DE1011174B - Clamping device for pipe testing presses - Google Patents

Description

Clamping device for pipe testing presses For strength testing of rolled or drawn pipes, hydraulic test presses are used.

So far, the pipes have been jammed from both pipe ends, whereby the pipes are stressed for kinking. Also it is known the pipes to hold frictionally by pressing jaws, the pressing pressure from the holding members must be included.

The invention relates to a clamping device for pipe testing presses For testing flange pipes or socket pipes that have a thread at both ends and which are easy to connect with a flange piece. requirement for the idea of the invention is that at least one pipe end has a flange or a flange piece can be attached to one end. The facility has a sealing receptacle for the pipe to be tested, as it is known per se.

There are known devices for connecting two pipelines, in which the device is fixed to one pipeline and the lock of the two lines by locking elements that can be inserted behind the flange of a line takes place, which consists of pivotally mounted on the device claw levers. One of the pipes can be used to apply a test pressure to the other pipe to direct. The known facility is primarily intended to serve as a relocated Check pipeline network for leaks. However, when testing larger pipes the trunnion bearings of the claw lever quickly knock out, as the stressed on train Claw levers would have to absorb the entire axial pressure during the testing process. In addition a frontal seal is provided between the two pipes to be connected, the effect with increasing pressure and increasing elongation of the claw lever must subside. This device is therefore for the clamping of heavy pipes not suitable.

The invention uses the positive locking one with one Flanged pipe end on a test device and provides in particular that the pivot ends of the claw lever are provided with angular heads with axial play both in an outer annular groove in the fixed body of the testing device as well as in an inner annular groove of a common, axially displaceable control ring intervene, the stop edges of the annular grooves when the control ring is displaced work together in pairs. Due to the boltless swivel bearing of the swivel lever Wear in the pivot pin, pin or the like is completely avoided. With axial Pull on the claw lever there are only flat surfaces for support that move when pivoting away lift the claw levers apart and do not require any lubrication. The only ones, Joints of the testing device that are subject to wear are thus maintenance-free.

Since the claw levers as locking organs themselves do not have a clamping stroke perform a frontal seal between the pipe to be tested and the Test device only possible if the claw levers in their entirety are additionally would be driven axially. Such an additional device as in the known one There is a locking device for two tubes, according to the further invention by selecting a known cylindrical receptacle for the one to be sealed Tube provided, the cylinder of which corresponds to the inside diameter of the flange end or piece and on which the test specimen end can be moved while sealing. These radial seal allows the pipe to be tested without affecting the Sealing when introducing the test pressure to move axially until the swiveled in Claw levers act as locks.

Because the control ring for the claw lever is hydraulic or is pneumatically operated, you can quickly connect and disconnect the pipes to be tested.

The drawing shows two exemplary embodiments of the subject matter of the invention shown schematically, namely Fig. 1 shows a device with a to be tested Socket pipe, the clear width of which corresponds to the outside diameter of the receptacle, Fig. 2 the same jig for testing a socket pipe of lesser lights Width and Fig. 3 a section along the line III-III in Fig. 2.

The testing device has a body 1, which at one end closes a cylindrical receptacle 2 with Sealing ring 3 is formed. A flange piece 4 can be pushed onto this receptacle against the pressure of a spring 5 which is connected to the socket pipe 7 to be tested via a socket 6.

The socket pipe, such as a drill pipe, is screwed on at the end by a Hood 8 closed.

The pipe to be tested is fastened to the receiving head 2 according to the invention by claw lever 9, the ring-shaped around the receptacle 2 radially are arranged pivotable in and out and their pivot ends 10 are on the body 1 of the test device. In the upper half of Fig. 1 and in Fig. 2 is the locking position of the claw lever 9 is shown. If the line 11 Pressurized water is introduced, so the test tube 7 strives from the receiving head 2 to migrate, however, is positively locked by the claws 9 a located behind the flange 4 held. A special feature of the subject of the invention is the swivel drive for the claw lever 9.

These are not provided with pivot bearings, but have at the pivot ends angular heads 10 with axial play both in an outer one Annular groove 12 in the fixed body 1 of the testing device as well as in an inner one Engage annular groove 13 of a common axially displaceable control ring 14, wherein the stop edges of the ring grooves work together in pairs when the control ring is moved.

In the lower half of Fig. 1 a claw lever 9 is splayed Location shown. The control ring 14 is shifted to the left, and through the stop edges 15 and 16, a torque in the sense of spreading is exerted on the lever 9. In this situation, a tested pipe is released, or a new pipe can be opened the recording 2 can be postponed.

If the control ring 14 is shifted to the right, the stop edges effect 17 and 18 a locking of the claws 9 a behind the flange 4 of a pipe.

The control ring 14 is expediently hydraulic via servomotors 19 or pneumatically operated.

The circuit of the servomotors can also according to the further invention automatically by stopping when the flange end 4 is pushed onto the receptacle 2 to be triggered. The control forces for the claw levers can be very low, since they only need to move the claw levers. Due to the form-fitting Locking, the pipes are held securely even at the highest test pressures.

The clamping device according to Fig. 2 corresponds to that according to Fig. 1 completely with regard to the actual restraint; it is only indicated that one with connection of a reducing flange piece 4 a also a MuKenrohr 7 a can connect that a different from the diameter of the recording head 2 light Has width. The head pieces 10 of the claw levers 9 are useful to form circular ring sections formed and complement each other in their ring-shaped arrangement to form a closed one Ring, as shown in Fig. 3.

PATENT CLAIMS: 1. Clamping device for pipe testing presses for testing of flanged pipes or socket pipes, which by means of threads on the pipe ends can be connected to a flange piece, with a sealing receptacle on the test device for the pipe to be tested and with locking devices that can be inserted behind the flange, which consist of claw levers pivotably arranged on the testing device, thereby characterized in that the pivoting ends of the I (tepid lever (9) with angular heads (10) are provided with axial play both in an outer annular groove (12) in the fixed I (body (1) of the test device as well as in an inner annular groove (13) of a common. engage axially displaceable control ring (14), the stop edges of the Ring grooves work together in pairs when the control ring is shifted.

Claims (1)

2. Clamping device according to claim 1, characterized in that the receptacle (2) for the pipe to be sealed in a known manner from one of the clear Diameter of the flange end or -piece consists of the corresponding cylinder. 3. Clamping device according to claims 1 and 2, characterized in that that the control ring (14) is actuated hydraulically or pneumatically. 4. Clamping device according to claim 3, characterized in that the actuation of the control ring (14) when sliding the flange end (4j onto the Recording (2) is triggered automatically by a stop. o. clamping device according to claims 1 to 4, characterized in that the flange end or piece (4) can be pushed open against spring pressure. Considered publications: German Patent Specifications No. 41,287, 546,864, 809,857, 875,578; U.S. Patents No. 2,007,521, 2,241,526, 2,445,876; 2,640,492; German patent application B 18455 IX / 42k.