SU1328683A1 - Apparatus for weighing continuous loads - Google Patents

Abstract

The invention relates to a weight measuring technique and allows an increase in the accuracy of mass measurement while increasing reliability and reducing the cost of a weighing device. The weighed heat-generating elements 2 are placed on the load-receiving platform 1. The proportional weighted mass forces transmitted by the support prisms 3 and 4 through the cargo rack 5 and the link 19 to the tight-fitting 23 T-shaped levers 6 and 20 cause their angular displacement . A mass power converter 15, including an inductive displacement sensor 11, a processing unit 12, a moving coil 13 and a permanent magnet 14, returns the T-arms 6 and 20 to their original position. In the lower part of the load stand 5, a string 7 is installed through a pillow 9 connected to the body 10 of the weighing device. Stage 23 can be made as a rigid bending link. 1 hp f-ly, 1 ill. a "(L EiiSiSiSgiiiiSiSi8S8SS SXSRSSSiSJR8 TR O 1Q oooYahyahhu uvmots 05 00 with

Description

 one

The invention relates to instrumentation, in particular to weighing equipment, and can be used for weighing long loads, mainly heat gels, (TELs) of nuclear reactors.

A device for weighing long weights, preferably heat generating elements of nuclear reactors, is known, comprising a cargo receiving platform mounted on two quadrules of a parallelogram lever mechanism, each of which is connected to a power transducer; digital converters with the inputs of an adder, the outputs of which are connected to the inputs of a display board (Germany No. 2622586, Cl. G 01 G .21 / 24, 1978).

However, this device has insufficient accuracy due to the use of a part of the measuring range of the power mass transducers for balancing the tare weight of the load-receiving platform and the four-link parallelogram of large-scale mechanisms.

The aim of the invention is to improve the accuracy of mass measurement while increasing reliability and reducing the cost of a weighing device.

The drawing shows a device for weighing long weights.

The device contains a cargo-receiving platform 1 with the TVEP 2 lying on it. The platform is mounted on supporting prisms 3 and 4. The cushion of the supporting prism 3 is connected to the cargo rack 5, with which in its middle part one of the horizontal arms is connected with a T-shaped lever 6, A string 7 is installed in the lower part of the cargo stand 5, the T-arm 6 is supported on the pad 8, and the other end of the string 7 is connected via the pad 9 to the body 10 of the weighing device. On the other arm of the T-shaped arm 6, an inductive displacement sensor 11, electrically coupled to the processing unit 12, and a movable coil 13, which cooperates with a permanent magnet 14, are strengthened. The inductive displacement sensor 11, the processing block 12, a movable coil 13 and a permanent magnet 14 form

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power converter 15 mass. On the other horizontal arm of the T-shaped arm 6, a tarn 16 is also fixed, the output signal from the mass converter 15 is fed to the analog-to-digital converter 17, and its output to the display board 18, the end of the platform 1 equipped with

Q prism 4, through the earring 19 interacts with one of the horizontal arms of the second T-shaped lever 20, the cushion 21 of the prism of which is mounted on the housing 10 weighing

15 devices. On the other horizontal shoulder, the T-shaped lever. 20 is located. Tare gear bells 22. T-weights 16 and 22 fixed on T-shaped levers 6 and 20 are designed to balance the mass of load-receiving platform 1, load rack 5, earrings 19, straightening 23 and part of the mass of string 7, the vertical shoulders of both T-shaped Levers 6 and 20 are rigidly fixed to 23.

The device works as follows.

The weighted heat-generating elements 30 are superimposed on load receiving platform 1. Forces, proportional to the applied mass, are transmitted by means of supporting prisms 3 and 4 through load strut 5 and link 19 to interconnected rigid fitting 23 T-shaped levers 6 and 20, causing their angular displacement. Rotation of the T-shaped lever 6 and the associated movement sensor 11 of the slider 4 causes a proportional change in the output signal of this sensor. A change in the signal at the output of the processing unit 12 causes a proportional change at its output (—the current, which, entering the moving coil 13, returns the T-shaped lever. 6 to its initial equilibrium position. The second T-shaped lever 20 through a rigid tie 23 also returns to its original 35

50

initial position.

The measuring current at the output of the processing unit 12, directly proportional to the mass of the weighed fuel rods, is converted into an analog-to-digital converter 17 into a discrete form and fed in the form of units of mass to the display board 18.

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Claims (2)

The invention of the horizontal arms of the first T-OB1. A device for weighing different levers is associated with forceful long loads, mainly with mass converters, and the second with heat generating elements for pulsating load receiving reactors containing load-forms through the load rack, the second platform, installed finally with a string - a four-link parallelogram ryan with the body, and a second T-shaped chazhny mechanism, connected to the lesser lever, is associated with a second reference plate with one power transducer. rmy posredst- ers mass connected through ana CMV earrings, wherein the vertical logo-digital converter, while both shoulders of the T-shaped levers soe--binding score which distinguishes-dineny together zhkoy Article, p. in order to increase the 2. The device according to claim 1 of a tl and - ness, a four-link parallelogram - 15 is due to the fact that in it the lever mechanism is made in the form of a stitch made in the form of a rigid on de T-shaped levers, one-bend link.