed outer cylinder, a variable inner cylinder with spring. An expansion by increasing the number of cylinder and spring elements is possible.

A particularly advantageous embodiment of the module according to the invention provides that the module can be provided with damping means, for. B. Hydraulic cylinder. On the one hand, the hydraulic cylinders can be used to absorb forces, on the other hand, the length of a module can be varied. The latter is used in order to shorten or shorten the mode duLzn. B. to vary the length of the vehicle, while maintaining the required static regulations.

The design according to the invention makes it possible, for example in motor vehicles, to reduce the conventional base plate or chassis to a minimum in terms of material and weight, since the horizontal and vertical modules are inherently stable and thus self-supporting. The distribution of the impact forces via the non-positive connections and discharge in the closed system leads to a return of the absorbed energy, which has the positive effect of the reduction Has. This makes it possible to reduce the weight of the vehicle as well as the manufacturing costs and effort. However, when installing the base plate, it must be ensured that the energy-dissipating or consuming capabilities of the module are not negatively influenced, for example by producing the base plate from plastic or isolating the struts, pressure rings or pressure ellipses.

When considering the use of the safety cell according to the invention in ships, compliance with the usual safety standards and regulations, such as the installation of bulkheads and the like. Like., considered, also the reinforced design of floor or ceiling panels.

To simplify the manufacture and to reduce the weight, it is possible to construct a module with the space elements proposed according to the invention in a structurally simple manner while maintaining the required stability and taking into account the corresponding regulations, with standardized construction elements of different materials, which can also be produced with a Selection of plastic composite constructions with hardening plastic or combination constructions can be carried out. These can consist, for example, of plastic, metal or various types of steel profiles as well as light alloys such as aluminum or reinforced hollow profiles. Of course, here too, care must be taken to maintain all predetermined and necessary design and stability-related forces and moments. It is advisable to retrofit these with self-hardening materials, e.g. B. plastic or the like can be filled, which can also lead, inter alia, to an increase in rigidity and shape retention in the event of fires at a comparatively low weight.

This is particularly important for the execution in the ship and aircraft industry, where gross register tons must not be exceeded. When using the construction proposed according to the invention, the dead weight of the ship is reduced while maintaining the required stability, the net register tons of the cargo can thereby advantageously be increased. When using the module proposed according to the invention in aircraft construction, a higher refueling and thus a greater range can be achieved by maintaining the total weight of the aircraft. Likewise it is possible with the design according to the invention, for example for tankers or ships which are used for the transport of dangerous goods, in a structurally simple construction and with low weight, while maintaining the required static regulations, to produce an internal safety cell.

The advantage is striking that the module security cells equipped according to the invention are produced in the most varied of shapes and these shapes are combined with one another. This makes it possible to provide corresponding openings in a simple manner, for example at different points. Naturally, the use of intermediate elements and / or separating elements can also be dispensed with. With the module system according to the invention, any skeleton shapes and heights can thus be realized without great effort.

This can be used particularly in the manufacture of roll-off roll-on ships. Likewise, by combining the modules according to the invention, entry and exit ramps as well as lifts with entrance and exit gates can be installed in a simple and safe manner. This is particularly advantageous in the slave construction industry, also in the wide-bodied aircraft industry, or when installed in the fuselage of an aircraft or multi-storey aircraft.

There are hardly any limits to the possible uses due to the present invention. It is also conceivable to use the invention to create floating parking decks or floating shopping centers, of course also in combination. This is possible due to the possible flexibility while maintaining the static requirements and much lower weight.

The present invention is explained in more detail below with reference to exemplary embodiments schematically illustrated in the accompanying drawings. The possible embodiments are not limited to the modules shown, it is also possible to combine the modules shown with one another or with one another.

1 to 4 show examples of room elements in a schematic representation, seen obliquely from above. The two-level closed frame planes are designated by 1, 2 and 3, the pressure ellipses are designated by 6 to 6 ", with sections designated by 4 essentially running in the vertical direction. However, the sections can also be tends to be arranged to achieve inclined or inclined construction sections or to obtain pyramid-like or conical spatial elements and constructions. 5, 5 'and 5 "denote sections of the frame planes which run essentially horizontally, but which can also be arranged at an incline.

With 3 the closed frames are designated, which connects the end of the sections 5 of the frame levels. These frames are shown with 1 and 2.

5 shows how the stability and stability of a module of a safety cell according to the invention can be increased by installing an additional frame level 7 or 8. With 6 a pressure ring is shown, with 11 and 12 pressure rings.

6 to 18 show how, in a structurally simple manner, the manufacture of a car, ship or plane is made much easier, for example, by almost infinite variations and solutions of the module elements according to the invention.

19 to 24 show how, for example, a single-module frame body can be designed, calculated and generated in a simple manner with a printing euipse.

Due to the same length and parallelism and thus favorable construction conditions for the formation of the crossing points of the construction parts, an economical construction is possible.

25 shows a basic illustration of the advantages of the vehicle produced by the modules according to the invention. In order to better distribute or forward the resulting impact or impact forces, which particularly affect the lower area of the vehicle, 15 pressure rings or pressure eips 6 were built into the elements that form the frame 16 of the vehicle in the floor area by installing struts "", the recesses for wheels 17 being visible. The attacking forces become in particular via the pressure ellipses or pressure rings 6 "" and the non-positively connected longitudinal frame 14 and transverse frame 13 in the form of a cavity resonator effect from non-periodic peak voltages to periodic Resonance waves that are derived, returned, consumed and thereby minimized. A further embodiment of the module according to the invention is shown in FIG. 26, the connection points of the frame level 21 with that of the frames 20 and 22 by means of two struts 23 and 24, which function as the pressure rings, to control the forces of the connection points of the frames 20, 21 and 22 to take over. FIG. 27 is a further development of FIG. 26 in order to increase the stability and strength of FIG. 25.

FIGS. 28 to 38 show an illustration for the manufacture of a single-module car, similar to that in FIGS. 19 to 24; however, the pressure ellipse was replaced by struts located in the floor area of the vehicle.

39-41 also show two-module vehicles with struts.

42 to 49 show examples of a three-module vehicle, the advantages of energy consumption still being retained. The manufacture can be facilitated by the implementation in different modules. The rigid and stable connection between the modules is made possible, for example, by riveting, screwing or welding.

A further possible embodiment is shown in FIGS. 50 and 51. The damping of the absorbed energy can be increased by the built-in hydraulic cylinders, and the size of the module can be easily varied by installing these cylinders. The execution of these hydraulic cylinders is shown in FIG. 53 shows a possible embodiment when installing the hydraulic cylinders proposed according to the invention. Installation is preferably carried out in the rear of the vehicle behind the wheels.

A device for deflecting the impact force to improve the module of the safety cell is shown in FIG. 54, the resultant force vectors reducing and redirecting the impact energy - or dissipation - of the attacking force by using an instantaneous and almost simultaneously acting force at right angles to the attacking force Impact energy from the passenger compartment, preferably downwards, is reached. The chassis of the vehicle is shown at 33, 33 'shows the direction of travel. 34 to 36 and 39 are components of the shock-absorbing mechanism, 37 and 38 are securing elements. mente. 40 represents a movable, parallel part of the module. 41 is the fixed outer cylinder, 42 is the variable inner cylinder, in which a spring is installed at 43. An expansion by increasing the number of cylinder and spring elements is possible.

A further embodiment of the module according to the invention is shown in FIG. 55, the connection points of the frame level 44 to the frames 46 and 45 being replaced by two struts 47 and 48, which replace the function of the pressure rings, in order to ensure that the frame 44, 45 and 46 occurring forces to take over. This embodiment can preferably be used in shipbuilding, since the proposed embodiment allows for an advantageous enlargement of the dimensions, while improving the required stability.

FIG. 56 shows a further increase in the stability of the module described in FIG. 55, which can be used in a simple and economical manner when building ships with a double-wall system to increase safety, with the advantageous beveling of the side edges.

57 shows how the stability and strength can be optimized in a simple manner. It is also possible to insert a pressure ring or a pressure ellipse at the upper and lower ends of the module.

58 to 67 show proposed applications of the proposed modules in shipbuilding, the possibility of installing openings, ramps and the like. can be seen.

68 shows a further embodiment in which the struts are preferably used by pressure rings or pressure gypsies for the production of large vessels, tankers, and the like. be replaced.

The modules shown in FIGS. 55 to 69 can be used to simplify and also to reduce the weight in the manufacture of standardized construction elements of different materials and combinations, for example combinations of plastic, MetaU or different types of steel profiles and light alloys such as for example aluminum, or reinforced hollow profiles, which can be added later Self-hardening materials, e.g. plastic, can be filled in to increase the rigidity and shape retention of the module, e.g. when used in the manufacture of roll-off roll-on ships, the wide-bodied aircraft industry, for the manufacture of floating parking decks or floating shopping centers.

FIG. 69 shows a module for use in extreme conditions, especially in the field of the manufacture of spaceships, whereby, as in FIG. 57, pressure rings or pressure ellipses can be attached to the upper and lower ends.

70 to 75 show examples of room elements in a schematic representation, seen obliquely from above. These are extended embodiments of FIGS. 1 to 4, wherein frame elements are advantageously oval or ring-shaped in order to enable their use in aircraft construction technology. At least two of the struts forming the frame must preferably be made at right angles, crossing or penetrating each other. The third level is formed by an oval or ring-shaped frame with interpenetrating, preferably intersecting, inner struts. The embodiment for use in the construction of the wing was not shown, the surface of the curved frame of the module being convex and the underside being concave.

76 shows the possible use in aircraft construction technology. 57 shows the installation of pressure ellipses in the horizontal plane, 58 the installation of pressure ellipses in the vertical plane. The most important moments of force that act on the wing are shown by arrows. 77 shows the side view of an airfoil by means of the modules proposed according to the invention. It is also possible to design the underside of the wing in a concave manner (FIG. 77 ').

78 shows a spatial representation of the connection of the fuselage to the wings.

FIG. 79 shows an expanded embodiment of the module, as shown in FIG. 72, wherein pressure rings 60 are preferably inserted in the frame 59 to increase the stability, and an oval or circular frame 61 is used in comparison to FIG. 72. As can be seen from FIG. 80, the frame 62 is used across the entire module Airplane on the top and bottom in the longitudinal axis above bow and stern in a closed design, trained. 81 to 83 show various perspectives of an aircraft using the modules according to the invention, which are described in FIGS. 70 to 79.

84 and 85 show a module according to the invention as described in FIG. 79, wherein in another embodiment the pressure ring 60 or 60 'is replaced by struts 64 or 65 which penetrate one another.

86 shows a spatial representation of an aircraft using the modules proposed according to the invention, a combination of FIGS. 84 and 85 being carried out, as can be seen from the struts 64 'and 65.

87 to 89 show different perspectives of the manufacture of an aircraft by means of the modules proposed according to the invention, as described under FIG. 86.

Claims

1. Module of a security cell of a means of transport or means of transport, for example a motor vehicle, a ship or an airplane and the like. The like, characterized in that it consists of at least three closed, mutually penetrating, rigid, frame levels (1, 2, 3, 5, 7, 8, 13, 14, 15, 16, 20, 21, 22, 25 , 26, 27, 28, 29, 30, 31, 44, 45, 46, 49, 50, 51, 52, 59, 60, 61, 62) consists of frames which have at least three frame levels (1, 2, 3, 5, 7, 8, 13, 14, 15, 16, 20, 21, 22, 25, 26, 27, 28, 29, 30, 31, 44, 45, 46, 49, 50, 51, 52, 59, 60, 61, 62) are non-positively connected and form three intersecting planes which preferably form a right angle with one another, at least one of the frame planes (1, 2, 3, 5, 7, 8, 13, 14, 15, 16, 20, 21, 22, 25, 26, 27, 28, 29, 30, 31, 44, 45, 46, 49, 50, 51, 52, 59, 60, 61, 62) is arranged horizontally and is designed as a load-bearing plane and preferably vertical sections (4, 4 ') of the frame planes (1, 2, 3, 5, 7, 8, 13, 14, 15, 16, 20, 21, 22, 25, 26, 27, 28, 29, 30 .

31, 44, 45, 46, 49, 50, 51, 52, 59, 60, 61, 62) form the outer edges of the module, and that in the plane at least one of the frame levels (1, 2, 3, 5, 7 , 8, 13, 14, 15, 16, 20, 21, 22, 25, 26, 27, 28, 29, 30, 31, 44, 45, 46, 49, 50, 51, 52, 59, 60, 61 , 62) at least one pressure ring or euipse (6, 6 ', 6 ", 11, 12) designed as a force carrier is arranged rigidly and non-positively and or two interpenetrating, non-positively connected and preferably including a right angle Struts (23, 24, 47, 48, 64, 65) are provided. (Fig. 1-18, 26, 27)

2. Module according to claim 1, characterized in that it is self-supporting.

3. Module according to claim 1 or 2, characterized in that a body or a combined frame body for vehicles, in particular for motor vehicles, consists of at least one module. (Figs. 19 to 25)

4. Module according to one of claims 1 to 3, characterized in that it is constructed from hollow profiles made of MetaU, in particular light metal, or of plastic or Metal-plastic combinations, for example metal hollow profiles filled with self-hardening plastic, exist.

5. Module according to one of claims 1 to 4, characterized in that struts of the frame levels (1, 2, 3, 5, 7, 8, 13, 14, 15, 16, 20, 21, 22, 25, 26, 27 , 28, 29, 30, 31, 44, 45, 46, 49, 50, 51, 52, 59, 60, 61.62) or the struts (23, 24, 47, 48, 64, 65) to vary their Dimensions or for cushioning shocks with damping devices, e.g. B. hydraulic cylinders (32) are provided. (Figs. 50 to 53)

6. Module according to one of claims 1 to 5, characterized in that two substantially paraüele and spaced frame elements (33, 40) exclusively by at least one spring element, e.g. Compression spring element, air spring element or the like, and at least one further element (70) are connected, the further element (70) reliably controlling the distance of the frame elements (33, 40) in the original state and the connection between the frame elements (33 , 40) mechanically. (Fig. 54)

7. Module according to claim 6, characterized in that the frame elements (33, 40) are arranged essentially horizontally and spaced perpendicularly from one another.

8. Module according to claim 6 or 7, characterized in that the further element (70) consists of an essentially U-shaped, horizontally displaceable part (71) arranged on the frame element (33) and a holding element fixedly arranged on the frame element (40). element (36), the two legs (34, 39) of the U-shaped part (71) having different lengths and one leg (39) of the U-shaped part (71) being horizontally displaceably and releasably guided in the holding element (36) is.

9. Module according to claim 8, characterized in that a prestressed compression spring (35) is arranged on the leg (34) of the U-shaped element (71), which at the free end of the

Leg (34) and on one on the frame element (33) for guiding the leg (34) provided guide element (72) is supported.

10. Module according to claim 8 or 9, characterized in that the further element (70) is equipped with a releasable connection between the leg (39) and the holding element (36) locking device.

11. Module according to claim 10, characterized in that the security device consists of an opening (38) provided on the leg (39) and a locking pin (37), for example in the form of a key.