WO2024110550A1 - Swing hammock suspension, swing hammock system, and method for connecting a receiving device to at least one spring element - Google Patents

Abstract

The invention relates to a swing hammock suspension (1) for connecting at least one spring element (2) to a receiving device (3). The swing hammock suspension (1) comprises at least one securing element (4) for securing the spring element (2) and at least two hook elements (5) for securing the receiving device (3). The at least one securing element (4) and the at least two hook elements (5) are mutually spaced in a first direction (R1), and the two hook elements (5) are mutually spaced in a second direction (R2) which is substantially orthogonal to the first direction (R1). The invention additionally relates to a swing hammock system (10) and to a method for connecting a receiving device (3) to at least one spring element (2).

Description

Spring cradle suspension, spring cradle system and method for connecting a receiving device to at least one spring element

The present invention relates to a spring cradle suspension for connecting at least one spring element to a receiving device, a spring cradle system and a method for connecting a receiving device to at least one spring element.

Electrically powered spring cradles are known from the prior art. The spring cradles have a support device for holding a baby or a small child. The support device is usually a cloth-like structure in which the child can lie down. The support device is then connected to a suspension at certain points via a hook. The suspension is in turn attached to a drive unit using springs and a tension element. Consequently, it is known from the prior art to connect suspensions to the support device only at certain points using a carabiner. This means that the support device forms a triangular shape up to the connection point with the suspension.

However, the disadvantage of the known cradle systems is that the receiving device has to be attached to the suspension in a complicated way. It is also impractical that the receiving device can be rotated around the attachment point with the suspension, so that an opening of the receiving device is arranged at any point, which often makes access to the child in the receiving device difficult. Another disadvantage of the prior art is that a hammock suspended in a triangular carabiner can quickly change position. so that the hammock no longer hangs centrally in the suspension, especially when a baby moves in the hammock or turns to the side.

Therefore, it is an object of the present invention to provide a system and a method which, on the one hand, allow easier operation for the user and, on the other hand, offer the greatest possible comfort for a child carried in the suspension.

This problem is solved with a spring cradle suspension having the features of claim 1, with a spring cradle system having the features of claim 24 and with a method for connecting a receiving device with at least one spring element having the features of claim 26.

According to one aspect of the present invention, a cradle suspension is provided for connecting at least one spring element to a receiving device, the cradle suspension comprising: at least one fastening for securing the spring element, at least two hook elements for securing the receiving device, the at least one fastening and the at least two hook elements being spaced apart from one another in a first direction, the two hook elements being spaced apart from one another in a second direction which is substantially orthogonal to the first direction.

Compared to the known prior art, the present invention provides the advantage that the receiving device (for example a hammock) and at least one spring element are suspended from the same component. This means that connecting elements (such as a triangular carabiner or the like) can be dispensed with. Furthermore, when at least one spring element is provided, a position or orientation of the receiving device (ie its position in three-dimensional space) can be defined. In other words, it can be prevented that the receiving device rotates or is rotatable freely around the connection point. By arranging the at least two hook elements, the receiving device is automatically in a fixed positional relationship to a series of spring elements suspended in the suspension. This means that an opening in the receiving device can easily be positioned in a desired area, for example so that the user has access to the receiving device and to a control panel of the cradle on the same side. Furthermore, by omitting further links between the receiving device and the spring elements, material abrasion, in particular metal abrasion, can be avoided, whereby standards such as DIN EN 1130 can be met. Furthermore, by hanging the receiving device in two hook elements, the height of the receiving device and thus the overall height of the spring travel can be reduced. Furthermore, the cradle suspension means that the receiving device requires less material compared to prior art cradles. For example, a hammock can require less fabric because the two hook elements mean that the receiving device (e.g. hammock) can already be held in an advantageous position.

This can reduce the overall space requirement of the cradle, which also allows it to be used in small spaces. Furthermore, by fixing the suspension device to two hook elements, the receiving device can be prevented from slipping. This can improve overall safety when operating the cradle. By designing the connection between the receiving device and the suspension as two hook elements, hanging and unhooking the receiving device can be made easier, since, for example, a hammock fabric can simply be inserted into the hook elements from above and no further steps are necessary for fastening. In other words, there is no need to screw a carabiner on and off, for example. This can improve the handling of the cradle. Furthermore, the cradle can be operated almost silently, since no connecting elements are required between the receiving device and the cradle suspension, which could potentially cause noise. In contrast, the prior art usually provides for triangular carabiners, for example, which can generate rattling noises during operation of the cradle. The cradle suspension can be a rigid component. The fastening for securing the spring element can be designed in such a way that a spring element can be hooked into it. In particular, the spring element can be positively connected to the cradle suspension. The cradle suspension preferably has a plurality of fastenings for securing a spring element in each case. The fastening can be a passive fastening. Passive can mean that a user does not have to handle the fastening in order to secure a spring element in it. In this context, handling can mean that the user changes the fastening in some way in order to attach at least one spring element to it. The cradle suspension is specially designed to be used in the area of children's or baby cradles. This must be taken into account in particular when configuring and/or choosing materials. In the area of children's or baby cradles, there are very specific requirements in terms of loads to be carried and durability compared to other technical areas. It is known in the art to open, unscrew and/or move suspensions or parts thereof in order to attach a spring element to them.

This is not necessary with the suspension according to the invention. This allows a particularly simple connection between the spring element and the cradle suspension to be realized. Furthermore, the cradle suspension can have more fastenings than necessary to fix all the required spring elements in it. This makes it possible, for example, to vary the number of spring elements that are actually used. This is important, for example, when particularly low weights act on the cradle suspension. The at least two hook elements can be rigid, immovable elements that do not have to be handled by the user in order to fix a receiving device to them. For example, each hook element can have a curved structure that can hold at least part of a receiving device in a form-fitting manner. This makes it particularly easy to fix the receiving device to the hook elements. In particular, the receiving device can be attached to the hook elements with one hand, for example. be placed, whereby the receiving device is held on the hook elements. The first direction can, for example, run along the direction of gravity when the spring cradle suspension is in an operating position. The second direction, on the other hand, can run orthogonal to the first direction. Furthermore, the second direction can run parallel to a horizontal when the spring cradle suspension is in an operating position. In other words, the two hook elements can be horizontally spaced from one another in the operating position of the spring cradle suspension. This can ensure that the receiving device, which is arranged between the hard hook elements, runs essentially horizontally. This can achieve a trapezoidal structure of the receiving device. This can reduce the height of the overall system, which can also reduce the space requirement. The receiving device is preferably a cloth-like structure, such as a hammock or the like. Preferably, at least one spring element can be attached exclusively to the at least one attachment. Preferably, the receiving device is attached directly to the hook elements. This means that a receiving device, such as a sling, can be arranged directly on the hook elements without the need for an additional component or the like to be interposed. This simplifies the overall system.

Preferably, a plurality of fastenings are provided, wherein the fastenings are arranged on the same straight and virtual line. In other words, the fastenings can be arranged in a row. Preferably, the row or the straight and virtual line extends along the second direction. This ensures that spring elements that are hooked into the fastenings can all have the same length, whereby the spring cradle suspension can hang horizontally and the spring elements can be variably exchanged. Furthermore, it is preferred that the at least two hook elements are arranged on a straight line that extends in the second direction. In other words, the two hook elements can be arranged on a horizontal line in an operating position of the spring cradle suspension. Since the second direction is orthogonal to the direction of gravity (in As the spring element is aligned with the spring element (operating state of the cradle suspension), a force distribution can be exerted symmetrically on the cradle suspension. This ensures that the receiving device, which can be attached to the cradle suspension, hangs straight. Furthermore, the fastenings can be arranged at the same distance from one another. This offers the advantage that spring elements which are suspended in the fastenings exert the same force on the cradle suspension, so that in the event of a dynamic oscillation of the cradle suspension, it can only oscillate in the vertical direction (in the operating position of the cradle suspension in the first direction) without causing undesirable sideways movements. This means that operation of the cradle suspension, for example in conjunction with a baby cradle, in particular with a cradle motor, can be designed to be particularly safe.

The spring cradle suspension preferably comprises a receptacle for securing a tension element. The tension element or tension cable can be a rope-like or band-like structure that can connect the spring cradle suspension to a drive unit. The drive unit can apply a tensile force to the tension element so that the spring cradle suspension and any receiving device attached to it can be moved in the vertical direction. Furthermore, the tension element can be a flexible element. The receptacle is preferably arranged on the same straight and virtual line on which the fastenings are arranged. In a preferred embodiment, the spring cradle suspension has five fastenings. The receptacle can be arranged between the second and the third fastening. The receptacle can have the same distance from the second fastening and from the third fastening. This has surprisingly led to the fact that when force is applied to the spring cradle suspension via the tension element, the spring cradle suspension can be moved in the vertical direction without causing a sideways movement (ie a movement in a direction orthogonal to the vertical direction). This means that the spring cradle suspension and a mounting device attached to it can be particularly securely mounted in the vertical Direction without causing deflections of the cradle alignment. In a further preferred embodiment, the cradle suspension comprises four fastenings and a tension element holder arranged exactly in the middle (with respect to the first direction). The tension element can extend along a force vector. This largely prevents sideways movement and swinging.

Preferably, the holder and the fastenings are arranged on the same straight and virtual line. Thus, a force can be applied in the first direction by the spring elements fixed to the fastenings and the tension element fixed to the holder at the same point on the cradle suspension. This can prevent swinging, particularly in the case of a dynamic vibration pattern that can be applied to the cradle suspension by the tension element and the spring elements. Swinging can mean an increasing lateral swinging or rocking. This can increase the safety of operating a cradle in which the cradle suspension is provided.

Preferably, the at least one fastening differs from the receptacle, in particular geometrically. In other words, the at least one fastening can be designed such that a tension element cannot be secured to it. Analogously, the receptacle can be designed such that a spring element cannot be secured to it. This makes it possible to implement a key-lock principle so that the user does not inadvertently secure a spring element in the receptacle and a tension element to one of the fastenings when assembling the cradle suspension. This can prevent incorrect assembly. This makes handling easier for the user and also ensures safe operation even with a system assembled by the user himself.

Preferably, the receptacle has a substantially rectangular cross-section. The rectangular cross-section can also be referred to as a square. The corners can be designed as acute angles. Accordingly A tension element can be provided with a corresponding fastening element, such as a hook, which has the same cross-section. This ensures that only the fastening element of the tension element can be secured to the holder. This can prevent a spring element from being incorrectly secured to the holder.

Preferably, the at least one fastening and/or the receptacle is/are designed as through holes. In other words, the fastening and/or the receptacle can be a recess in the material of the cradle suspension. In this case, the extension through the material of the cradle suspension can have a constant cross-section.

Preferably, the ratio of the extension of the cradle suspension in the first direction to the extension of the cradle suspension in the second direction is between 1.3 and 1.9, preferably between 1.5 and 1.7. The cradle suspension in the second direction can therefore have a greater extension than in the first direction. This makes it possible to achieve particularly good stabilization or stability during dynamic oscillation operation of the cradle suspension. The range between 1.5 and 1.7 has proven to be particularly advantageous, as this achieves the optimal ratio between the reduction in height in the vertical direction (i.e. in the first direction in the operating position) and a stable oscillation movement. This ensures that a baby cradle in which the cradle suspension is used as a connection between the receiving device and the spring elements can be designed to be particularly compact.

Preferably, the spring cradle suspension comprises a damping element which is arranged in the at least one fastening and/or in the receptacle and is designed to dampen a force applied to the spring cradle suspension. Furthermore, the damping element can be designed to hold a fastening element, with which the tension element or the spring element is fixed to the spring cradle suspension, in a certain position. This is particularly advantageous if the damping element is provided in the holder for securing the tension element. The tension element can be a flexible element, so that a fastening element with which the tension element is secured to the cradle suspension (for example a tension element hook) can be arranged and held in a stable position in the holder. This offers the advantage that, on the one hand, reduced noise can be generated by the rattling of a tension element hook and, on the other hand, tangling of the tension element in other elements can be avoided.

Preferably, the hook elements are designed in the same way. In other words, the hook elements can be symmetrical with respect to an axis of symmetry that runs along the first direction. This can ensure that the receiving device can be held in an identical manner by the two hook elements. Furthermore, a similar design of the hook elements can ensure that the spring cradle suspension hangs straight (i.e. horizontally aligned) in an operating state.

Preferably, the spring cradle suspension is integrally formed. In other words, the spring cradle suspension can be a one-piece component. Integral or one-piece can mean that individual elements of the spring cradle suspension cannot be separated from one another without causing damage. This allows a particularly simple component to be created. Furthermore, any noise generated due to elements of the spring cradle suspension being movable relative to one another can be avoided.

Preferably, each of the hook elements has a receiving section for receiving at least a part of the receiving device and an insertion section for passing through at least a part of the receiving device. Each of the hook elements can, for example, be a strip protruding in the first direction that is bent over to form a hook element. The receiving section can be designed to hold a part of the receiving device (for example a part of a hammock). The insertion section can have a smaller clear width in the third direction, which is orthogonal to the first and second directions, than the receiving section. This can ensure that a part of the receiving device which is received in the receiving section cannot be easily removed from the receiving section through the insertion section. This can ensure that the receiving device is securely held on the spring cradle suspension. The insertion section can be defined between two parts of the spring cradle suspension. The hook sections can each have a smaller extension in the second direction than the rest of the spring cradle suspension. This allows the receiving device to be held at certain points by the two hook elements.

Preferably, the receiving section is circular in shape at least in sections. The circular shape of the receiving section at least in sections ensures that at least part of the receiving device can be stored in the receiving section without being damaged. More precisely, the clear space (i.e. the receiving space for receiving at least part of the receiving device), which is defined in a cross section in the third direction and in the first direction, can be a substantially circular space. In contrast, a clear space which is defined in the insertion section in the third direction and the first direction can be a substantially rectangular space. This ensures that the part of the receiving device received in the receiving section cannot be removed from the hook elements without active intervention. The receiving device can thus be attached particularly securely to the cradle suspension.

Preferably, the cradle suspension has a general extension in the first direction, and the hook elements are preferably designed and provided such that a center point of the at least partially circular receiving section lies on a virtual and straight line that continues the general extension of the first direction. In other words the center of gravity of the clear receiving space, which is defined by the receiving section, can lie on a line that continues the general extension of the spring cradle suspension. This can ensure that the spring cradle suspension hangs straight when a receiving device is attached to it. More precisely, the general extension of the spring cradle suspension in the first direction can be aligned exactly in the direction of gravity. This can prevent any moments exerted on the spring cradle suspension or other elements connected to it. This can prevent material fatigue. Furthermore, unwanted deflection of the spring cradle suspension during dynamic operation can be avoided.

Preferably, the insertion section of at least one of the hook elements has a guide element which is designed to feed at least part of the receiving device to the insertion section for passage. In other words, the outer end (for example of a bent strip of the cradle suspension) can be shaped at an opening of the insertion section so that at least part of the receiving device can be fed to the insertion section and thus to the receiving section without any problems. Preferably, the bent end section which forms the insertion section has a 90° bend in order to be bent from an extension in the first direction to an extension in the third direction. This can prevent the receiving device from getting caught on a pointed end of the insertion section when the receiving device is inserted into the insertion section and thereby being damaged. This can prevent damage to the receiving device and ensure that a baby cradle in which the cradle suspension is used can be operated safely.

Preferably, the at least one fastening has a substantially rectangular shape in cross-section and in particular two corners of the cross-section are rounded. The cross-section can be defined in the first direction and in the second direction. Furthermore, the cross-section of the at least one fastening can have a greater extent in the first direction than the Receptacle. This can ensure that the spring element, which is designed to be fixed in the at least one fastening, cannot be fixed to the receptacle. Furthermore, the at least one fastening can have a smaller extension in the second direction than the receptacle. This can ensure, analogously to the above, that a tension element, which is designed to be fixed to the receptacle, cannot be fixed to the at least one fastening. Furthermore, the at least one fastening can be rounded on one end side in the first direction. In other words, the at least one fastening can have a semicircular end. This can ensure that a complementary element, which is intended to connect a spring element to the fastening, has a special shape that can only be fixed to the fastening in a certain orientation. This can prevent an unwanted separation between the spring element and the cradle suspension. This can increase the safety of operating a baby cradle in which the cradle suspension is provided. Furthermore, the fastening can be T-shaped on an opposite end side in the first direction. In other words, the fastening can have protrusions in the cross-section in the second direction. This makes the cradle suspension particularly easy to manufacture.

Preferably, a ratio between the extent of the at least one fastening in the second direction to an average extent of the spring cradle suspension in a third direction, which is orthogonal to the first and the second direction, is in a range of 0.8 to 1.2, preferably between 0.8 and 1.1. As a result, a spring element can only be fastened in a very specific orientation of the spring element (i.e. a fastening between the spring element and the spring cradle suspension). Safety can thus be increased by, for example, not being able to remove a spring element at an angle from the fastening. The range between 0.9 and 1.1 has proven to be particularly advantageous, since the connecting element which connects the spring element to the spring cradle suspension is particularly can be designed to be slim. This makes it possible for the spring elements to be arranged close to one another (ie in the second direction), whereby the spring cradle suspension can have a small extension in the second direction. This makes it possible to provide a particularly compact spring cradle suspension.

Preferably, the cradle suspension is made of stainless steel. By not using a coating, metal abrasion can be prevented and DIN EN 1130 can therefore be met. This means that the cradle suspension can even be used on cradles for babies and small children without causing any health damage to them.

Preferably, the fastenings are arranged symmetrically with respect to a line running in the first direction on the cradle suspension. This allows a uniform and problem-free introduction of force into the cradle suspension without deflections occurring transversely to the first direction (i.e. in the operating position in the vertical direction).

Preferably, the spring cradle suspension has a shape that widens in the second direction from one end in the first direction to its other end in the first direction and then tapers. When the spring cradle suspension is in operation, the spring cradle suspension can have a greater extension in the second direction on its upper side in the vertical direction than on its lower side in the vertical direction. Between the two sides, the spring cradle suspension can have a bulging shape. It has been found that the shape allows stresses in the material to be optimally distributed, which can prevent fatigue of the spring cradle suspension even under permanent vibration loads.

According to a further aspect of the present invention, a cradle system is provided, comprising a receiving device (receiving a child or baby), at least one spring element for attachment to a fixed object, wherein the receiving device and the at least one spring element are connected or connectable to a cradle suspension according to one of the above embodiments. The receiving device can be a hammock made of a fabric material. The spring element can be a coil spring. Furthermore, the tension element can be a compression coil spring. Compared to the known prior art, no further connecting elements are necessary. For example, the receiving device can be arranged directly on the hook elements of the cradle system.

The spring cradle system preferably comprises a drive unit that can apply a tensile stress to a tension element, wherein the tension element is fixed or can be fixed to the spring cradle suspension, in particular to a holder. In other words, the tension element can also be fixed to the spring cradle suspension. A hammock (holder device), springs (spring elements) and tension element can thus be suspended from the same component, which means that connecting links such as triangular carabiners can be dispensed with.

According to a further aspect of the present invention, a use of a cradle suspension according to one of the above embodiments is provided for connecting a receiving device for receiving a child or baby to at least one spring element for fastening in a fixed object. The fixed object can be, for example, a suspension on an immovable object such as a door frame or ceiling hook or a fixed frame.

According to a further aspect of the present invention, a method for connecting a receiving device to at least one spring element is provided, the method comprising: providing a spring cradle suspension according to one of the above embodiments, securing the receiving device to the hook elements of the spring cradle suspension, and securing the at least one spring element to the spring cradle suspension. The spring cradle suspension can be a passive element which does not have any Special handling is required so that the receiving device or the spring elements can be attached to it. Rather, at least part of the receiving device can simply be hooked into the hook elements. This eliminates the need for laborious screwing on of a carabiner or the like. Furthermore, the spring elements can be attached to the cradle suspension with a simple fastening element that corresponds to the fastenings.

The method preferably includes securing a tension element, which can be moved with a drive unit, to the spring cradle suspension, in particular to the holder. The preferably flexible tension element can be secured to the spring cradle suspension in a similar manner. This makes it possible to provide a particularly simple system which simplifies handling on the one hand and increases safety during operation on the other.

Individual features or embodiments can be combined with other features or other embodiments to form new embodiments. The individual embodiments and advantages mentioned in connection with the features or the embodiment also apply analogously to the new embodiments. Furthermore, embodiments and advantages mentioned in connection with the device also apply to the method and the use and vice versa.

In the following, preferred embodiments are described in detail with reference to the accompanying drawings.

Figure 1 shows a perspective view of a cradle suspension according to an embodiment of the present invention.

Figure 2 shows a perspective view of a cradle suspension according to another embodiment of the present invention. Figure 3 shows a schematic section through the cradle suspension according to an embodiment of the present invention.

Figure 4 shows a front view of a cradle suspension according to an embodiment of the present invention.

Figures 5A and 5B show a front view of a cradle suspension, each according to an embodiment of the present invention.

Figure 6 schematically shows a spring cradle system according to an embodiment of the present invention.

Figure 7 schematically shows a perspective view of a spring cradle system according to another embodiment of the present invention.

Figure 8 shows schematically and in perspective another embodiment of a spring cradle system according to an embodiment of the present invention.

Figure 1 is a schematic and perspective view of a spring cradle suspension 1 according to an embodiment of the present invention. In the present embodiment, the spring cradle suspension 1 has 5 fastenings 4 for securing a spring element 2 (not shown in Figure 1). Furthermore, the spring cradle suspension 1 has a receptacle 6 for securing a tension element 7 (not shown in Figure 1). The spring cradle suspension 1 is a plate-like element which extends mainly in a first direction R1 and in a second direction R2. Furthermore, the spring cradle suspension has two hook elements 5. The hook elements 5 are similar, curved hooks into which a part of a receiving device 3 (not shown in Figure 1) can be secured. The hook elements 5 are shaped in such a way that they protrude from the area defined by the plate-like structure of the spring cradle suspension. nated plane. Figure 2 is a schematic and perspective view of a spring cradle suspension 1 according to a further embodiment of the present invention. The present embodiment corresponds to the previously described embodiment with the difference that a damping element 8 is provided in the receptacle 6. More precisely, the damping element 8 holds a hook, to which the tension element 7 is connected, in a defined position on the spring cradle suspension. This can prevent the flexible tension element 7 from getting caught on other elements or the spring cradle suspension 1 during a dynamic up and down movement in the first direction R1. Furthermore, the damping element 8 can prevent noise such as rattling or the like. In the present embodiment, the damping element 8 is made of a rubber-like material with good damping properties. The damping element 8 can preferably be made of a softer material than the rest of the spring cradle suspension 1.

Figure 3 is a schematic sectional view through the spring cradle suspension 1 in a sectional plane defined by the first direction R1 and the second direction R2. In Figure 3 it can be seen that the hook section is formed from an insertion section 51 and a receiving section 52. The insertion section 51 has a smaller clear width in the second direction R2 than the receiving section 52. This ensures that the receiving device is held securely in the hook element 5. It can also be seen that the center of the clear receiving space of the receiving section 52 lies exactly in a line of the general extension of the spring cradle suspension 1 in the first direction R1. This can prevent the spring cradle suspension from being deflected in the second direction R2 during operation (i.e. in a case where the receiving device is held in the receiving section 52). It can also be seen that the hook element 5 has a guide element 53 which protrudes from the insertion section 51. In other words, the guide element 53 is an outer end of the insertion section 51 bent in the second direction R2. This can prevent the receiving device from being damaged if it is not fully inserted into the hook element 5. Furthermore, this can simplify the process of inserting the receiving device into the hook element itself.

Figure 4 is a schematic front view of the spring cradle suspension according to an embodiment of the present invention. The present embodiment corresponds to the embodiment shown in Figure 1. In Figure 4 it can be seen that the fastenings 4 are arranged at equal distances from one another on the spring cradle suspension 1. It can also be seen that the receptacle 6 is arranged between the second and the third fastening. In addition, the spring cradle suspension 1 has a greater extension in the second direction R2 on one side in the first direction (on the upper side in the operating position) than on the opposite side in the first direction R1. In between, the spring cradle suspension 1 has a bulge in the second direction R2. The bulge enables a particularly advantageous force distribution to be achieved in the material of the spring cradle suspension, so that material fatigue can be avoided.

Figure 5A is a schematic front view of the cradle suspension according to an embodiment of the present invention. The cradle suspension shown in Figure 5A corresponds essentially to the embodiment shown in Figure 4, with the difference that exactly four fastenings 4 are provided. Furthermore, the fastenings 4 are arranged symmetrically about a central axis which extends in the first direction R1. The receptacle 6 is located on the central axis. In other words, the receptacle 6 is arranged in the middle of the fastenings 4 in the second direction R2. A distance between two adjacent fastenings 4 is identical to a distance between the receptacle 6 and adjacent fastenings 4.

Figure 5B is a schematic front view of the spring cradle suspension according to an embodiment of the present invention. The spring cradle suspension shown in Figure 5B corresponds essentially to the embodiment shown in Figure 4, with the difference that a distance between two adjacent fastenings 4 is not identical to a distance between the receptacle 6 and adjacent fastenings 4.

Figure 6 shows a schematic and perspective view of part of a spring cradle system. In the embodiment shown in Figure 6, spring elements 2 are suspended from the spring cradle suspension 1 using spring element hooks 21. More precisely, the spring element hooks 21 are fixed to the fastenings 4. The spring element hooks 21 are designed in such a way that they can only be inserted into the fastenings 4 of the spring cradle suspension in a defined position. This can prevent the spring element hooks 21 and the spring cradle suspension 1 from accidentally coming loose. It can also be seen that not all fastenings 4 are equipped with spring elements.

2 must be in contact. In particular, this may depend on the weight of a person who is to be accommodated in the receiving device 3.

Figure 7 is a schematic and perspective view of a spring cradle system 10 according to another embodiment of the present invention. In the present embodiment, the spring cradle system comprises a drive unit 8. The drive unit 8 can apply a tensile force to a tension element 7. The tension element 7 is in contact with the spring cradle suspension 1 via a tension element hook 71. More precisely, the tension element hook 71 is fixed to the receptacle 6 of the spring cradle suspension 1. In addition, 2 spring elements 2 are fixed to the spring cradle suspension 1 with their spring element hooks 21. A part of a receiving device is attached to the hook elements.

3. The receiving device 3 is a hammock made of fabric that can be easily hooked into the hook elements 5. During operation, the drive unit 8 can pull the pulling element 7, whereby a movement of the cradle suspension 1 and the receiving device 3 attached to it can be realized in the first direction. Periodic vibrations can be generated by targeted control of the drive unit 8. Figure 8 is a perspective and schematic view of a weighing system 10 according to a further embodiment of the present invention. The present embodiment corresponds essentially to the embodiment shown in Figure 7 with the difference that the drive unit 8 is not fixed to an object above it, but is arranged on a stand structure. Furthermore, the spring elements are not fixed directly to the drive unit 8, but to a corresponding device on the stand structure. Furthermore, in the present embodiment, 5 spring elements are suspended from the receiving device 1.

List of reference symbols:

1 spring cradle suspension

2 Spring element

3 Recording device

4 Fastening

5 hook elements

6 Recording

7 Tension element

8 Damping section

10 Spring cradle system

21 spring element hooks

51 Introduction section

52 Recording section

71 Tension element hook

R1 first direction R2 second direction

Claims

Claims Spring cradle suspension (1) for connecting at least one spring element (2) to a receiving device (3), comprising: at least one fastening (4) for securing the spring element (2), at least two hook elements (5) for securing the receiving device (3), wherein the at least one fastening (4) and the at least two hook elements (5) are spaced apart from one another in a first direction (R1), wherein the two hook elements (5) are spaced apart from one another in a second direction (R2), which is substantially orthogonal to the first direction (R1). Spring cradle suspension (1) according to claim 1, further comprising a receptacle (6) for securing a tension element (7). Spring cradle suspension (1) according to claim 2, wherein the receptacle (6) and the at least one fastening (4) are arranged on the same straight and virtual line. Spring cradle suspension (1) according to claim 2 or 3, wherein the at least one fastening (4) differs from the receptacle (6), in particular geometrically. A cradle suspension (1) according to any one of claims 2 to 4, wherein the receptacle (6) has a substantially rectangular cross-section. A cradle suspension (1) according to any one of the preceding claims, wherein a plurality of fastenings (4) are provided, wherein the fastenings are arranged in a row, and wherein the row extends along the second direction. Spring cradle suspension (1) according to one of the preceding claims, wherein a plurality of fastenings (4) are provided, wherein the fastenings (4) are arranged symmetrically with respect to a line running in the first direction on the spring cradle suspension (1). Spring cradle suspension (1) according to one of the preceding claims, wherein a ratio of the extension of the spring cradle suspension (1) in the first direction (R1) to an extension of the spring cradle suspension (1) in the second direction (R2) is between 1.3 and 1.9, preferably between

1.5 to 1.7. Spring cradle suspension (1) according to one of the preceding claims, wherein the hook elements (5) are of identical design. Spring cradle suspension (1) according to one of the preceding claims, wherein the spring cradle suspension (1) is of integral design. Spring cradle suspension (1) according to one of the preceding claims, wherein each of the hook elements (5) has a receiving section for receiving at least a part of the receiving device and an insertion section for passing through at least a part of the receiving device. Spring cradle suspension (1) according to claim 11, wherein the receiving section is circular in shape at least in sections. Spring cradle suspension (1) according to claim 11 or 12, wherein the insertion section of at least one of the hook elements (5) has a guide element which is designed to feed at least a part of the receiving device to the insertion section for passing through. Hammock suspension (1 ) according to one of claims 11 to 13, wherein the bent end portion forming the insertion portion has a 90° Has a bend in order to be bent from an extension in the first direction to an extension in the third direction. Spring cradle suspension (1) according to one of the preceding claims, wherein the spring cradle suspension has a general extension in the first direction, and wherein the hook elements (5) are preferably designed and provided such that a center point of the at least partially circular receiving section lies on a virtual and straight line which continues the general extension of the first direction. Spring cradle suspension (1) according to one of the preceding claims, wherein the at least one fastening has a substantially rectangular shape in cross section and wherein in particular two corners of the cross section are rounded. Spring cradle suspension (1) according to one of the preceding claims, wherein each of the hook elements (5) has a receiving section (52) for receiving (6) at least part of the receiving device (3) and an insertion section (51) for passing through at least part of the receiving device (3). Spring cradle suspension (1) according to claim 17, wherein the receiving section (52) is circular at least in sections. Spring cradle suspension (1) according to one of the preceding claims, wherein a ratio of the extension of the spring cradle suspension (1) in the first direction to an extension of the spring cradle suspension (1) in the second direction is between 1.3 and 1.9, preferably between 1.5 and 1.7. Spring cradle suspension (1) according to one of the preceding claims, wherein the spring cradle suspension (1) comprises a damping element, which- ches is arranged in the at least one fastening and/or in the receptacle and is designed to dampen a force applied to the cradle suspension (1).

21. Spring cradle suspension (1) according to one of the preceding claims, wherein a ratio between the extension of the at least one fastening (4) in the second direction (R2) to an average extension of the spring cradle suspension (1) in a third direction, which is orthogonal to the first and to the second direction (R2), is in a range from 0.8 to 1.2, preferably between 0.9 to 1.1.

22. Spring cradle suspension (1) according to one of the preceding claims, wherein the spring cradle suspension (1) is made of stainless steel.

23. A cradle suspension (1) according to any one of the preceding claims, wherein the cradle suspension (1) has a shape which widens in the second direction and then tapers from one end in the first direction to its other end in the first direction.

24. A cradle system (10), comprising a receiving device (3) for receiving a child or baby, at least one spring element (2) for attachment to a fixed object, wherein the receiving device (3) and the at least one spring element (2) are connected or connectable to a cradle suspension (1) according to one of the preceding claims.

25. Spring cradle system (10) according to claim 24, further comprising a drive unit which can apply a tensile stress to a tension element (7), wherein the tension element (7) is fixed or can be fixed to the spring cradle suspension (1), in particular to a receptacle (6). Method for connecting a receiving device (3) to at least one spring element (2), comprising:

Providing a spring cradle suspension (1) according to one of claims 1 to 23, fixing the receiving device (3) to the hook elements (5) of the spring cradle suspension (1), and

Fixing at least one spring element (2) to the cradle suspension (1).