DE2540458A1 - Hollow body or container testing - using hydraulic pulses superimposed on pre:stressed medium in test piece - Google Patents

Abstract

Hollow body or container testing uses hydraulic pulses superimposed on pre-stressed medium in test piece. Optimum threshold values are obtained without any electronic control equipment. The test piece is filled with a pressure medium and oscillated through a pulsating stream of pressure medium of variable frequency and amplitude. A motor drives an oil pump which feeds the oil via. a volume regulator for amplitude regulation, to a pulse generator. The latter is driven hydraulically or electrically with a fixed or an adjustable number of revolutions and has four connections. The oil is fed to the pulsating hydro-cylinder.

Description

Veranren and device for testing hollow bodies with impulse hydraulics for internal pressure swell systems.

The present invention relates to a prior method and a new one Device for testing hollow bodies, i.e. storage of containers and tubes hydraulic impulses, which without electronic control in their frequency and amplitude infinitely variable and superimposed on a pre-stressed medium in the test specimen.

A test is part of the production of hollow bodies in general of the finished product to the preps of the individual work steps.

Essentially, the test is about the acquisition of Materialfenler, resp. of material fatigue or manufacturing springs, which can occur e.g. during the deformation or processing of the material.

The preliminaries are of different kinds and divisions sensibly according to the later intended use of the product.

It is used, for example, for Nehöltern that are deformed or welded and are exposed to very low pressures, just a simple one Leak test carried out as a certain static pressure for safety of the product is completely sufficient.

The test regulations change widely if, for example, pressure vessels, Tanks, bottles, cylinders or pipes comply with the provisions of the Technical Monitoring Association or are subject to certain acceptance conditions of the customer. These regulations are Also versatile, depending on the purpose of the test item. You can subdivide them in static and dynamic test methods.

It is used, for example, with bottles or oil storage tanks that consist of a Ronling can be produced by deformation, normally only a static pressure test performed.

For tubes made of steel or plastic and the are exposed to various pressure and temperature stresses, are not only from the TÖV, but predominantly from the customer special acceptance conditions for safety the prefabricated parts put in later use. Because of this, the products Tested for dynamic behavior very locally You operate the pressure test, which for the most part comply with the safety regulations, the hydraulics as Pressure medium, whereby oil, oil emulsion and water are the media with the lowest compressibility factor in contrast to air.

In the last few years the prdf methods are constantly improved and has been streamlined, as the testing and acceptance conditions are increasing have been tightened.

In the case of hollow bodies, this is mainly used for the production of Bottles and tubes too. For example, welded tubes are often used as the starting point X-ray examination of the weld seam is insufficient for certain pipe qualities. The customer also wishes to be tested for material fatigue by means of endurance tests.

Based on these requirements, test equipment was developed to investigate the dynamic behavior of test objects and so-called internal pressure swell systems built.

The wish of the workshop laboratory of the manufacturers of hollow bodies goes there, the pre-tensioned hydraulic fluid in the test item in different bridging areas to pulsate i.e. variable vibrations by changing the frequency and amplitude within wide limits in order to be able to test the material fatigue obtain.

So far, test methods have been used based on electro-hydraulic Ways to cause the test pressure to swell and swell.

Fig. 1 illustrates the structure of a hydraulic scheme, with a adjustable axial piston pump is electronically reversed and its changing Transmits impulses to the test system. The electronic part for this is shown in Fig. 2, instead of adjustable axial piston pumps, the test procedures Pulsations also generated by reversing directional spool valves. with this structure Until then, electronics are also used.

The development of internal pressure swell systems for material testing for endurance tests without electronics and without reversible pumps, respectively.

Directional valve was the idea behind the patent application.

The invention with regard to the method for testing hollow bodies is based on the application of the new impulse hydraulics, which makes it possible without Electronics to change the frequency and amplitude of a pressure medium within wide limits and to overlay the pre-stressed medium of a test object.

It is to be regarded as particularly expedient if the oscillating movement is generated by pulses introduced at a time interval.

This makes it possible to shape the vibrations in such a way that allow optimal threshold values to be achieved.

In particular, this is the case when pulses begin at the beginning of the pulse a strong increase in force and then until the end of the impulse a steady or even increase have uniformly changing force.

The essence of the arrangement according to the invention is best in the structure an internal pressure swell system, in which a l'lit is preloaded with a pressure medium Test specimen in connection with a double-sided cylinder, the Is acted upon alternately by a pressure medium via a control device and is variable Transmits impulses to the medium of the test object.

The control unit is connected to a central pressure oil station.

Fig. 3 shows the structure of an internal pressure swell system with impulse hydraulics emerged.

The electric motor l drives an oil pump z, which inr oil via the Volume controller 4 for amplitude control to the pulse generator (control unit) 5 promotes. The latter is hydraulic or electric with a fixed or adjustable speed driven for frequency control 6 and has four line connections. The lines B and A lead the pressure oil to the pulsating hydraulic cylinder 7, which alternates is applied. In the control unit, the connection P - A is short-circuited and the backflow of the cylinder 7 flows from B - T via filter 8 into the Tank back. The pressure relief valve 3 determines the system pressure and is used for Force control.

The frictional connection between the pulsating working cylinder 7 and the test item is carried out according to Fig. 3 via a lantern in the axis of the one The side of the piston rod of the working cylinder protrudes extended into the uen test piece, There are a number of other means of constructing a pulsation of the working piston transferred in cylinder 7 to the pressing device in the test item, e.g. membrane.

The device for generating pressure pulses (control unit) can be a rotating or swinging spool with which at least against one side of the piston in the working cylinder in alternating sequence once a pressure line, the other time the return line is connected.

The rotating or swinging control slide has very simple options to change the pulse shape and the pulse frequency.

A possibility for the specific design of pulse shapes and also to change them is that the slots and openings (Len pressure medium passage are equipped with curved lines in the control spool. By Slits and holes deviating from the rectangular shape are different Generate pulse shapes.

The frequency can easily be adjusted with a vibrating control slide vary in that a squat wheel is provided as the drive, its drive motor can be set to different speeds.

With a rotating control spool piston, the frequency is more easily released change by having a drive motor that can be adjusted to different speeds as the drive is provided.

The control spool of a rotary valve can be rotatable as also be designed to be displaceable. If the control slide is rotating, this is the drive speed of the control piston is decisive for the pressure frequencies generated. An additional Shifting the rotating control spool causes a change in the flow rates and with N = const. a change in pressures.

The oscillation frequency is used for an oscillating control spool piston the piston of a certain frequency of hydraulic impulses. Additionally läsbt sicn the oscillating control spool piston even during his Twist the stroke. This also gives variable flow rates.

The formation of the rotary valve driven by a drive motor in simple execution without longitudinal displacement and its mode of operation gent from Fig. 4 emerges.

The illustration shows schematically the development of the circumference of the Rotary valve in connection with the working piston in both end positions and this is the division of the current. With hydraulic actuation of the rotary valve the oil enters through an inlet opening in the housing and a connection to a circumferential ring groove of the rotary valve. Right and left of this ring groove are offset by 180 ° with one or two axially arranged gel pockets on the circumference milled.

In addition, there are one or two corresponding ones belonging to the oil pockets Oil bores arranged offset on the circumference, which run inward and the pressure medium lead with an axially directed bore to the oil outlet ring groove.

Radial bores are also provided in the rotary valve housing, the one turn of the rotary valve with the oil pockets and holes in the valve come to cover.

As a result, when the pressure medium enters the annular groove, the cut is made a - b the oil hole A short-circuited with the piston side A of the working cylinder. The oil displaced on B flows simultaneously via bore B to the annular oil outlet groove.

After half a turn of the rotary valve, the oil hole is opened C short-circuited to the pressure medium supply. A and B remain closed. The pressure medium now acts on the solenoid side C in the opposite manner. Of the Working piston moves into the other end position below pushes the oil over Hole D.

By choosing this rotary valve, the pressure medium flow becomes intermittent divided into two streams of oil. The frequency changes with the speed. The change in flow rate varies the pressure.

The structural design of internal pressure welding systems is based on according to the shape and dimensions of the test object.

The single structure for small and medium-sized power units According to Fig. 3, the test item is the combination of control unit 5 and the working cylinder 7 together with the pressure oil supply station in one unit.

Between the exiting piston rod of the working cylinder and the animal A mechanical or hydraulic force-fit connection is to be established on the test item, to transmit the pulsation to the pressure medium of the test specimen.

For larger test objects, as in Fig. 3, it appears appropriate to to separate the working cylinder from the control unit and rigidly connect it to the test item connect to.

A special structure of an internal pressure swell system stent, if a 20 - 30 m long hollow body, e.g. Tubes in a long-term test for strength and Material fatigue should be checked.

Such a system is shown in Fig. O. The pressure oil station for control unit and working cylinders form a unit.

The PrZflinO, which is closed at the ends, receives in its axis a smaller pipe with a bushing on one side of the test object. This honr which in short intervals inside the pretling with membrane bodies is equipped, is filled with a hydraulic fluid and received like the test specimen variable impulses superimposed by the working cylinder.

Another variation in testing long pipes results from a pressure body (pig) running through the interior.

In summary, the invention has the following advantages over Previous test methods for internal pressure swell systems are based on: - Impulse tests with internal pressure swell systems for the investigation of material fatigue in a long-term test without electronics only with hydraulically generated, variable frequency and amplitude Pulsations that are superimposed on the pretensioned medium in the test object.

- Internal pressure swell systems, which are used as a test bench in a pressure oil station, Control unit and pulsation cylinder combine and impulses mechanically or hydraulically transferred to a test object.

- the use of a rotary valve using impulse hydraulics with division of the pressure medium flow and ideal adaptation to achieve optimal Thresholds.

Claims (1)

Protection claims 1. Procedure for testing hollow bodies with the aid of impulse hydraulics in the case of internal pressure swell systems, characterized in that a pressure medium filled test object an oscillating movement by a control unit outgoing, pulsating pressure medium flow, variable superimposed in frequency and amplitude which means that without electronic control units, optimal threshold values are widely available Limits are reached. 2. The method according to claim 1, characterized in that the Frequency of the oscillating movement constantly between an upper and a lower Limit changed. 3. The method according to claim 1, characterized in that the vibrating movement is generated in the form of pulses introduced at a time interval. 4.) The method according to claim 1, characterized in that the pulses a strong increase in force at the beginning of the impulse and then a steady increase until the end of the impulse or have uniformly changing force. 5.) Device according to claim 1-4, characterized in that the Device is a test bench of an internal pressure swell system, consisting of a Pressure oil station a control unit and a Arbeitszilinder in one unit or built up, which mechanically or hydraulically the pulsation in frequency and amplitude transmits variably to the test subject. 6.) Device according to claim 5, characterized in that the device the combination of a control unit with to generate the oscillation movement intermittently exiting pressure pulses and a working piston acted upon by them consists in a cylinder. 7e) Device according to claim U dadurcn that uie device (Control unit) is a rotating or oscillating control slide, with which at least because of one side of the piston in the cylinder, a pressure line 1 in alternating sequence the other time the return line is connected. 8.) Device according to claim 6, characterized in that at the tandem arrangement of control unit and working cylinder that transmitted the torque The drive shaft of the control unit is designed as a rotary valve and at the same time the working cylinder is arranged in extension on this shaft. 9.) Device according to claim 6, characterized in that the Slots and openings for the pressure medium flow in the control slide of the control unit are equipped with curved edges. 10.) Device according to claim 6, characterized in that as The drive for the rotating control spool piston is adjustable to various speeds Drive motor provided ist0 11.) Device according to claim 6, characterized in that that the control spool of the control unit is both rotatable and displaceable is. 12.) Device according to Ansprucn b, characterized in that for Transmission of the pulsation from the vibration generator to the test object in an oil column a high in Vibration is set and its threshold values via the membrane to the medium of the test specimen. 13.) Device according to claim 6, characterized in that aass for Transmission of the pulsation from the vibration generator to the test object and a hose a membrane body in the interior of the hollow body serves as a vibration carrier, which its Pulsations superimposed on the pretensioned medium of the test object.