DE2356604B2 - HYDRAULIC CLAMPING DEVICE FOR FASTENING A SCREW BOLT WITH A NUT UNDER PRELOAD - Google Patents

Description

The invention relates to a hydraulic clamping device for fastening a screw bolt with a nut under pretension, with a piston-cylinder unit that can be supported on a component to be braced, whose piston can be connected to the nut, and with at least one when the screw bolt is tightened adjustable spacer between nut and component.

The use of hydraulic tensioning devices is known for tensioning tie rods, expansion screws and the like on cylinder heads, reactor covers, etc. After the screw bolt has been pushed through the corresponding bores in the parts to be clamped, a hydraulic piston-cylinder unit is pushed over its threaded end. An additional nut is screwed onto the end of the bolt thread, which belongs to the clamping device and is removed again after the clamping process. The piston-cylinder unit is supported with its cylinder on the component, while the piston presses against the additional nut. In this way, the bolt is extended, while which are compressed to be strained Bauteif _e (DT-AS, 300472 and US PS 25 7 i 265) below, the cylinder of the piston-Zvünder-Einhcit is an annular space which receives the actual Spannmulier which, after the piston-cylinder unit has been pressurized, can easily be rotated on the bolt thread without major frictional losses until it hits the component to be braced. If the piston-cylinder unit is then relieved, the nut, which was not previously loaded, takes it. the tensile stress forces of the screw bolt. Instead of the additional nut with which the piston of the hydraulic tensioning device is supported on the screw hole, the piston itself can also be provided with an internal thread into which the screw bolt thread is screwed.

Furthermore, clamping devices are known (US-PS 32 85 568 and DL-PS 56 737). where a pulling organ does not act directly on the screw bolt to be tightened, but on the nut that sits on the thread of the Screw bolt is screwed on. Below the nut there is an adjustable spacer, for example consists of two rings on top of one another with a helically increasing thickness. The one to use Nut has an external thread. on which a threaded sleeve is screwed, which has a Tie rod is connected to a head piece. The head piece rests on the upper face of the piston and can be pushed up by this, taking along the piston rod and the threaded sleeve. When tensioning the screw, the tie rod is stretched at the same time, so that some of the tensioning forces for a Change in length of the tie rod is consumed. In addition, the jig has because of the required Tie rod a considerable height.

Furthermore, clamping devices are known in which the piston-cylinder unit after it is clamped has been locked in this state so that it can be depressurized without the stress state of the screw bolt is abandoned (DK-PS I 17 396, GB-PS 7 00 425). With these jigs the entire piston-cylinder unit remains on the screw bolt. Overall, it forms a clamping nut with locking element and thus represents a component and not a tool that successively for Clamping multiple bolts would be used.

Finally, hydraulic nuts are known (DT-Gbm 72 08 767, US-PS 30 33 597 and DT-PS 12 00 760), the can be used to push a gear onto a conical shaft part. The hydraulic nuts consist of a piston-cylinder unit, the cylinder of which can be threaded around it to be able to attach to a threaded part of the shaft.

The object of the invention is to provide a clamping device of the type mentioned above that can be used as a tool det is and in which only the nut and a spacing piece remain on the bolt, while dit The piston-cylinder unit can be used for other purposes after the screw bolt has been tensioned, and that Possibility of use does not depend on whether part of the screw bolt protrudes beyond the nut form that it gets by with little installation space above de: the end of the bolt and from a few

Dividing exists as the known jigs.

To solve this problem it is proposed according to the invention that the nut be inside the piston the piston-cylinder unit is housed and releasably attached there.

Such a clamping device had a low overall height, since no tie rods are required. Since the Nut is screwed directly into the piston, it is sufficient if the piston has a height that is approximately corresponds to that of the mother. The clamping force of the piston is applied in the most direct way without intervening transferring elastic parts to the bolt. With the jig you can even such bolts are detected, the threaded part protrudes just so far that the nut on him can be attached. The nut forms the connecting part from the piston-cylinder unit to the Bolt. After tensioning, it remains on the screw bolt while the piston-cylinder unit is removed to be reused elsewhere. The shortening of the effective length of the Screw bolt is not done in the invention in that the nut continues on the threaded part of the Screw bolt is screwed, as in the known devices, but by the fact that below a spacer is placed in position of the nut.

The cylinder of the piston-cylinder unit expediently lies directly on the piston-cylinder unit via a perforated ring Component so that the spacer can effortlessly pass through the perforated ring when the piston-cylinder unit is tensioned can be rotated.

The nut can engage with an external thread in an internal thread of the piston, which is a special one results in low overall height. Alternatively, the internal thread and the external thread of the nut can be axial be offset from one another, the external thread being provided on an end-face attachment. Included a polygonal profile for attaching a wrench can be provided above the internal thread.

The following are some preferred embodiments the invention explained in more detail.

F i g. 1 shows a first embodiment of the invention Clamping device in longitudinal section;

F i g. 2 shows a second embodiment of the tensioning device in longitudinal section;

F i g. 3 and 4 show a spacer in the form of a flat split disc in side view and in FIG Top view;

F i g. 5 and 6 show a spacer in the form of a conical split disk in side view and FIG in plan view; and

F i g. 7 shows a helical perforated disk with the associated nut.

In the embodiment according to FIG. 1, the screw bolt 10 is to be braced through a hole in the Component 11 is inserted through and protrudes with its threaded pin 12 from the bore. Above the end of the screw bolt 10 is pushed a helical perforated disk 13 with a flange ring 14 rests flat on the top 15 of the component 11. the The helical perforated disk 13 is rotatable with respect to the screw bolt 12. Above her mother is 16 screwed onto the screw bolt thread. This is essentially cylindrical Special nut which is provided with both an internal thread 17 and an external thread 18. the Nut 16, which engages with its internal thread 17 in the bolt thread, has on its lower end face a helical part 19 which forms the counterpart to the helix of the perforated disk 13.

The structure of the nut 16 and the perforated disk 13 is shown in FIG. 7 clearly visible. One recognises, that the height of the upper face of the perforated disc (3 in the form of a helix with constant pitch per The degree of circumferential angle increases and at 20 in the form of a steep flank from the highest point to the lowest falls off. The height of the flank: 20 is - if one disregards the possible use of additional washers - about a measure for the largest Clamping stroke. In practice, however, only part of the flank height 20 can be used because the support surface in which the two coils 19 and 21 are axially adjacent to one another, the smaller, and thus the surface pressure The more the perforated disk 13 is rotated relative to the nut 16, the larger it becomes.

The flange 14 of the perforated disk 13 is provided with radial bores 22 into which a round rod is inserted can be in order to be able to rotate the perforated disc. It also has knurling to keep it from To be able to twist your hand.

The piston-cylinder unit 23 consists of a cylinder 24 which encloses a piston 25. The piston 25 has an axial bore 26 with an internal thread which engages with the external thread 18 of the nut stands.

The cylinder 24 and the piston 25 are offset in steps approximately in the middle of their axial extent, namely complementary to each other. This step-shaped shoulder 27 results when the parts 24 and 25 axially be pulled apart, an annular space 28 which expands axially. In the annular space 28 leads over a Bore 29 in the piston 25 through a controllable pressure line 30 into it. They are also used for sealing of the pressure chamber 28 on the sliding surfaces of the parts 24 and 25 seals present.

On the opposite side of the bore 29 is a similar bore 30 'which is in the Pressure chamber 28 leads into it and is closed with a vent screw 31.

The cylinder 24 is supported on the upper surface 15 of the component 11, but openings 32 are provided in the support through which the perforated ring 13 is accessible so that it can be rotated from the outside even when the piston-cylinder unit is tensioned.
To operate the device, the helical perforated disk 13 is first pushed onto the threaded part of the screw bolt 12. Then the nut 16 is screwed on in such a way that the spirals 19 and 21 lie close to one another. Finally, the piston-cylinder unit 23 with the internal thread of the piston 25 is screwed onto the nut.

If pressurized fluid is pumped into the pressure chamber 28, then the piston 25 is raised and takes with the mother 16. The nut 16 in turn pulls the screw bolt 12 in length, whereby between the two coils 19 and 21 a gap is created. The perforated disk 13 is now rotated until the resulting The difference in length is balanced and the turns are as close as possible to one another. The perforated disk is rotated through the bores 32 by means of a suitable round rod or the like .. After the subsequent relief of the piston-cylinder unit, the nut 16 and the support Perforated washer 13 the tensioning

25 whether t> U4

strengthen.

The embodiment of Figs. 2 differs from that of FIG. 1 only through the formation of the nut 16 'of the piston 25'. The Mutier 16 ' also engages here with its internal thread 17 'in the bolt thread, but it is on its upper end face provided with an axial extension 35 on which the external thread 18 'is located. Internal thread 17 'and External threads 18 'are thus offset from one another in the axial direction.

The internal thread into which the external thread 18 is located is located in the upper, narrower part 36 of the piston the nut 16 'engages. The nut 16 'can on its outside over the thread 17' with a polygonal profile 37 be provided for attaching a wrench.

The F i g. 3 and 4 show a flat split disc, which can be used in place of the perforated disk 13 as a spacer between the nut and the component. at There is of course no need to use such land holders also the helix 19 on the lower face of the nut. The two halves of the split Disc 38 are connected to one another by pins 39 or the like. The thickness of the slice is to be expected Pin elongation and component pressure are coordinated, or several such divided disks are cinandcrgeset / t.

The outer edge 40 of the disk 38 is beveled. This edge break serves to secure it against being pulled out

After the piston-cylinder unit 21 has been removed as shown in FIG. I can namely be screwed onto the external thread Ii of the nut 16 a (not shown) thread protection sleeve, which the nut thread

ίο protects and protrudes down to the edge break 40.

The assembly of the split disk 38 takes place because the two halves of the disk after the chip the piston-cylinder line through the breakthrough openings 32 of the Siüizleils through around the Bolzci be grouped.

The I "i g. 5 and b / own a split washer 41 with a conical contact surface 42 for the nut. Hicrdurcl it is possible to adjust the span width determined by the thickness of the washer additionally (at least slightly) by changing the position of the washer half With this disk, too, of course, locating pins 39 can be provided.

For this purpose 3 sheets of drawings

Claims (9)

Patent claims: 1. Hydraulic clamping device for fastening a screw bolt with a nut under pretension, with a piston-cylinder unit that can be supported on a component to be braced and the piston of which can be connected to the nut, and with at least one adjustable distance between the nut and component when the screw bolt is tensioned _{! 0} piece, characterized in that the nut (16, 35) is housed in the interior of the piston (25, 25 ') of the piston-cylinder unit (23) and is detachably fastened there. 2. Clamping device according to claim 1, characterized in that the cylinder (24) of the piston-cylinder unit rests directly on the component (11) via a perforated ring (22). 3. Clamping device according to claim 1, characterized in that an internal thread (17) and a The external threads (18) on the nut (16) lie one above the other. 4. Clamping device according to claim 1, characterized in that an internal thread (17 ') and a External threads (18 ') on the nut (16') are axially offset from one another, the external thread on an end shoulder (35) is provided. 5. Clamping device according to claim 4, characterized in that over the internal thread (17 ') a polygonal profile (37) is provided for attaching a wrench. 6. Clamping device according to one of claims 1 to 5, characterized in that the nut (16, 16 ') has a helical extension (19) on one end face, which is the counterpart to one below arranged perforated disc (13) with a helically increasing thickness. 7. Clamping device according to one of claims 1 to 6, characterized in that the spacer is a split washer (38, 41), the bearing surface (41) of which is conical for the nut. 8. Clamping device according to claim 7, characterized in that the upper outer edge (40) of the split disc is beveled (broken edge). 9. Clamping device according to claim 7 or 8, characterized in that a threaded protection sleeve is intended to be screwed on over the nut that surrounds the split disc laterally.