The invention is in the field of mechanical engineering and construction and concerns methods for anchoring a first object in a second object, for example being of a dense material or including hollow spaces.
Anchoring in objects that have a low density and/or low mechanical strength may be a challenge. Such objects for example include objects with macroscopic hollow spaces, for example bricks with hollow spaces (so-called “hollow bricks”). For these, there exist special dowels that provide some anchoring strength for a further object (such as a screw) despite the special properties of the objects with the hollow spaces. Such special dowels are pushed into pre-drilled holes in the objects and have the property of spreading when thereafter a screw is inserted, so as to anchor the screw by the conventional dowel principle. A disadvantage is that the anchoring strength is limited. Especially, given the limited axial extension (extension with respect to an axis of the pre-drilled holes) hollow spaces often have, the extent by which the dowel may expand into the hollow spaces depends on the material strength, with only little expansion being possible if the dowel material is comparably strong. This limits the anchoring strength.
A further category of objects in which anchoring is a challenge is constituted by objects of dense materials that are not meltable and have a low ductility so that fastening methods like welding or anchoring a screw are not applicable. Such objects for example include objects of concrete, brick, hardened plaster, ceramics, stone, glass etc. For fastening a first object to a second object of such material, according to the prior art often curable resins were used. While such curable resins have the potential of yielding a very strong connection, they firstly have the disadvantage that curing often takes a lot of time until the connection may be loaded. This makes processes more complicated and more expensive. A second disadvantage is that the presence of drill dust or other debris at the interface may cause the connection to become unreliable and to fail. In order to deal with this, further steps, such as cleaning steps after drilling, may be necessary, which adds additional complication.
The object of the present invention is to provide a method for anchoring a first object in a second object, which method works for a large variety of second objects, including objects of dense material having a low ductility, objects of low mechanical strength and/or objects of low density. It is a further object to provide a method of anchoring a first object in a second object which overcomes disadvantages of prior art anchoring methods and which especially is more efficient at least in some situations.
According to an aspect of the invention, a method of anchoring a first object in a second object is provided. To this end, initially, the second object is provided, wherein the second object includes an opening. Such opening may for example by provided by drilling into the second object. The opening can optionally be symmetrical about an opening axis. The first object has an insert portion that defines an insertion axis. The method includes inserting the insert portion in the opening, with a hardenable composition (for example liquid or pasty resin, pre-polymerized solid resin, mortar) between a wall of the opening and the insert portion, and causing mechanical vibration energy to impinge to cause the hardenable composition to undergo a chemical hardening process to yield a hardened composition, so that a first connection between the first object and the hardened composition and a second connection between the hardened composition and the second object results, whereby the first object is anchored in the second object.
The steps of inserting the insert portion into the opening and of causing mechanical vibration energy to impinge may in a group of embodiments be carried out at least partially simultaneously, i.e., the vibration may impinge while the insert portion is advanced into the opening (this does not exclude that the vibration energy continues to impinge after the advance movement has been completed, with the insert portion being held stationary). This has a plurality of advantages.
Firstly, the coupling of energy into the hardenable composition is more efficient. Due to the relative movement of the first object, the hardenable composition is displaced by the first object being inserted, especially if it is liquid or pasty, it and its surface structure and circulation caused by the movement of the first object assist in coupling energy into the hardenable composition. If the hardenable composition is solid, then friction between the first object and the hardenable composition assists in coupling energy into the hardenable composition.
Secondly, depending on the consistency of the hardenable component, insertion of the first object may be difficult or almost impossible without the effect of the vibration that has an initial effect of lowering the viscosity.
Thirdly, the in configurations in which the hardenable composition in addition to being hardened has to be driven outward into structures of the second object, the fact that the vibrations assist this driving-outward already during introduction may be helpful or even important: Without the vibration impinging the hardenable composition may, if sufficiently flowable, have the tendency to just flow back out of the opening when the first object displaces it during insertion, and additional measures have to be taken and substantial pressure may have to be applied to control the flow.
Further, the relative movement of the first object relative to the hardenable composition and/or the second object is helpful for there being circulation of hardenable composition material that helps to integrate drill dust or other debris material present in the opening. In this way, such drill dust or other material will not only be removed from the interface but in addition integrated into the hardenable composition to serve as a filler.
Even more, if the hardenable composition is dimensionally stable, the relative movement may also assist there being energy absorption at the interface between the hardenable component and the second object to cause local liquefaction of the hardenable component at this interface and interpenetration of structures of the second object or other bonding of the hardenable composition to the second object thereby.
In a group of alternative embodiments, the steps of inserting the insert portion into the opening and of causing the mechanical vibration energy to impinge may be carried out sequentially, i.e., the vibration energy impinges only after the insert portion has been inserted. This group of alternative embodiments features the advantage that the application of the ultrasound is much easier to control. Especially, this group of alternative embodiments is well suited for manual insertion of the insert portion independent of the viscosity of the hardenable composition.
Especially (but not only) in this group of alternative embodiments, also the inserting step may be carried out sequentially in that first the hardenable composition is dispensed into the opening and then the insert portion is inserted. If this is the case, it may be advantageous if the viscosity of the hardenable composition is relatively low, whereby the insert portion is subject to only a small mechanical resistance when being inserted.
In embodiments that feature dispensing the hardenable composition first and inserting the insert portion only after the dispensing (without or with mechanical vibration energy being coupled into the first object during inserting), the method may include mechanically coupling the first object to a sonotrode. Such sonotrode vibrates during the step of causing the mechanical vibration energy to impinge on the first object and thereby couples the vibration energy into the first object. Mounting the first object to the sonotrode is in contrast to a set-up in which the vibrating sonotrode merely hammers onto the first object for coupling the energy into it. By such a mechanical coupling between the sonotrode and the first object, the full amplitude is transmitted into the first object. Also, coupling of the vibration energy into the first object thereby is not influenced, or influenced only to a lesser extent by how strong any pressing force from the sonotrode onto the first object is. Thus, due to this mechanical coupling, the transmission of vibration energy into the first object does not depend on any mechanical resistance onto the first object.
Also in embodiments of the group of alternative embodiments, which feature carrying out the inserting first and only thereafter causing the mechanical energy to impinge, the first object may be coupled to the sonotrode already during insertion, before the sonotrode is set into vibrational motion.
Especially, but not only, in embodiments of the group of alternative embodiments, which feature carrying out the inserting first and only thereafter causing the mechanical energy to impinge, a resilient element may be placed between a distal end of the insert portion a bottom of the opening. Such resilient element may be such as to cause only a minimal damping in an amplitude range of up to about 200 μm (peak-to-peak). It may for example include one or more of: a mechanical spring (metallic, of a plastics); an elastomeric disc; a disc of a paper-like material such as paper or cardboard; see for example WO 2019/068901 for a definition of suitable materials). This measure serves to prevent the capability of the first object to vibrate from being impeded by physical contact between the first object and the—often hard—bottom of the opening. The resilient element may be placed before or after dispensing the hardenable composition. In embodiments, it may be pre-mounted to the distal end of the insert portion during the first object's insertion.
Due to the elastic element, the first object can vibrate essentially freely when the vibration energy is coupled into it, even if it is held against the bottom of the opening. This is advantageous in that the process is much easier to control compared to set-ups in which the first object cannot be held against the bottom of the opening. For example, due to this solution, activation by a hand-held tool is possible. Also automated solutions are easier to implement in that no device for controlling the position needs to be present; rather, it may be sufficient to just apply a pre-determined force to make sure that the first object ends in the desired position, introduced into the full depth of the opening.
Alternatively the sonotrode, or other part of the device, may include means that delimit the insertion of the first object in the hole so that it does not reach the bottom.
In embodiments, the hardenable composition, in addition to having a hardenable (for example cross-linkable) matrix, may have a filler that serves to increase the heat conduction and/or to increase absorption of vibration energy.
The filler may especially include a material that has a higher heat conductivity than the material composition that constitutes the matrix, for example higher by at least a factor 3.
Increasing the heat conduction is beneficial in view of the fact that absorption of mechanical vibration energy may take place rather locally, especially in places where there is physical contact between the first object and the hardenable composition and near vibration antinodes. The heat conduction increasing fillers assist the heat transport to portions of the hardenable composition that are not at these places and ensure a more homogeneous hardening during the vibration energy input and immediately thereafter. Suitable fillers comprise:
High thermal conductivity ceramics as fillers feature the advantage that in addition to having the high thermal conductivity, they are also corrosion resistant, and many of them are cost efficient, too.
In addition to material properties and concentration, also the shape (granular, spheric for optimal flowing behavior; fibrous, plate-like (for example as nanoplatelets) may have an influence on the thermal conductivity of the hardenable composition, for example by leading to a suitable percolation behavior.
A filler that serves to increase the absorption energy may have the effect of ensuring a sufficient heating already at comparably low amplitudes. Such a filler may for example include thermoplastic particles with a high internal damping, for example of a material that is has a glass transition temperature below room temperature or only slightly there above (for example below 50° C. or below 40° C.).
In addition or as an even further alternative, the hardenable composition may include an activator that is activated at a comparably low temperature so that a moderate heating is sufficient for initiating the hardening. While such compositions are more difficult to store, they may nevertheless constitute an option for certain special applications.
The first connection and/or the second connection may include an adhesive connection, which may include chemical bonds between the hardenable composition and the first/second object. For this, the effect of the mechanical vibrations causing an efficient wetting of the surface of the first/second object by hardenable composition material provides a strong benefit, in addition to the benefit coming from a substantial acceleration of the hardening process caused by the energy absorption.
In embodiments, the insert portion of the first object has an outer shape forming an undercut with respect to axial directions, whereby the first connection between the first object and the hardened composition includes a positive-fit connection, in addition or an alternative to including an adhesive connection.
In embodiments, the mechanical vibration energy also causes the hardenable composition to interpenetrate structures of the second object (especially structures adjacent the wall of the opening), whereby the second connection includes a (second) positive-fit connection between the hardened composition and the second object, in addition or as an alternative to including an adhesive connection.
A chemical hardening process is a process in which the chemical composition undergoes a substantial change, as opposed to mere physical process such as a freezing process (a freezing process being a process of solidification by mere change of the aggregate state). Usually, a chemical hardening process will be irreversible, i.e., it cannot be reversed by for example re-heating. Examples of chemical hardening processes used herein are curing processes in which molecules are for example caused to form a cross-linked network of polymer chains, chain polymerization processes, or hydration reactions.
In a group of embodiments, the hardenable composition, therefore, is a prepolymer. Then, the chemical hardening process may include a cross-linking process yielding a cured polymer. Also, other polymeric reactions, such as a chain polymerization process are possible.
In another group of embodiments, the hardenable composition is a mortar, and the chemical hardening process is a for example hydraulic curing (involving a hydration reaction).
In embodiments, as mentioned the mechanical vibration energy may also cause the hardenable composition to interpenetrate structures of the second object to cause, after solidification, a (second) positive-fit connection between the hardened composition and the second object. Then, the anchoring of the first object in the second object has properties of the so-called ‘Woodwelding’ anchoring, as has already been proposed in various publications, including WO 98/42988, for anchoring a joining element of a thermoplastic material in an object. The ‘Woodwelding’ process includes pressing the joining element against the object while mechanical vibrations are coupled into the object until thermoplastic material of the joining element becomes flowable and flows into structures of the object to yield, after re-solidification, a positive-fit connection between the joining element and the object. This approach leads to a solid and efficient anchoring especially in objects having a comparably high mechanical strength while nevertheless being porous or being capable of developing pores under the effect of hydrostatic pressure—for example wood or wood composites. However, there are limits to the method if the material of the object is too dense to be interpenetrated or comparably weak or brittle and/or if the material of the joining element is too soft for mechanical vibration to be transmitted through it without too high internal losses. The present invention deals with these limits: Firstly, a hardenable composition for example being a polymerizable material or mortar can be provided as a relatively soft material that has a high internal friction when subject to mechanical movement or even as an essentially liquid material. Therefore, when mechanical energy impinges, the hardenable composition may, due to internal friction and/or micro-circulation caused by the vibration, efficiently absorb energy and become heated independent of whether or not the circumstances allow for high external friction. Secondly, it is possible that the set-up is kept stable independent of the mechanical strength of the hardenable composition during the process so that the prepolymer/mortar may become entirely flowable if desired (this being in contrast to the ‘Woodwelding’ process where the joining element, with the exception of specific flowable regions, needs to maintain mechanical stability during the process). Thirdly, after hardening, the resulting hardened composition, especially polymer or hardened mortar material, may have a high mechanical stability in a state in which in embodiments it may interpenetrate both, structures of the first object and structures of the second object. Thus, the beneficial anchoring obtained in the Woodwelding process for mechanically stable second objects is obtained in accordance with embodiments of the present invention also in second objects of weaker/less dense material or material that may not be sufficiently interpenetrated by the hardenable composition. Also in the here-discussed embodiments that include interpenetration of material of the second object and/or structures of the first object by the hardenable composition to yield a positive-fit connection, the effect of the hardenable composition chemically bonding to the second object and/or the first object may be present, in addition to the positive-fit connection.
In embodiments, the hardenable composition has the property of reducing its viscosity upon activation by mechanical vibration. This may be due to being heated (i.e. a temperature dependent viscosity) or by the mechanical activation itself (thixotropy), or both. Thereby, the vibration energy input does not only activate the composition to harden, but initially also acts to ease introduction of the first object and, as the case may be, to cause the hardenable composition to interpenetrate structures of the second object and possibly of the first object.
In a group of embodiments, the second object has hollow spaces, wherein at least one of the hollow spaces opens into the opening and thereby forming radial outward extensions of the opening. Such hollow spaces are different from a mere (microscopic) porosity, which may be present in addition to the hollow spaces. Rather, they are macroscopic and have defined positions and shapes, in contrast to a mere porosity. The dimensions of the hollow spaces—and of the outward protrusions, are for example larger than 1 mm or larger than 2 mm in any direction/dimension. At least some of the hollow spaces thus may have a volume of at least of at least 10 mm3 or at least 100 mm3. The hollow spaces may be closed cavities or open cavities, formed for example by tube-shaped through openings in the second object, as is known for some bricks available on the market. The hollow spaces may for example form a regular pattern.
The first object may be of any material that does not become flowable under the conditions present during the process. For example, the first object may be metallic, such as of stainless steel, aluminum, wood or any other suitable material. It may optionally be equipped to be a sonotrode, i.e., to be directly coupled to a vibration generating apparatus.
The first object may have, on its insert portion, outer structures that form the mentioned optional undercut. In an example, such outer structures are formed by a thread, whereby the insert portion may for example belong to a threaded bar. Alternatively, the outer structures are formed by ribs that may run in tangential direction and/or in axial direction, or knurling patterns.
Outer structures of this kind may include micro-structures (yielding a micro-positive-fit), in the form of a surface having a roughness of greater than Ra=10 μm, greater than Ra=20 μm, greater than Ra=50 μm or even greater than Ra=100 μm) and/or macroscopic structures with protrusions/indentations of radial extensions of at least 0.2 mm or at least 0.5 mm or at least 1 mm or even 2 mm or more. Macroscopic structures cause a macroscopic positive-fit connection. In addition to yielding the positive-fit connection, such microstructures and especially macroscopic structures have the effect of causing local micro-flows, thereby coupling energy into the hardenable composition.
Generally, the hardenable composition may be in a liquid, pasty or solid state prior to the input of mechanical vibration energy.
If it is in a liquid (viscous) state (viscosity for example below 106 Pa s or 105 Pa s, below 104 Pa s or below 103 Pa s), then an additional stabilizing element, such as a meshed sleeve may have to be used.
When being in a pasty state (viscosity above 104 Pa s or 105 Pa s or 106 Pa s or below 103 Pa s), also an additional stabilizing element may be used, and/or its properties can be adapted to the shapes and dimensions of the opening and the insert portion in a manner that the insert portion is capable of displacing the hardenable composition but with a flow resistance sufficiently high so that the hardenable composition does not just flow away in an uncontrolled manner into structures of the second objects and/or out of the opening.
Both, when in a liquid state or when being in pasty state, the hardenable composition may be dispensed from a hardenable composition container, i.e., from a receptacle that contains more material than required for the individual opening. The method may then thus include dispensing the hardenable composition into the opening and/or onto the insert portion.
If the hardenable composition is in a solid state, it may be provided as an element having a defined shape (for example sleeve-shaped) and being dimensionally stable. To this end, it may be in a state in which it has a Young's modulus that is defied and that is for example at least 10 MPa, in some embodiments at least 100 Mpa. The dimension of such hardenable composition element may for example be such that the opening is slightly undersized, whereby the hardenable composition element is held in the opening by an interference fit and tends to expand into structures of the hole when relaxed by the impact of the mechanical vibration energy.
If the hardenable composition is in a solid state, it may especially be provided as a sheath-like (or tube-like) element with or without a closed bottom. An inner diameter of the sheath-like or tube-like element may be dimensioned to be smaller than an outer diameter of the insert portion, whereby upon insertion of the insert portion, material of the hardenable composition element is displaced, especially outwardly and possibly into structures of the second object, so that the mentioned anchoring in the second object may benefit.
For the hardenable composition to be in a pasty or solid state, it may include a resin that is pre-polymerized to a desired extent, but not fully cured, i.e., it may be a prepolymer. In addition or as an alternative, it may include a filler that enhances its viscosity/modulus. In the latter case, the resin may still be a monomer, the hardenable composition nevertheless optionally being pasty or even solid.
If the hardenable composition is a composition capable of being polymerized, as a material for the hardenable composition, any suitable composition that can be activated to form a polymer, especially a cross-linked polymer, is suitable. Often, such materials, for example prepolymers, exhibit thermoplastic properties, i.e., their viscosity can be lowered by heating. Thereby, the absorption of heat upon mechanical activation has as several functions. Firstly, it brings the hardenable composition into a more flowable state in which it flows better and therefore is in a condition such as to interpenetrate structures of the second object and if necessary also of the first object (this necessity arises if the hardenable composition is not already pre-assembled with the first object). Secondly, the heat absorption on a bit larger timescale ensures activation for the hardenable composition to harden, i.e., depending on its state, to form polymer chains, to modify/lengthen the polymer chains and/or to cross-link so that it becomes hard and mechanically stable. Further, it improves wetting of the surfaces, optionally both, of the second object and of the first object. A further possible effect of the mechanical activation is that it assists the driving of the hardenable composition into the structures of the second object. This may be potentially beneficial both, for better anchoring (positive-fit connection) and for repairing defects, especially in the second object. An even further possible effect is that drilling dust or other material present is being flown around and embedded in the hardenable composition material instead of impeding a reliable connection.
The hardenable composition may include a plurality of components for example mixed together immediately prior to the step of inserting the hardenable composition.
Examples of suitable compositions include oligomers, especially oligomers having thermoplastic or thixotropic properties, i.e., having the property of reducing the viscosity upon activation by mechanical vibration. For specific example of a prepolymer is a composition of components that mixed together harden to become a polyurethane or an epoxy.
In addition to a polymerizable component (monomer, prepolymer), the hardenable composition may optionally include a filler. Suitable fillers include the mentioned materials enhancing the thermal conductivity. More in general, they include ceramics, mineral fillers, fibers, thermoplastic bodies, etc. Their content may be chosen such that the desired mechanical properties, especially thermal conductivity and/or viscosity, are achieved.
The fillers, in addition or as an alternative to allowing an engineering of the thermal conductivity and/or viscosity, may optionally have one or more of the following additional functions:
As a mortar, the hardenable composition may include a hydraulic cement, and additionally water and possibly a filler. Also, for mortars, the above-mentioned effects of mechanical activation by vibration (initially bringing into a more flowable state, activation of the hardening process, wetting, driving into structures, integrating of drill dust or similar) may be present, as cements may exhibit thermoplastic and/or thixotropic properties. A further possible effect of the mechanical vibration energy that is especially manifest for mortars is that they assist local densification.
It is also possible that the hardenable composition in addition to a cement and fillers includes a polymeric filler or prepolymer filler, whereby the composition is a kind of mortar/polymer composite. This possibly increases the toughness of the connection.
For both, prepolymers and mortars, the hardened composition after the process may include one or more ingredients that were not present initially in the hardenable composition but that were absorbed during the process. Especially, if there is drilling dust or other debris in the opening, this may effectively be absorbed and even contribute to the stability of the composition by serving as a filler—as opposed to prior art approaches where dust compromises the bond quality, for example by preventing adhesive connections from working etc.
Applying the hardenable composition may include pre-assembling (during manufacturing) it with the first object or the second object or both, or providing it as an initially separate, dimensionally stable item that may be mounted to the first object or inserted into the opening (on site).
For example, the hardenable composition when in a pasty state may be filled into the opening, for example manually, by using a glue gun or the like, or in an automated process. Alternatively, it may form a sleeve or plug that is insertable into the opening. Such sleeve-like or plug-like item of the hardenable composition may also be mounted to the first object, for example by having an inner thread and being capable of being screwed onto the insert portion. As an even further alternative, the hardenable composition may be present as a—comparably thick—coating of the insert portion and/or as a coating of an opening wall of the opening.
In this, a “flowable state” implies that the material is at least sufficiently pliable for a permanent (and not only elastic) deformation to occur.
The mechanical vibration energy may include longitudinal vibration, especially ultrasonic vibration.
Mechanical vibration or oscillation suitable for the method according to the invention has preferably a frequency between 2 and 200 kHz (even more preferably between 10 and 100 kHz, or between 20 and 40 kHz) and a vibration energy of 0.2 to 20 W per square millimeter of active surface. The vibrating tool (e.g., sonotrode) is e.g., designed such that its contact face oscillates predominantly in the direction of the tool axis (longitudinal vibration) and with an amplitude of between 1 and 100 μm, preferably around 30 to 60 μm. Such preferred vibrations are e.g., produced by ultrasonic devices as e.g. known from ultrasonic welding. In addition or as an alternative to oscillating predominantly in the longitudinal direction, the vibrating tool may be designed to be subject to rotational oscillation or also transversal oscillation.
In this text, the terms “radial” and “axial” are to be understand as relating to the proximodistal axis which may, during the process, coincide with the respective axis of the opening.
Concepts of the present invention include the step of causing mechanical vibration energy to impinge for causing the hardenable composition to harden. This entails the advantages described in this text, namely that in addition to a rapid hardening (compared to an approach of just waiting until the composition has hardened), the wetting, the possible temporary reduction of viscosity (and possible interpenetration of structures), the improved wetting, and the possible integration of drill dust or other debris into the composite. Especially if these additional advantages are not important, then concepts of embodiments of the present invention may, however, also be useful if curing is caused by other energy input than mechanical vibration, for example irradiation (by laser radiation, UV radiation etc.), by induction, by other forms of heat input (for example by a flow of hot air or by a heated probe etc.) etc.
Then, method of anchoring a first object in a second object may include the steps of:
The method may especially include causing the energy to impinge while the insert portion is being advanced into the opening or alternatively, as described hereinbefore, only thereafter.
The method may include any one or combination of feature of the dependent claims. Especially, the insert portion of the first object may have an outer shape forming an undercut with respect to axial directions, whereby the first connection between the first object and the hardened composition includes a positive-fit connection. In addition or as an alternative, the hardenable composition is also caused to interpenetrate structures of the second object, whereby the second connection includes a positive-fit connection between the hardened composition and the second object. In addition or as an alternative to including a positive-fit connection, the first and/or the second connection may include an adhesive connection. Also, the properties of the first object, the second object, and the hardenable composition, which properties are discussed in the present text, may apply to methods with these alternative energy inputs as well.
The invention and embodiments thereof are described in further detail in connection with the appended drawings that are all schematical. Same reference numbers refer to same or analogous elements. In the drawings:
The first object 1 has a pin-like insert portion 11 and a head portion 12. The insert portion 11 has an outer shape that forms an undercut with respect to axial directions (the opening axis 30 is illustrated to coincide with the axis of the insert portion). In the illustrated embodiment, the insert portion is shown to have a plurality of protrusions, for example ribs, 15 for example being ridges extending circumferentially around the axis 30, with indentations between the ridges, whereby the insert portion has the undercut structures.
A sheath of the hardenable composition 5 (for example, prepolymer or mortar; in the description of some of the embodiments in this text, it is referred to a prepolymer as an example, the teaching being equally applicable to mortars) inserted in the opening. The sheath in
Instead of a sheath or other solid element, the hardenable composition may also be provided as a coating of the walls of the opening (covering all walls or just a portion of them) or may be provided as a coating of at least a part of the insert portion or dispensed as liquid or paste into the opening (see below). Then, the consistency of the hardenable composition may optionally be such that it is initially pasty or even liquid and not necessarily dimensionally stable.
For anchoring, the first object 1 is subject to mechanical vibration while the insert portion is pressed into the opening, or, to be precise into the hardenable composition material 5. The inner diameter of the sheath formed by the hardenable composition is undersized relative to the outer diameter of the insert portion 11. The mechanical vibrations may for example be coupled into the first object 1 by sonotrode (not shown in
In the embodiment of
In embodiments like the one of
In
For ease of manufacturing, in embodiments it may be advantageous that the undercut structures of the first object 1 form a thread. Depending on material properties, especially adhesion of the cured polymer to the material of the first object, thereby the anchoring of the first object in the second object may be reversible, in that after the curing the prepolymer forms an inner thread into which, and out of which, the first object 1 or an object with an identical thread, may be screwed reversibly.
Firstly, the hardenable composition material 5 is shown to partially fill the opening 21 in an initial state, so that the first object needs to be driven into it by the joint action of the vibration and a pressing force onto the first object. In such a configuration, dispensing is particularly easy and can be done from container containing a bulk of the material. Especially, the hardenable composition may be in a liquid (for example viscous) or pasty state. The introduction of the first object while being vibrated in addition to having the effects of causing the composition to flow into structures and to cause or accelerate the hardening process also causes some circulation in the hardenable composition material before it is hardened. This in addition to contributing to the energy input/heating also has the described effects of supporting a reliable wetting of the second object and the first object by the hardenable composition and of integrating drill dust or similar into the hardenable composition.
Secondly, the first object is illustrated to have an insert portion (with the protrusions 15 for example forming a thread) that tapers towards distally. This eases introduction into the hardenable composition material if the latter is comparably tough and/or hard.
Further possible design features that—in addition or as an alternative to the taper—ease introduction into the hardenable composition material may include at least one of: axially running grooves allowing a backflow of the hardenable composition towards proximally; a hollow shape, for example the shape of a hollow cylinder so as to reduce the amount of hardenable composition material to be displaced.
In
Also, independently of the nature of the opening, the prepolymer may be provided in a shape that it forms a bottom portion distally of the first object, as shown in
In the embodiments described so far both, the second object and the first object are provided with structures capable of being interpenetrated by the hardenable composition material while the same is in a flowable state to yield, after (re-) solidification, a first/second positive-fit connection with the first/second object, possibly in addition to an adhesive connection. This, however, is not a requirement. Rather, the invention is also useful if the connection between the hardenable composition and the first object and/or the connection between the hardenable composition and the second object is only an adhesive connection, without any interpenetration.
The hardenable composition 5 is in a liquid or pasty state and is dispensed into the opening by a suitable dispensing device. Then, the first object 1 is inserted while being vibrated, whereby the insert portion is moved into the opening and pressed into the hardenable composition 5, whereby the hardenable composition 5 is locally displaced and set into motion. After a very short time, for example less than a minute, the hardenable composition is hardened and adheres both, to the walls of the opening 21 as well as to the insert portion 11.
For example in embodiments in which the second object includes macroscopic hollow spaces 23, there is the option of providing an auxiliary element for stabilizing the hardenable composition prior to its hardening if the hardenable composition is initially liquid or pasty.
While the depicted embodiment shows these differences in combination, they would be implementable individually or in sub-combinations, even though these features act in a synergistic manner. This is especially true for the dispensing in a flowable state and the mechanical coupling between the first object and the sonotrode, as well as for the elastic element together the coupling of vibration energy into the first object after its introduction.
As in any embodiment, also in the embodiments of
The invention is not restricted to these embodiments. Other variants will be obvious for the person skilled in the art and are considered to lie within the scope of the invention as formulated in the following claims. Individual features described in all parts of the above specification, particularly with respect to the figures may be combined with each other to form other embodiments and/or applied mutatis mutandis to what is described in the claims and to the rest of the description, even if the features are described in respect to or in combination with other features.
Number | Date | Country | Kind |
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00238/21 | Mar 2021 | CH | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2022/055618 | 3/4/2022 | WO |