NL1044378B1 - Plug with Plunger - Google Patents

Abstract

There are two options for retrofitting fasteners in existing stone-like materials, namely drilling a hole into which a fastener is placed and 'shooting' a fastener. In the latter method, a fastener is placed in the material with a large kinetic force 5. When drilling takes place, the hole can then be filled. Depending on the circumstances, the most ideal option is chosen. The desire is the possibility to apply the properties of a sleeve with or without thread into existing stone-like material. Sleeves with internal threads have the great advantage that fasteners can be taken in and out again and again, whereby the force exerted on the fastener remains of constant quality. The stony surface also remains intact. The desire is to introduce the properties of a sleeve with or without thread into existing stone-like material. 15 20 25 30 1044378

Description

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Description Plug with Plunger

There are many solutions available for attaching metal fasteners to stony materials. For the metal fasteners applied in the stone-like material, a force is exerted on the inserted metal fastener after use. The direct and indirect adhesion of the inserted metal fastener to the stone-like material differs and determines the quality and strength of the fastener.

When a stone-like construction is made, for example from concrete or masonry, metal or reinforced plastic sleeves with threads can be included in the construction. Sleeves with internal threads have the great advantage that fasteners can be taken in and out again and again, while the force exerted on the fastener remains of constant quality. The stony surface also remains intact. When the sleeves are included in the construction at the time it is made, the adhesion is optimal and with bulges on the sleeve it becomes part of the stone-like material. The characteristic of these sleeves is that the attachment is as strong as the Ils is strong and does not depend on the attachment.

There are two options for retrofitting in existing stone-like materials, namely drilling a hole into which a fastener is placed and 'shooting'.

The latter method involves inserting a fastener into the material using a high kinetic force. When drilling takes place, the hole can be filled. Depending on the circumstances, the most ideal option is chosen.

The desire is the possibility to apply the properties of a sleeve with or without thread into existing stone-like material. In order to provide a sleeve in stone-like material that can be retrofitted in a simple manner, a new facility has been devised, the actual invention.

To apply the invention, a hole is first drilled into the stony material. The diameter of the hole is matched to the outer diameter of the sleeve to be inserted. A hollow soft metal sleeve is inserted into the hole, the end of which is machined in such a way that it is point-shaped. A non-closed ring, whether or not stainless steel, is inserted around the point in a recess intended for this purpose.

When the metal sleeve has been inserted to the desired depth, a plunger is inserted into the hollow sleeve. In another version, the metal sleeve is already provided with the plunger. Then a firing pin with an outer diameter slightly smaller than the inner diameter of the sleeve is inserted into the hollow metal sleeve. Now the plunger can be driven through the pre-formed tip with the firing pin, causing it to expand and the end of the sleeve to clamp in the stone-like material. Because the composition of the sleeve is softer

IO 1s then the plunger and the ring, it forms completely! firmly in the stony material.

Because the ring is not closed but has an open part, material is pressed into the vacated space so that the sleeve cannot rotate or it is very difficult to rotate.

The invention will be explained in more detail on the basis of drawings with exemplary embodiments (limitative). It also shows:

Fig. 1 is a cross-section of the invention with screw thread, the plug with plunger;

Fig. 2 a cross-section of the plug with plunger, in a pre-drilled hole;

Fig. 3 shows a cross-section of the plug with plunger in a pre-drilled hole, after which a fastener can be fitted through the thread provided in the sleeve;

Fig. 4 is a cross-section of another version of the plug with plunger, with a thickened stop point at the rear:

Fig. 5 is a cross-section of this version of the plug with plunger, which is clamp-fitted in both the inner and outer walls.

In Fig. 1 shows a hollow soft metal sleeve (1) with a screw thread (2), which is made pointed at the end by incision and deformation (3) and provided with an open ring (4) on the thus narrowed part. A carbide plunger (5) is fitted in the soft metal sleeve. In a special design, the carbide plunger is provided with ribs at the tip that ensure that the plunger can be driven in but cannot slide back,

In Fig. 2 shows a situation where the plug (1) with plunger is inserted into a pre-drilled hole, with the diameter of the plug, in stony material (6) and if it is sufficiently deep and clean, the plug can be removed with a blow. on a firing pin (7) and thus on the plunger ($).

Fig. 3 shows that once fitted, the sleeve (1) forms a thread in a stone-like material, after which bolts (8) and other threaded fasteners can easily be fitted.

The sleeve can have different designs, such as different soft metals such as copper, aluminum, zinc, etc., but also reinforced plastic. The pointed end of the sleeve can also be created in various ways, taking into account curling the end so that when the plunger is driven in, not only the ring, but also the folded sleeve material is clamped in the hole.

Another situation is one in which two stone-like materials are connected to each other with a metal attachment, namely the cavity wall. Facades for homes and buildings that are composed of masonry are constructed from two separate masonry walls to prevent moisture penetration. The brick wall on the inside of the building is the inner leaf, the one on the outside is the outer leaf, and the space in between is the cavity. The construction is called a “spun wall”.

For the sake of the stability of the sometimes thin walls, the inner and outer leaves are interconnected by steel pins, so-called wall ties. The outer leaf is exposed to sun, wind & rain. To prevent moisture from penetrating the wet outer leaf, the cavity is ventilated with outside air. This construction method is especially common in the Low Countries, where moisture problems in the form of mold and rot are significant. Buildings and homes with cavity walls last for decades. However, the wall ties, which are made of iron and steel, whether or not galvanized, rust away in the damp cavity.

With the removal of the spigot wall anchors, the cavity wall loses its stability, which can have major undesirable consequences. For example, parts of the outer facade can collapse due to suction during a storm. Research into the condition of existing cavity walls leads to the need for measures, such as re-stretching. of the outer leaf or the subsequent installation of new wall ties. There are some systems / solutions available for the latter, but these are expensive and laborious.

The problem is that if the outer leaf is removed and the anchorage to the inner leaf has to be made 'blind', it is sufficiently strong and reliable.

must be IG in order to provide the required resistance. Anchoring to the outer leaf is also difficult, especially if the repair should not have too many consequences for the appearance of the outer facade and therefore the building. An additional problem is that the wall tie does not absorb moisture. - whether a condensation bridge may form between the two leaves, ts A common method involves drilling a hole through the outer leaf, through the cavity, into the inner leaf with a masonry drill. A heavy stainless steel pin with a thread is screwed into the drilled hole. . This requires heavy tools and usually results in a Tors hole, which damages the outer facade. Another method is to use a long plastic plug, where a special stainless steel screw with double 29 thread provides a plug connection to the inner and outer leaves. The latter method also has a version with a chemical binder, where the plug is permeable and therefore allows the chemical agent to pass through, after which a steel pin is inserted into the whole,

In order to easily provide a retrofit anchoring of the inner leaf to the outer leaf, a different design of the plug with plunger is a more obvious solution.

In Fig. This is clarified in Figure 4, the hollow soft metal sleeve (1) is made pungent at the end (3) by crushing and deformation and provided with an open ring (4) on the thus deformed part. A carbide plunger (9) with a thickened stop point at the rear is fitted in the soft metal hollow. The rear of the soft metal sleeve is able to expand due to a cut in the event that the thickened stop point is hammered into the soft metal housing. In a special version, the carbide plunger is provided with ridges at the tip, which means that the plunger can be driven in but cannot slide back.

To apply the invention, as described above, a hole is first drilled through the outer facade, through the cavity into the inner leaf. The diameter of the hole is 10 mm, which, when made in the joint, will hardly damage the outer facade. disfigured.

In Fig. § shows how the hollow soft metal sleeve with carbide plunger is inserted into the hole. When the sleeve and plunger is inserted into the inner leaf, a firing pin drives the plunger into the deformed tip, which pinches the ring and forges the soft metal around the plunger. At the same time, the back is driven into the soft metal sleeve, whereby the back expands and the soft metal is forged around the carbide. The ribs prevent the plunger from sliding back and the hollow metal sleeve grips tightly through the cavity (10) in both the inner (11) and the outer wall (12).

Claims (9)

Conclusions 1. The invention comprises a simple way of firmly anchoring a soft metal sleeve, with or without thread, in stony material by means of expansion at one or more provided locations using a carbide plunger, wherein the soft metal sleeve provides both an attachment point for other parts can be as the fastener itself can be. 2. If two stone-like materials need to be coupled or mutually attached, the soft metal sleeve can be provided with a carbide plunger that simultaneously expands the soft metal sleeve in two places, thereby forming a rock-solid attachment between these materials. 3. The expansion can be achieved by cutting into the soft metal sleeve, making it possible to reduce the diameter at the location of the cuts and applying filler material at the location of the reduced diameter, which becomes clamped by hammering in the plunger. to sit between plunger and drilled cavity. 4. Filling material for clamping can consist of a carbide open ring, which prevents the sleeve from twisting in the drilled hole after hammering in. 53. Impingement filler material may consist of recurved material from the inserted soft metal sleeve, which forges the soft metal between the plunger and the heard cavity. 6. Filler material for clamping can be a combination of the above. 7. To help prevent the plunger from sliding back after stroke, it can be provided with ridges that are shaped in such a way that they act like a barb. 8. In another embodiment, the striking pin for the point is enclosed in the hollow metal pin/soft metal housing with which it forms one whole, so that it does not need to be additionally inserted after the soft metal sleeve has been fitted. 9. In another embodiment, the interruption halfway through the firing pin is designed in such a way that after driving the conical firing pin in the rear, the interruption expands extra, so that no moisture can run along the soft metal sleeve.