RU2527129C1 - Meter of axial forces in tendons - Google Patents

Abstract

FIELD: instrumentation.

SUBSTANCE: proposed meter is composed of top and bottom force transmitting boards with central bore and force meter with electromagnetic system arranged between said boards. Said force meter is composed of several independent string dynamometers which have case and sensitive element composed by plate with tensioned string.

EFFECT: higher accuracy, possibility to calibrate the meter at existing reference equipment, higher reliability, decreased weight and overall dimensions.

6 cl, 4 dwg

Description

The technical solution relates to measuring equipment, in particular, to measuring axial forces in the cable-beam reinforcement of the VVER NPP containment shells, and can be used to measure the loading forces of various structures and determine their mass.

A measuring device is known for measuring the tension of rope bundles. The device consists of two annular plates, one of which has a dielectric applied, and a piezoresistive material on the dielectric. By the method of thick-film technology, six active and two passive (unloaded) piezoresistors are formed on the plate. The same method is used to form current-carrying circuits and contact pads connecting piezoresistors to a Whitstone bridge or a potentiometric chain (Patent GB 2326719 IPC G01L 1/20, G01L 1/22, G01L 23/18, G01L 5/24. Force sensitive devices / Atkinson JK, Cranny AW, Sion RP - No. 19980013171; claimed 19.06.98).

The disadvantage of an analogue is:

- low accuracy, because piezoresistors measure local voltage, and the resultant force exerted on the device is not stabilized;

- a sufficiently high drift of the initial resistances of the piezoresistors;

- high value of temperature coefficients of resistance of piezoresistors (0.0004-0, 0009) 1 / ° C.

At high measured forces, the meter cannot be calibrated, because There are currently no silo model cars with a measurement limit of more than 500 tf. The measurement error of silo-building construction machines with a large limit of the measured force is (5-7%).

A known method of operational control of the tension of cable-beam reinforcement in prestressed structures and structures (RF Patent 2315272 IPC G01L 5/10, G01N 29/024. Method of operational control of the tension of cable-beam reinforcement in prestressed structures and structures (Khilkov B.V., Khilkov K. V. - No. 2006119188; application form 01.06.2006; publ. 02.01.2008) The essence of the proposed method consists in installing several metal spacers between the spacers and the base plate having acoustic decouples between the spacers and the base plate. opening of the upper plate inserted ultrasonic emitters connected to meter timing signals.

However, using the proposed method, it is impossible to create a measuring device that would allow testing during operation of the rope bundle (the ultrasonic emitter is stored separately and can only be installed during maintenance work). The authors' reasoning that the spacers have high mechanical reliability is untenable, since they cannot quickly fix the breakage of individual ropes in the bundle, on the basis of which it would be possible to decide on the safe operation of the power plant. It should be borne in mind that the force measurement vectors in spacers are not stabilized. Therefore, at the contact points of the upper plate and the spacers, there may be large values of contact stresses and their relaxation in time.

The closest technical solution to the proposed one is a meter of axial forces in a strained rope, containing upper and lower power transmitting plates with a central hole for the rope, a force sensor located between them, having upper and lower power-receiving pads and electrical interconnected sensitive elements and power-leveling surfaces formed on the contact areas of the lining plate (Prospectus from TELEMAC. Dynamic sensor, CV-8 strain gage. 1999).

The CV-8 force transducer is a heat-treated steel cylinder, equipped with sensitive measuring instruments that are installed between the cable end coupling and the base plate. Local compression deformations caused in the cylinder by the tensile force in the rope are measured by eight equally spaced sensitive ones with vibrating wire elements located on the periphery of the cylinder.

The average value of the readings of the stresses (mechanical) taken from eight sensitive elements is the average value of the strain on the rope. The ring-shaped mild steel linings at the ends of the sensor are deformed at a specific location, while maintaining a relatively uniform voltage distribution between the cable head and the base plate.

However, this meter has an error in measuring the tension of the rope due to local deformations of power-leveling surfaces formed at the contact areas of plates and pads. Local deformations do not reflect the complete deformation of the force-leveling surface. The range of measurement of the tensile strength of armored ropes can be from hundreds to thousands of tons and above. Model silos in such ranges have a single design and are significantly more expensive than model silos in tens of tons. Therefore, calibration of force measuring devices for large measuring ranges, as a rule, is carried out either for an incomplete measuring range (which leads to an increase in the error), or force-setting devices having measuring instruments with a large error, for example, through pressure measurement in a hydraulic system.

It is also impossible to verify the metrological characteristics of the sensitive elements of the force sensor and, if necessary, replace them after installation on the rope, since the installation or removal of the sensor is possible only during installation or dismantling of the rope, which reduces the reliability of control of the reinforcement rope. It should be borne in mind that the force-sensitive linings of the sensor are made of mild steel and used only once. The magnitude of the effort is recalculated according to the readings of the jack gauge by the “lift-of” method.

The objectives of the proposed technical solution are:

- improving the accuracy of measuring axial forces of rope-beam reinforcement;

- providing the ability to calibrate the meter on existing model equipment;

- reduction of overall mass characteristics;

- increase the reliability of the meter.

The tasks are solved in that the axial force meter in the cable-beam reinforcement comprises lower and upper power-transmitting plates with a central hole, between which a force measuring device with an electromagnetic system is located. As a force-measuring device, several autonomous string dynamometers are used, having a body and a sensing element in the form of a plate with a stretched string. The string of each of the dynamometers is perpendicular to the vector of applied force. Each dynamometer has two spherical surfaces, one of which is convex and formed on a ball cushion, and the other is concave and made in a plate in contact with the ball cushion. A plate with a tensioned string and a concave surface rests on a narrow ledge of the housing and is rigidly connected to the housing along the external contour. A circuit chamber for the electromagnetic system and side openings with a sealed connector are located in the meter housing.

Between the set of essential features of the claimed object and the achieved technical result there is a causal relationship, namely:

- improving accuracy is achieved by the fact that the proposed scheme allows you to measure the entire value of the axial force as the sum of the forces measured by each of the dynamometers located between the two load-bearing rings. It should be borne in mind that the measurement range of each dynamometer is less than the force applied to the meter of the axial forces of rope tension n times, where n is the number of dynamometers. In this case, the sum of the forces applied to the dynamometers is equal to the force applied to the meter of the axial forces of tension of the rope. With this technical solution, each dynamometer can be calibrated on an exemplary force-setting machine, which has a significantly smaller range of reference forces, which will allow the use of exemplary force measuring instruments. The errors of individual dynamometers add up, and the measurement limit of the axial force meter increases by the same amount.

Therefore, the relative error of the meter of axial tension forces in the rope-beam reinforcement will be no more than the arithmetic mean of the relative errors of the calibrated dynamometers on a model silos-setting machine;

- a decrease in overall mass characteristics is achieved by the fact that the string is located on the plate perpendicular to the force vector applied to the dynamometer. The plate rests on the protrusion of the housing and is fixed by welding. With this arrangement of the applied force relative to the string, the dimensions of the sensing element are significantly reduced. With a parallel arrangement of the string and the applied force vector, it is necessary to increase the length of the sensing element after the string is fixed to ensure uniform deformation in the area of string attachment.

In addition, the dynamometer error decreases due to the small value of the hysteresis of the calibration characteristic (the friction in the plate support is minimal) and, accordingly, the overload range can be increased without increasing the error.

Tests of dynamometers on a silo-picking machine showed that they withstand an overload of 1.5 times without loss of accuracy;

- the reliability of the proposed design will increase for the following reasons:

1. all dynamometers have a large stock of metrological reliability (1.5);

2. dynamometers are located symmetrically between the plates and work in parallel;

3. for additional alignment of the load distribution between dynamometers according to the known technical solution, one of the rings is made more plastic;

4. it is possible to verify the metrological characteristics of the sensitive elements of the sensor (dynamometer) if necessary to replace them.

The essence of the invention is illustrated by figures.

Figure 1 presents a General view of the meter axial forces;

Figure 2 presents the sensitive element of the dynamometer;

Figure 3 presents a General view of the dynamometer;

Figure 4 shows the installation of the sensor in operating conditions.

The axial force meter in the cable-beam reinforcement contains the upper (1) and lower (2) rings, made with stepped holes located along the average diameter of the rings symmetrically to the center of the circles of the rings. Technological screws (3) fix the dynamometers (4) between the upper and lower rings. Each of the dynamometers consists of a ball cushion (5), made in the form of a cylinder with two parallel identical flats on a cylindrical surface or without flats. A spherical surface is formed on one of the end surfaces of the pillow. The ball cushion is in contact with the concave spherical surface of the plate (6), the vertical projection of the plate coincides with the vertical projection of the ball cushion. This design allows to reduce the error when the deviation of the force vector relative to the surface of the rings.

On the opposite end surface of the plate, a groove (7) is made to accommodate the string (8). The string is tensioned and secured with two straps (9) and four screws (10) from the two ends of the groove. An electromagnetic system (11) is placed above the string, consisting of an inductor (12), two washers (13), one on each side of the groove for the string, two bushings (14), a strap (15) with three holes, two studs (16) threaded rod of magnetic material (17), one nut (18) and two locknuts (19).

The vertical projection of the housing (20) corresponds to the vertical projection of the ball cushion and plate. The housing has a narrow protrusion (21) around the perimeter of the end surface formed by the groove (22). The width of the protrusion is determined by the value of the permissible contact stresses of the materials of the housing and plate. The housing has a groove (23) to accommodate the string and its fastening straps. The circuit chamber (24) is used to accommodate the electromagnetic system. The circuit chamber for accommodating the electromagnetic coil is connected by a stepped side hole (25) with the outer surface of the housing for installing a sealed connector (26). The plate body is connected by a weld (27). The plate and ball cushion are fixed by the side 28.

The axial force meter in the cable-beam reinforcement works as follows.

The meter (1, 2, 4) is installed on the base plate (29), which is mounted in the protective shell (30) of the reactor installation. Reinforcing beams consisting of ropes are stretched in the channels of the containment shell (31). More precisely, the ring (32), the anchor washer (33) of attaching the ropes in the bundle, on which the conical split collets (34) are worn, are sequentially put on the meter. The ends of the ropes are threaded into a jack, the piston of which abuts against the anchor washer, and the rope is pulled to the required value. After tensioning the beam, the collet is choked and the jack is removed. A protective cover (35) is put on the free ends of the ropes and filled with sealant (36). The sealant is also filled into the channels of the reactor containment. The force F _ISM loads the dynamometers of the meter forces F _i . The distribution of the forces F _i between the dynamometers may be uneven, but everywhere such that the vectors of these forces are stabilized and directed parallel to the force of the entire beam. The measured force is equal to the sum of the forces measured by each dynamometer.

Where n is the number of dynamometers installed in the axial force meter of the rope-beam reinforcement.

The technical solution allows to increase the accuracy of measuring the axial forces of a stretched rope, to calibrate individual dynamometers with more accurate means of calibration, to reduce the overall mass characteristics of the meter and increase its reliability.

Claims (5)

1. The axial force meter in the cable-beam reinforcement, containing the upper and lower power transmitting plates with a central hole, between which is a power measuring device with an electromagnetic system, characterized in that several self-contained string dynamometers having a body and a sensing element are used as a power measuring device in the form of a plate with a stretched string. 2. The axial force meter in the cable-beam reinforcement according to claim 1, characterized in that each of the dynamometers has two spherical surfaces, one of which is convex and formed on a ball cushion, and the other is concave and made in a plate in contact with the ball cushion. 3. The axial force meter in the rope-beam reinforcement according to claim 1 or 2, characterized in that the string of each of the dynamometers is located in a plane perpendicular to the applied force vector. 4. The axial force meter in the cable-beam reinforcement according to claim 1, characterized in that the plate with a taut string and a concave surface rests on a narrow protrusion of the housing and is rigidly connected to the housing along the outer contour. 5. The axial force meter in the cable-beam reinforcement according to claim 1, characterized in that the circuit chamber for the electromagnetic system and side holes with a sealed connector are placed in the housing.

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