EP3789087B1 - Use of rescue load distribution element for bracing rescue equipment which creates pressure - Google Patents

Description

The invention relates to the use of a rescue operation load distribution element for supporting pressure-generating rescue equipment on an accident vehicle according to the claims.

In accordance with the state of the art, dimensionally stable pressure plates and sill attachments are used to support and distribute the load of rescue equipment, in particular hydraulic rescue cylinders, mechanical gear winches, spreading tools and the like, on external objects such as vehicle components, in particular dashboards, sills and door sections. Due to their rigid shape, these pressure plates and sill attachments cannot be used universally on every surface or in every operational situation, which hinders efficient and rapid operation or even impairs the functionality of the rescue equipment. For example, dimensionally stable pressure plates for support on fittings are not suitable for support on all types of sills and vice versa. In addition, emergency organizations usually carry a number of pressure plates and sill attachments of different contours and sizes in order to be able to meet the specific operational requirements. Furthermore, pressure plates and sill attachments according to the state of the art have a high mass in order to withstand the loads and can therefore only be transported over short distances and with difficulty. Due to their bulkiness and the large number of different designs and sizes required, valuable storage space in rescue vehicles is taken up and an efficient response is hindered. Overall, this also results in a longer period of danger for all those involved in the operation.

Load distribution elements are DE 20 2007 016946 U1 , EN 10 2009 051255 A1 and the DE 13 22 445 U known.

The object of the present invention was to overcome the disadvantages of the prior art and to provide a device by means of which a user is able to achieve a simple, fast and stable load distribution between a pressure-generating rescue device and an external object, in particular an accident-damaged vehicle. This should enable rescue operations, in particular to rescue accident-damaged or injured persons, to be carried out more quickly and safely for all those involved.

This object is achieved by a device according to the claims.

According to the invention, the use of a rescue operation load distribution element for supporting pressure-generating rescue devices, in particular hydraulic rescue cylinders, mechanical gear winches, spreading tools and the like, on an accident-damaged vehicle is provided. The rescue operation load distribution element comprises at least one load-bearing surface for introducing a support load of a rescue device and at least one load transfer surface for transferring the support load to an external object. At least the load transfer surface is formed by a shape-changing boundary casing. The boundary casing delimits at least one chamber, at least in sections, the chamber being at least partially filled with a flowable or overall shape-flexible filling material.

The use of a rescue load distribution element according to the invention has the advantage that, due to its shape flexibility, it can be used universally on different vehicle components or in many application situations and is suitable, for example, for support on dashboards as well as on sills and door sections. Furthermore, the rescue load distribution element can also be positioned under a vehicle or used for support on soft surfaces, such as wet floors. Support on trees or similar is also conceivable. This makes it possible to meet the specific application requirements better or more quickly with just one or just a few rescue load distribution elements and also to save valuable storage space in emergency vehicles. In addition, the rescue load distribution element is particularly uncomplicated to use and can therefore be used quickly. Due to its good shape adaptability, it can be attached easily and quickly to a wide variety of support zones on various vehicles that have been involved in an accident, which may be severely deformed. Due to the high degree of shape variability, a comparatively high slip resistance of the rescue load distribution element can be achieved, especially in connection with relatively narrow, metallic webs of vehicle bodies, for example in the area of their entry bars. This means that rescue operations can be carried out as planned as possible and ultimately more quickly and efficiently, which significantly reduces the duration of danger for all those involved in the operation and ensures a higher level of safety.

In addition, it can be expedient for at least one handling and/or fixing element to be formed on the limiting casing. Handling elements serve both to facilitate manual transport and simple positioning, while fixing elements can act as fixing or attachment points for slings, ropes, chains and the like. When using the handling and/or fixing elements as attachment points, they serve, for example, to create a load triangle. The handling and/or practicality of use, in particular with regard to avoiding undesirable slipping tendencies of the rescue load distribution element, can thus be further improved.

According to a particular embodiment, it is possible for the at least one handling and/or fixing element to be designed as a handle, flexible loop or eyelet. Handles facilitate manual transport and/or positioning in particular. Flexible loops or eyelets can primarily serve as fixing or attachment points for slings, ropes, chains or the like in order to be able to safely maintain the desired position during the respective rescue operation.

It may also be expedient for the boundary cover to be designed to be liquid-repellent or liquid-tight or to have a liquid-repellent or liquid-tight impregnation. This means that the rescue load distribution element can be used without any problems even during rainfall or in water without suffering any significant impairment of its functionality. In addition, the rescue load distribution element can be exposed to various vehicle fluids, such as oils or fuels, without causing a significant increase in the risk of fire. In addition, this design can prevent the mass of the rescue load distribution element from increasing in a disadvantageous way or its usability from changing in any other way.

Also advantageous is a form according to which it can be provided that the boundary cover has at least in sections a slip-resistant surface which is formed by a coating or at least partially consists of an anti-slip material, for example an elastomeric plastic. This can improve the static friction between a rescue device, for example a hydraulic cylinder, and the load-bearing surface of the rescue load distribution element, and in particular the static friction between the load-bearing surface of the rescue load distribution element and the external object underneath, for example an accident-damaged vehicle. This design therefore increases the safety and stability of the system and makes it easier to handle.

In addition, the boundary cover can be made of non-flammable or flame-retardant material or have a non-flammable or flame-retardant coating. This can reduce the risk of fire or burns to those involved in the operation when it comes into contact with flammable substances and/or when exposed to heat. This design increases safety for all those involved in the operation and can also extend the service life of the rescue load distribution element.

Furthermore, it can be provided that the limiting cover is made of a flexible material with increased tear resistance, for example aramid, leather, natural fibers, carbon fibers or a combination thereof, so that the rescue load distribution element can withstand a load of more than 20 kN. This is of increased importance for the rescue load distribution element to have the highest possible transverse pressure dimensional stability, which means that a wide range of applications can be covered. The high level of robustness also benefits the highest possible functional reliability and service life.

According to a further development, it is possible for the filling material to be made of a granular substance, for example sand, plastic, or a mixture of these components. By using a granular filling material, the highest possible transverse pressure dimensional stability of the rescue load distribution element can be achieved. In addition, granular filling materials can adapt particularly well to a wide variety of surface profiles or to strongly varying contours and thus implement the load distribution as evenly as possible. In addition, this can increase safety against abrupt, undesirable slipping movements.

Alternatively, the filling material can be made from a loose knit or structure made from fibers, for example cotton wool. This design offers a great weight advantage, so that the rescue load distribution element can be transported quickly and easily even over long distances. This can reduce the duration of the operation and the risk for everyone involved.

It can also be advantageous if the filling material is made of a liquid, particularly water, or a gel-like substance, since liquids or gels are easily moldable. In addition, water in particular is usually an easily available resource during rescue operations, which facilitates simple and rapid variability of the filling level of the rescue load distribution element.

According to a practical measure, it can also be provided that the chamber is divided into several at least partially separated sub-chambers, so that a minimum degree of distribution of the filling material is ensured. This can ensure that the filling material is distributed sufficiently evenly between the load-bearing surface and the load-transfer surface, thus positively influencing the load distribution function. In particular, this can easily prevent the filling material from accumulating on one side in relation to the boundary shell. Accordingly, these sub-chambers achieve a minimum degree of distribution of the filling material, whereby the filling material cannot be displaced in such a way that direct contact occurs between the load-bearing surface and the load-transfer surface. Overall, this measure increases the transverse pressure dimensional stability of the rescue load distribution element and improves safety in use.

Furthermore, it can be provided that a completely closed chamber is formed by means of the limiting casing. This ensures uncomplicated handling of the rescue load distribution element, since undesirable leakage of the filling material can be prevented.

Furthermore, it may be expedient for the proportion of filling material in the maximum volume of the chamber to be more than 33%, in particular more than 50%, preferably in a range of at least 60% up to and including 98%. A sufficiently high or balanced proportion of filling material ensures that there is no direct Contact between the load-bearing surface and the load-transfer surface would occur, which would negatively affect the transverse pressure dimensional stability of the rescue load distribution element. On the other hand, this can ensure that the rescue load distribution element is sufficiently flexible in terms of shape. In addition, this can achieve the most comprehensive possible form fit between the load-transfer surface and the external object, in particular with respect to a vehicle contour, so that the risk of the rescue load distribution element slipping can be minimized.

Another advantageous embodiment is one in which the limiting casing is designed to be airtight or has an airtight impregnation and has a valve, preferably a vacuum valve, with which a flow connection between the limiting casing, in particular the external environment of the rescue load distribution element, and the chamber can be established and prevented as required. In particular, the vacuum valve can be used to at least partially evacuate the at least one chamber in the rescue load distribution element. This embodiment enables additional strengthening or stiffening of the rescue load distribution element during use. This is particularly the case when the rescue load distribution element is already loaded by a rescue device, so that maximum stability and additionally improved load distribution can be achieved. Ideally, such valves are attached to the side of the rescue load distribution element, in particular in the casing section of the limiting casing that connects the load-bearing surface and the load-distribution surface. This can prevent damage caused by support and/or load application, which can have a positive effect on the product lifespan.

According to a further development, it is also possible for the boundary cover to be made of airtight material or for the boundary cover to have an airtight impregnation or for the boundary cover to comprise an inner cover made of airtight material or for the boundary cover to comprise an inner cover, which inner cover has an airtight impregnation, wherein the inner cover is located between the boundary cover and the chamber. Airtight material can be realized, for example, by using thermoplastic polyurethane.

Furthermore, it can be provided that the boundary shell and/or the inner shell has a closable opening through which the amount and/or type of filling material can be changed or replaced. This allows the rescue load distribution element to be adapted to specific operating conditions and the product lifespan to be increased. In the event that the filling material is water, the fill level of the boundary shell can be quickly and easily adapted to the respective operating conditions using the closable opening. This is particularly true with regard to reducing the fill level starting from a comparatively high fill level. This feature also makes cleaning easier, particularly in the event of soiling during use.

Ideally, such openings are installed on the side of the rescue load distribution element, particularly in the section of the boundary casing that connects the load-bearing surface and the load-distribution surface. This can prevent damage caused by support and/or load application, which can have a positive effect on the product's service life.

Furthermore, it can be provided that the chamber contains at least one comparatively dimensionally stable pressure element with a predefined support contour in addition to the flowable and/or dimensionally flexible filling material. This pressure element can serve to stabilize the rescue load distribution element by predefining and/or supporting the load-bearing surface and/or the load-distribution surface. In an advantageous manner, this can also achieve partial stiffening or a predefined shape or dimensional stability of a desired shape. In addition, a comparatively dimensionally stable pressure element increases the transverse pressure dimensional stability of the rescue load distribution element.

According to a special embodiment, it is possible that a comparatively dimensionally stable pressure element with a predefined outline or support contour is attached to the outside of the limiting casing, whereby the outline or support contour has the load-bearing surface. Due to its dimensionally stability, this outline or support contour is particularly advantageous for supporting a rescue cylinder on the load-bearing surface of the rescue operation load distribution element, while the support on the load-bearing side is provided by the dimensionally flexible limiting casing. This embodiment combines The technical advantages of flexible and dimensionally stable support and load distribution structures can be used in a practical manner. In addition, the risk of damage to the limiting shell can be kept to a minimum even if a rescue device supported on the rescue load distribution element has a relatively small support surface, as is typically the case with a hydraulic rescue cylinder. In particular, point loads on the load-bearing surface can be avoided. In addition, undesirable sliding movements of the pressure-generating rescue device can be prevented by means of a support contour that is, for example, step-like, rung-like or wave-like.

In an advantageous embodiment, the relatively dimensionally stable pressure element is made of hard rubber or plastic. The shape of the relatively dimensionally stable pressure element can preferably be adapted to the shape and size of the rescue cylinder or can be larger in shape and size than the rescue cylinder. This makes it easier to apply force from the rescue cylinder to the rescue load distribution element over a large area.

Furthermore, it may be expedient for the comparatively dimensionally stable pressure element to be connected in a fixed position to the limiting shell and/or the inner shell, so that, in particular during the positioning of the rescue load distribution element and rescue device, there are no undesirable displacements of the pressure element relative to the limiting shell and/or inner shell.

According to a further development, it is possible for a coupling means that can be operated manually and/or without tools to be designed for the detachable connection of the comparatively dimensionally stable pressure element to the limiting cover and/or the inner cover as required. This enables the two components to be used separately, so that the rescue load distribution element can be used in even more diverse ways. The detachable connection can be implemented using straps, lashing straps, Velcro fasteners and/or magnets, for example.

It can also be advantageous if the limiting cover has a coupling means that can be activated and deactivated manually, in particular a Velcro fastener, at least in sections, and that several rescue load distribution elements can be connected or stacked as required using the coupling means. This means that rescue load distribution elements can be stacked in an advantageous manner, for example, and thus on the one hand act as raised support points and on the other hand serve to create a triangle of forces.

For a better understanding of the invention, it is explained in more detail with reference to the following figures.

Fig. 1

Ein Anwendungsbeispiel mit zwei Rettungseinsatz-Lastverteilungselementen zur Abstützung eines Hydraulikzylinders an einem verunfallten Fahrzeug;

Fig. 2

eine erste Ausführungsvariante eines Rettungseinsatz-Lastverteilungselementes mit quader- bzw. kissenförmiger Begrenzungshülle;

Fig. 3

eine zweite Ausführungsvariante eines Rettungseinsatz-Lastverteilungselementes mit L-förmiger Begrenzungshülle;

Fig. 4

einen Querschnitt eines Rettungseinsatz-Lastverteilungselementes entsprechend der ersten Ausführungsvariante inklusive Detailansicht;

Fig. 5

einen Querschnitt eines Rettungseinsatz-Lastverteilungselementes gemäß einer dritten Ausführungsvariante mit Teilkammern;

Fig. 6

einen Querschnitt eines Rettungseinsatz-Lastverteilungselementes gemäß einer vierten Ausführungsvariante mit luftdichter Innenhülle;

Fig. 7

eine fünfte Ausführungsvariante eines Rettungseinsatz-Lastverteilungselementes mit einem formstabilen Druckelement;

Fig. 8

eine sechste Ausführungsvariante eines Rettungseinsatz-Lastverteilungselement mit einem formstabilen Druckelement.

They show in a highly simplified, schematic representation:

Fig.1

An application example with two rescue load distribution elements to support a hydraulic cylinder on an accident vehicle;

Fig.2

a first embodiment of a rescue load distribution element with a cuboid or cushion-shaped boundary shell;

Fig.3

a second design variant of a rescue load distribution element with L-shaped limiting shell;

Fig.4

a cross-section of a rescue load distribution element according to the first design variant including a detailed view;

Fig.5

a cross-section of a rescue load distribution element according to a third embodiment with partial chambers;

Fig.6

a cross-section of a rescue load distribution element according to a fourth embodiment with an airtight inner shell;

Fig.7

a fifth design variant of a rescue load distribution element with a dimensionally stable pressure element;

Fig.8

a sixth design variant of a rescue load distribution element with a dimensionally stable pressure element.

By way of introduction, it should be noted that in the variously described embodiments, identical parts are provided with identical reference symbols or identical component designations, whereby the disclosures contained in the entire description are transferred analogously to identical parts with identical reference symbols or identical component designations. The position information chosen in the description, such as top, bottom, side, etc., also refers to the figure directly described and shown, and if the position changes, these position information must be transferred to the new position accordingly.

The Fig.1 shows an application example for two rescue operation load distribution elements 1 for supporting a rescue device 2, in the specific case of a hydraulic cylinder 3 on an external object 4, in the example shown on an accident vehicle 5. The two rescue operation load distribution elements 1 shown are each positioned at the ends 6 of the hydraulic cylinder 3 and subsequently clamped between the hydraulic cylinder 3 and the vehicle 5. The load-bearing surface 7 faces the hydraulic cylinder 3 and the load-transfer surface 8 faces the accident vehicle 5. The load-transfer surface 8 of the first rescue operation load distribution element 1 is supported on a door section 9 of the vehicle 5, while the load-transfer surface 8 of the second rescue operation load distribution element 1 rests on the A-pillar 10 of the vehicle 5. The flexible boundary casing 11 adapts to the contour of the surroundings on both the load-bearing surface 7 and the load-transfer surface 8, in the example in question to the shape of the door section 9 and the A-pillar 10. At both ends 6 of the hydraulic cylinder 3, a load is applied to the load-bearing surface 7 according to the arrow 12 by activating it, and the same load is transferred to the accident vehicle 5 via the load-transfer surface 8 according to the arrows 12.

In Fig.2 a first embodiment of a rescue load distribution element 1 with an approximately cuboid-shaped or cushion-shaped boundary shell 11 is shown. At least partial sections of the upper side of the rescue load distribution element 1 serve as a load-bearing surface 7, while at least partial sections of the lower side take on the function of a load-transfer surface 8. As in the application example in Fig.1 As shown, a load is applied to the load-bearing surface 7 according to the arrow 12 and the same load is transferred via the load-bearing surface 8 according to the arrows 12.

On the side of the rescue load distribution element 1 there is a handling and/or fixing element 13 in the form of a handle 14 1. Ideally, the handle 14 is ergonomically shaped so that the rescue load distribution element 1 can be carried and positioned comfortably. If required, the rescue load distribution element can 1 also have a plurality of distributed handles 14. Such a handle 14 can - as schematically indicated - be dimensionally stable in order to enable effortless gripping. Alternatively or in combination with this, at least one handling and/or fixing element 13 can be provided which is dimensionally flexible, as will be discussed below.

Fig.2 also discloses a variant of the rescue load distribution element 1 with an airtight boundary casing 11. With a valve 15, in the case shown in the form of a vacuum valve 16, which is practically attached to the side of the boundary casing 11, it is possible to establish or prevent a flow connection between the environment and the chamber 20 or a vacuum pump (not shown) and the chamber 20 as required. This function thus enables additional stiffening of the rescue load distribution element 1 in the event of at least partial evacuation of the chamber 20.

In the Fig.3 a further and possibly independent second embodiment of the rescue load distribution element 1 with L-shaped limiting casing 11 is shown, wherein the same reference numerals or component designations are used for the same parts as in the previous Fig.1 and Fig.2 To avoid unnecessary repetition, please refer to the detailed description in the previous Fig.1 and Fig.2 pointed out or referred to.

In addition to Fig.2 will be in the Fig.3 shown that neither the load-bearing surface 7 nor the load-transfer surface 8 has to be designed as a continuous surface and can in particular also be delimited by edges 17 and the like. In the specific embodiment, the rescue operation load distribution element 1 has two load-bearing surfaces 7 and two load-transfer surfaces 8. The load according to the arrow 12 can be applied to just one load-bearing surface 7 or to several load-bearing surfaces 7 and can be released by just one load-transfer surface 8 or several load-transfer surfaces 8. Which or how many of the load-bearing surfaces 7 and/or load-transfer surfaces 8 are exposed to a load and to what intensity can vary from application to application.

The Fig.3 discloses as further embodiments of handling and/or fixing elements 13 a loop 18 and an eyelet 19, each attached to the side of the rescue load distribution element 1. Depending on requirements and practicality, the rescue load distribution element 1 can also have a plurality of loops 18 and/or eyelets 19. These can be provided on the one hand for attaching traction means to secure the position of the rescue load distribution element 1 and on the other hand for carrying and positioning the rescue load distribution element 1.

It should be expressly pointed out that the shapes of the boundary shells Fig. 2 and Fig. 3 are to be understood as examples of possible design variants and a multitude of other and equally advantageous embodiments are conceivable. For example, a further advantageous design variant can be shaped in such a way that the rescue load distribution element is tapered or wedge-shaped or pyramid-like, so that support is also possible in angled or narrow positions, such as corners.

The Fig.4 discloses a cross-section of a rescue load distribution element 1 including a detailed view according to the first embodiment variant of Fig.2 A load-bearing surface 7 is located opposite a load-discharging surface 8. As in the application example in Fig.1 As shown, a load is applied to the load-bearing surface 7 according to the arrow 12 and the same load is transferred via the load-bearing surface 8 according to the arrows 12.

By means of the limiting casing 11, a completely closed chamber 20 is formed in the cross section shown, in which the filling material 21 is accommodated. The chamber 20 also contains a dimensionally stable pressure element 22 with a support contour 23, which enables a more stable support of a rescue device 2 due to its rigid design.

Fig.4 also discloses a variant of the rescue load distribution element 1 with an airtight boundary casing 11. With the valve 15, in the case shown in the form of a vacuum valve 16, which is ideally attached to one of the side surfaces of the boundary casing 11, it is possible to establish or prevent a flow connection between the environment and the chamber 20 or between a vacuum pump (not shown) and the chamber 20 as required. This function thus enables additional stiffening of the rescue load distribution element 1.

A closable opening 24, which is ideally arranged laterally in the boundary casing 11, enables the amount or type of filling material 21 to be changed and/or adjusted. The type of filling material 21 can be defined by different hardnesses and/or grain sizes and/or viscosities.

The lateral attachment of valves 15 and openings 24 to the limiting casing 11 offers the advantage in operational situations that damage caused by supports and/or load application can be prevented.

The Fig.4 The detailed section shown also shows a possible layer structure of the boundary cover 11. Viewed from the inside out, the boundary cover 11 is provided with an air- and/or liquid-tight impregnation 25 and is also equipped with a non-flammable coating 26. An anti-slip surface 27 can also be formed on this non-flammable coating 26, which is shown in the special form as a knob structure made of elastomer plastic. In the described embodiment, the anti-slip surface 27 extends over the load transfer surface 8. An alternative design variant with a complete covering of the boundary cover 11 with an anti-slip surface 27 or also the covering of one section or several sections is conceivable.

In the Fig.5 a cross section of a further and possibly independent third embodiment of the rescue load distribution element 1 with sub-chambers 28 is shown, wherein again the same reference symbols or component designations are used for the same parts as in the previous figures. Here too, in order to avoid unnecessary repetition, reference is made to the detailed description in the previous figures.

In the embodiment shown, the boundary casing 11 is divided into five equally sized sub-chambers 28, wherein the sub-chambers 28 are not completely separated from one another: Rather, the filling material 21 can move and/or distribute between the sub-chambers 28 in a limited manner, i.e. via openings 29.

The type and size of the sub-chambers 28 are shown in the Fig.5 are to be understood as examples and can also be implemented in a different way. For example, it is not absolutely necessary that all Partial chambers 28 are the same size and have the same characteristics. Rather, it is conceivable that at least some of the partial chambers 28 are designed without openings 29 and thus have an unchangeable proportion of filling material 21.

Fig.6 discloses a further cross-section of a rescue load distribution element 1 according to a conceivable fourth embodiment variant, wherein again the same reference symbols or component designations are used for the same parts as in the previous figures. Here too, in order to avoid unnecessary repetition, reference is made to the detailed description in the previous figures. In contrast to Fig.4 the airtightness in Fig.6 not by means of an airtight boundary casing 11, but rather with an airtight inner casing 30. In the present example, both the vacuum valve 16 and the closable opening 24 can establish a connection between the environment and the chamber 20 or between a vacuum pump (not shown) and the chamber 20 by being guided through the boundary casing 11 and the inner casing 30.

The Fig.7 discloses a fifth embodiment of a rescue operation load distribution element 1 with a dimensionally stable pressure element 22, which is or can be attached to the load-bearing surface 7 of the limiting sleeve 11 by means of manually or tool-free detachable coupling means 31, in the case shown by means of belts 32. In the embodiment shown, the belts 32 primarily serve to fix the pressure element 22 relative to the limiting sleeve 11, so that positioning of the rescue operation load distribution element 1 is made easier. The support contour 23 of the dimensionally stable pressure element 22 offers an optimal shape or load-bearing surface 7 for supporting a hydraulic cylinder 3. The support contour 23 can, for example, be designed in a rung-like, wave-like or grid-like manner. The limiting sleeve 11 can adapt ideally to the dimensionally stable pressure element 22 if the underside of the pressure element 22 is contoured. The easy detachability of the straps 32 enables separate use, so that the rescue load distribution element 1 can also be used without the dimensionally stable pressure element 22.

Fig.8 shows a sixth embodiment of a rescue load distribution element 1 with at least one comparatively dimensionally stable pressure element 22, wherein the at least one dimensionally stable pressure element is formed from a hard rubber plate and by means of a Velcro fastener 33 is detachably connected to the rescue load distribution element 1. The shape of the comparatively dimensionally stable pressure element 22 is based on the support surfaces of the hydraulic cylinder 3 in terms of outline contour and size. The at least one pressure element 22, which is relatively dimensionally stable compared to the limiting sleeve 11, can also be permanently connected to the limiting sleeve 11, in particular glued and/or sewn on.

The embodiments show possible embodiment variants, whereby it should be noted at this point that the invention is not restricted to the specifically illustrated embodiment variants thereof, but rather various combinations of the embodiment variants with each other are also possible and this possibility of variation lies within the skill of the person skilled in the art in this technical field due to the teaching on technical action through objective invention.

The scope of protection is determined by the claims. However, the description and the drawings must be used to interpret the claims. Individual features or combinations of features from the different embodiments shown and described can represent independent inventive solutions in themselves. The task underlying the independent inventive solutions can be taken from the description.

All information on value ranges in the description in question is to be understood as including any range and all subranges thereof, e.g. the information 1 to 10 is to be understood as including all subranges starting from the lower limit 1 and the upper limit 10, i.e. all subranges begin with a lower limit of 1 or greater and end with an upper limit of 10 or less, e.g. 1 to 1.7, or 3.2 to 8.1, or 5.5 to 10.

Finally, for the sake of clarity, it should be noted that in order to better understand the structure, some elements have been shown not to scale and/or enlarged and/or reduced.

Reference symbol list

1 Rescue operation load distribution 27 anti-slip surface element 28 Partial chamber 2 Rescue equipment 29 breakthrough 3 Hydraulic cylinder 30 Inner cover 4 external object 31 Coupling agent 5 vehicle 32 belt 6 End 33 Velcro fastener 7 Load bearing area 8th Load transfer area 9 Door section 10 A-pillar 11 Boundary envelope 12 Load according to arrow 13 Handling and/or fixing element 14 Handle 15 Valve 16 Vacuum valve 17 Edge 18 loop 19 eyelet 20 chamber 21 filling material 22 dimensionally stable pressure element 23 Outline or support contour 24 lockable opening 25 air- and/or liquid-tight impregnation 26 non-flammable or flame-retardant coating

Claims (21)

1. A use of a rescue operation load distribution element (1) for supporting pressure-generating rescue devices (2) on a vehicle (5) involved in an accident, wherein the load distribution element comprises at least one load receiving surface (7) for the introduction of a support load of a rescue device (2) and

   at least one load transfer surface (8) for transferring the support load to an external object (4),

   characterized in that

   at least the load transfer surface (8) is formed by a partial section of a deformable boundary envelope (11), and that

   the boundary envelope (11) delimits at least one chamber (20) at least in some sections, which chamber (20) is at least partially filled with a flowable or shape-flexible filling material (21).
2. The use of a rescue operation load distribution element (1) according to claim 1, characterized in that at least one handling and/or fixing element (13) is formed on the boundary envelope (11).
3. The use of a rescue operation load distribution element (1) according to claim 1, characterized in that the handling and/or fixing element (13) is formed by at least one handle (14), by at least one form-flexible loop (18) and/or by at least one eyelet (19).
4. The use of a rescue operation load distribution element (1) according to one of the preceding claims, wherein the boundary envelope (11) is configured to be liquid-repellent or liquid-tight or has a liquid-repellent or liquid-tight impregnation (25).
5. The use of a rescue operation load distribution element (1) according to one of the preceding claims, wherein the boundary envelope (11), at least in some sections, has a slip-resistant surface (27) which is formed by a coating or consists at least partially of a slip-resistant material, for example an elastomeric plastic material.
6. The use of a rescue operation load distribution element (1) according to one of the preceding claims, wherein the boundary envelope (11) consists of non-flammable or flame-retardant material or has a non-flammable or flame-retardant coating (26).
7. The use of a rescue operation load distribution element (1) according to one of the preceding claims, characterized in that the boundary envelope (11) is formed from a form-flexible material with increased tensile strength, for example from aramid, leather, natural fibers, carbon fibers or a combination thereof, so that the rescue operation load distribution element (1) can withstand a load of more than 20 kN.
8. The use of a rescue operation load distribution element (1) according to one of the preceding claims, characterized in that the filling material (21) is formed from a granular material, for example sand, plastic material, or a mixture of these components.
9. The use of a rescue operation load distribution element (1) according to one of claims 1 to 7, characterized in that the filling material (21) is formed from a loose knitted fabric or structure of fibers, for example cotton.
10. The use of a rescue operation load distribution element (1) according to one of claims 1 to 7, characterized in that the filling material (21) is formed from a liquid, in particular from water, or from a gel-like substance.
11. The use of a rescue operation load distribution element (1) according to one of the preceding claims, characterized in that the chamber (20) is subdivided into a plurality of subchambers (28) which are at least partially separated from one another, so that a minimum degree of distribution of the filling material (21) is provided.
12. The use of a rescue operation load distribution element (1) according to one of the preceding claims, characterized in that a completely closed chamber (20) is formed by means of the boundary envelope (11).
13. The use of a rescue operation load distribution element (1) according to one of the preceding claims, characterized in that a proportion of the filling material (21) in the maximum volume of the chamber (20) is more than 33%, in particular more than 50%, preferably in a range from at least 60% up to and including 98%.
14. The use of a rescue operation load distribution element (1) according to one of the preceding claims, characterized in that the boundary envelope (11) is configured to be airtight or has an airtight impregnation (25) and has a valve (15), preferably a vacuum valve (16), with which a flow connection between the boundary envelope (11) and the chamber (20) can be established and stopped as required.
15. The use of a rescue operation load distribution element (1) according to one of the preceding claims, characterized in that the boundary envelope (11) is formed from airtight material or the boundary envelope (11) has an airtight impregnation (25), or that the boundary envelope (11) comprises an inner envelope (30) of airtight material, or that the boundary envelope (11) comprises an inner envelope (30), which inner envelope (30) has an airtight impregnation (25), wherein the inner envelope (30) is located between the boundary envelope (11) and the chamber (20).
16. The use of a rescue operation load distribution element (1) according to one of the preceding claims, characterized in that the boundary envelope (11) and/or the inner envelope (30) has a closable opening (24) through which the amount and/or type of filling material (21) can be changed or exchanged.
17. The use of a rescue operation load distribution element (1) according to one of the preceding claims, characterized in that the chamber (20) contains, in addition to the flowable and/or form-flexible filling material (21), at least one comparatively dimensionally stable pressure element (22) with a predefined support contour (23).
18. The use of a rescue operation load distribution element (1) according to one of the preceding claims, characterized in that a comparatively dimensionally stable pressure element (22) with a predefined outline or support contour (23) is attached to the outside of the boundary envelope (11), wherein the outline or support contour (23) comprises the load receiving surface (7).
19. The use of a rescue operation load distribution element (1) according to one of the preceding claims, characterized in that the comparatively dimensionally stable pressure element (22) is connected to the boundary envelope (11) and/or the inner envelope (30) in a positionally fixed manner.
20. The use of a rescue operation load distribution element (1) according to claim 19, characterized in that a coupling means (31), which can be actuated manually and/or without tools, is formed for the optionally releasable connection of the comparatively dimensionally stable pressure element (22) to the boundary envelope (11) and/or the inner envelope (30).
21. The use of a rescue operation load distribution element (1) according to one of the preceding claims, characterized in that the boundary envelope (11), at least in some sections, has a manually activatable and deactivatable coupling means (31), in particular a hook-and-loop fastener (30), and that a plurality of rescue operation load distribution elements (1) can be connected and/or stacked as required by means of the coupling means (31).

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