DE29616950U1 - Threadlocker - Google Patents

Description

Screw locking

The innovation concerns a screw locking device on components that can be rotated or pivoted relative to one another, in particular on slewing rings of construction and work machines.

In the case of components that can be rotated or swiveled relative to one another, it often happens that the screws are not only subjected to the axial pre-tensioning forces but also dynamically stressed transversely to the axial direction. This stress can cause the self-locking in the thread to be eliminated and the screw connection to loosen. This is particularly noticeable in components such as slewing rings for construction and work machines, as it can happen that the upper part, which can be rotated or swiveled relative to a lower part, can tip off the lower part due to the screw connection becoming loose. In this case, high damage and subsequent costs for repairs can be expected, not only to the component, in particular the slewing ring, but also to the lower/upper part.

The aim of the innovation is therefore to design a screw locking device for the above-mentioned components, in which a removal of the self-locking in the thread in the area of the screw connection cannot lead to a loosening of the connection.

This aim is achieved by securing screws on components that can be rotated or pivoted relative to one another, in particular on slewing rings of construction and work machines, such as excavators, cranes or the like, with at least one matrix connecting several, in particular two, screw heads together and at least one securing element that can also be provided in the area of the screw heads above the matrix and that can be fixed relative to the matrix, in particular in a form-fitting manner.

Advantageous further developments of the subject matter of the innovation can be found in the subclaims.

By fixing at least two screw heads together, loosening of the individual screws and thus a loss of preload force is reliably prevented.

First, a matrix, preferably made of sheet metal and provided with passage areas, is placed over the screw heads in question. A sheet of metal with a hexagonal cutout corresponding to the wrench size of the respective screw head is preferably placed over this. These sheets are preferably welded to the corresponding matrix so that the screw heads are now blocked against each other.

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Since the sheets do not have a positive connection to the screws or other areas of the components, it is suggested that an additional safety measure be provided in the area of the respective screw head in order to prevent them from being lost due to them slipping off the screw heads. Clamping discs or locking rings (snap rings) inserted into the screw head can be used to safely prevent the connected sheets from slipping off the screw heads.

The innovation is shown in the drawing using an example and is described as follows. Shown are:

Figure 1 - Partial representation of a slewing ring for a construction not shown further

machine, such as an excavator or the like.

Figure 2 - Top view of a part of the slewing ring including screw lock

ration

Figures 3 and 4 - Cross sections through the screw locking device at different points on the slewing ring as shown in Figure 2

Figures 5 and 6 - alternative screw locking devices to Figure 2 Figures 7 to 9 - cross sections through Figures 5 and 6 Figures 10 to 12 - individual parts of the new screw locking device.

Figure 1 shows a partial view of a slewing ring 1, such as can be used in a hydraulic excavator. A partial area of an undercarriage 2 and a partial area of an uppercarriage 3 are indicated. The slewing ring 1 essentially consists of the following components: an inner race 4, an outer race 5 and several rollers 6, 7, 8 that enable a relative rotational movement between the components 4 and 5. The inner race 4 is connected to the undercarriage part 2 by means of screws 9. The outer race 5 is connected to the uppercarriage part 3 by means of screws 10. This measure enables a relative rotational movement of the uppercarriage part 3 with respect to the undercarriage part 2. Sealing elements 11, 12 are provided to seal the inner race 4 with respect to the outer race 5. In the area of the respective screw heads 13, 14 of the screws 9, 10, screw locks are provided, which are described in more detail in the following figures.

Figure 2 shows a partial view of the slewing ring 1, specifically in plan view. The screw heads 13 can be seen. A die 15 made of sheet metal is placed over the screw heads 13 of two adjacent screws (not shown here). This die is provided with passage areas 16 whose diameter is larger than the corner dimension of the respective screw head 13. Individual sheets 17 are then placed over these dies 15, the inner peripheral surface 18 of which corresponds to the wrench width of the respective screw head 13.

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As described in more detail in the following figures, the dies 15 are connected to the sheets 17 in a form-fitting manner. Since the die 15 and the sheets 17 do not have any form-fitting connection to the screw heads 13 or the components 4 of the slewing ring 1, it may happen, depending on the load, that these connected parts 15, 17 become detached from the screw heads 13 and possibly penetrate into the area of the slewing ring, where they can cause damage. To avoid this, additional securing elements are provided, which in this example according to Figure 2 are designed in the form of snap rings 19 inserted into circumferential grooves (not shown) of the screw heads 13.

Figures 3 and 4 show, on the one hand, a cross section through the screw 10 and, on the other hand, a cross section through the screw 9 according to Figure 1. The screw heads 14 and 13, the dies 15 and the sheets 17, which are positively connected to the dies 15 by welding 20, can be seen. The respective securing elements can also be seen in the form of snap rings 19, which have been inserted into corresponding grooves in the respective screw heads 14 and 13 with the aid of appropriate pliers.

It should be noted that these locking elements 19 are not absolutely necessary in order to be able to implement appropriate screw locking for all connections that can be rotated or pivoted relative to one another. They are only used where rough operating conditions prevail and the risk cannot be ruled out that the components 15, 17 could slip off the screw heads 14 or 13, for example due to vibrations.

Figures 5 and 6 show alternative screw locking systems to Figure 2. The same components are given the same reference numerals. The screw heads 13, 14, the dies 15 and other locking elements in the form of clamping disks 21, which are placed on the respective screw heads 13 and 14, can be seen. These clamping disks 21 are also intended to prevent the dies 15 and the metal sheets 17 (only indicated here) from rattling loose.

Figures 7 to 9 show cross sections through Figures 5 and 6. The screws 10, the screw heads 14 and 13, the sealing elements 11, the dies 15, the sheets 17 and the clamping disks 21, which are placed on the screw heads 14 and 13, can be seen.

Figures 10 to 12 show partial views of the screw lock described so far. The matrices 15 can be seen, which are provided with passage areas 16. The passage areas 16 can be formed on the one hand by holes and on the other hand by slots extending from a circumferential area, whereby the diameters of the passage areas 16 are in any case larger than the corner dimension of the respective screw head.

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Another individual part is the sheet metal 17, whose inner circumferential surface 18 corresponds to the cross-section of the screw head. Finally, the clamping ring 21 can be seen, which is equipped with elastically springy tongues 22, which are supported springily on the screw head (not shown here).

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Claims (9)

Protection claims 1. Screw locking on components that can be rotated or pivoted relative to one another, in particular on slewing rings (1) of construction and work machines, such as excavators, cranes or the like, with at least one matrix (15) connecting several, in particular two screw heads (13, 14) to one another and at least one locking element (17) that can also be provided in the area of the screw heads (13, 14) above the matrix (15), which can be fixed in particular in a form-fitting manner relative to the matrix (15). 2. Screw locking device according to claim 1, characterized in that a separate locking element (17) is provided for each screw head (13, 14). 3. Screw locking device according to claims 1 and 2, characterized in that the respective locking element (17) is connected to the die (15), in particular by welding. 4. Screw locking device according to one or more of claims 1 to 3, characterized in that the locking element (17) contains a through-opening (18), the cross section of which corresponds to the contour of the respective screw head (13, 14). 5. Screw locking device according to one or more of claims 1 to 4, characterized in that the die (15) is provided with passage areas (16). 6. Screw locking device according to one or more of claims 1 to 5, characterized in that the passage areas (16) are designed as substantially cylindrical openings. 7. Screw locking device according to one or more of claims 1 to 6, characterized in that the die (15) is provided with slots extending outwards, i.e. in the direction of a peripheral region, to form the passage areas (16). 8. Screw locking device according to one or more of claims 1 to 7, characterized in that a snap ring (19) arranged within a circumferential groove in the respective screw head (13, 14) is provided above the locking element (17). 9. Screw locking device according to one or more of claims 1 to 7, characterized in that a cover-like spring element, in particular a clamping ring (21), can be plugged onto the screw head (13, 14). 2368A.GBM/da/18.09.96 13:48