SU1432408A1 - Electric measuring instrument and method of fastening its moving part - Google Patents

Abstract

The invention relates to a measurement technique and can be used in the mass production of panel-mounted electrical measuring instruments with fastening of the movable part on stretching. The purpose of the invention is to improve the manufacturability of the design of the device, increasing the productivity of the process of adjusting the mounting of the moving part is achieved by automating the exhibition process by increasing

Description

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14

nor grow. For crepe-pins of the movable part of the device, the outer ends of the stretch 3 are fastened to the impregnation springs 65, the wedge 9 is inserted into the groove of the bracket 7 and the vibrating arm is set, c into position; in which the axis of the wedge is vertical and coincides with the direction of vibration. Excite oscillations of the device with the gradual introduction of the Kli

at the inter, tsuu bracket 7 and the 6p depreciation spring, then the acceleration is stopped and the electric meter is held until the fixed wedge cover 9 is solidified. Ustreystzo contains a frame 1 of the movable part, a magnetic system, cylindrical boxes 4, a clip 5, 2 sec. f-lts 2 silt

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The invention relates to a measuring technique and can be used in the mass production of panel-mounted electrical measuring instruments with the fastening of the movable part at distances,,

The aim of the invention is to improve the manufacturability of the design, increase the productivity of the process of adjusting the fastening of the sub-hv-part.

Fig 1 schematically kzobrazhen electric measuring device; in fig. 2 - section AA on fkg,

The electrical device contains a frame 1 of the podshkna part, placed in the working gap of the magnetic system 2 and suspended elastically with the help of extensions 3 fixed on the frame 1 by the inner ends using cylindrical boxes - ;, on flat cantilever 5 cage springs 6 - on the cage 5 parallel to each of the amortization springs 6 in the vicinity of its frame 1 facing up to which the brackets 7 are fixed console-mounted (in FIG. 1 only the upper fastening assembly of the upper cushion 3 is shown, the fastening assembly of the lower stretching 3 is completely The ridge is identical), near the point of attachment of the damping spring 6 to the holder 5 there is a perpendicular to the longitudinal axis of the bracket 7, a groove 8, Hanpuj-sep, of rectangular cross section, in which the clearance introduced between the bracket 7 and the damping spring 6 is placed wedge 9 in contact with the shock absorber spring b and plate 7 whose surfaces are covered with a fixing material, for example,

glue. In this case, the mass m and the length 1 of the wedge 9 are selected using the derived design ratios depending on the specified tension force of the stretching B of the stiffness characteristics of the damping spring 6 and orientation relative to it of the stretch 3, as well as the location of the displacement 9 and its angle (L - . ---, 3 ------;

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1 2 (l,.) Ll 9Е1ыГ

de set mustache: -shy natures stretch 3; oi - wedge angle 9; g is the acceleration of the free pader and | 1.5 L - distance from place

fastening the shock-absorbing spring b in the holder 5 to the wedge 9 and tension 3;

I and Е are the moment of inertia of the section and the modulus of elasticity of the first kind of damping spring 6.

The device works as follows

When current is supplied to the measuring winding of frame 1, it is deflected by an angle proportional to the current in the winding, under the action of rotating and countermeasure moments. Against one moment, this moment is created, for example, by means of moment springs,

The method of fastening the movable part of an electrical measuring instrument is the following.

The external ends of the stretch 3 are fixed (soldered) to the damping springs 6 when they are undeformed, i.e. horizontally, in position (it doesn’t matter if the spring 6 is completely undeformed, the stress is slightly strained, or vice versa, the stretch 3 sags slightly). Without a voltage, a wedge 9 is inserted into a groove 8, which is installed in the bracket 7, in both attachment points 3. Next, the device is installed on the shaker platform in a position where the longitudinal axis of the wedge is vertical and coincides with the direction of vibrations, with the wedge 9 pointing down, after that, oscillations of the device are excited, which result in the gradual introduction of a wedge between the plate 7 and the damping spring 6 and, accordingly, the deformation of the spring 6, gradually increase the amplitude of the vibration acceleration to g / oi, when wedge 9 is disrupted, moreover, by choosing the nominal value of the maximum amplitude of vibration acceleration A depending on the wedge angle 9 (A g / oi) and the wedge mass 9 depending on the set tension of the stretching tension 3 It takes place at a given tension force of the stretch 3 and a corresponding pressure on the wedge 9, after which the device is held at rest for a period of time that is not bypassed-south to solidify the wedge fixing material 9.

The proposed design and method of its adjustment make it possible to fully automate the process of exhibiting the stretching tension force, which, when assembling devices with fastening of the movable part on stretching, is the most laborious. The entire wedge insertion process does not exceed 5 seconds, not counting the time taken by the instrument to harden the wedge fixing material. The outer ends of the stretch are pre-soldered, prior to the tension, t, e. deformation of shock-absorbing springs. Therefore, the set value of the tension does not further change - the tension is already a parameter, specified not indirectly, but directly. It does not matter from what initial position undeformed depreciation

0

0

five

s

0

five

springs began the process of introducing a wedge. In any case, the process of moving the wedge will end with the same force acting on the wedge, i, e, with the same tension of the stretch equal to the specified tension

Thus, the device becomes more technologically advanced, its accuracy rises.

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Claims (1)

1. An electrical measuring instrument comprising a yoke with two flat cantilever damping springs on which the outer ends of the fasteners are fixed, the inner ends of which are fixed to the frame of the movable part, characterized in that, in order to improve processability, it is provided with two brackets with a transverse groove and two wedges with a fixing coating placed between the corresponding bracket and a shock-absorbing spring in transverse slots of the brackets fixed with the holder and arranged parallel to each other damping springs between the damping spring and the frame, and the mass and length of the wedges are selected from the ratio  ;: lilV ztgg 2 (j. m 1 s where T is the specified tension growth; uL - wedge angle; g is the acceleration of free fall; 1., L are the distances from the place of attachment of the depreciation spring in the cage to the wedge and extension, respectively; I, Е - the moment of inertia of the section and the modulus of elasticity of the 1st type of shock-absorbing spring; m and 1 are the mass and length of the wedge, respectively. 2, A method of fastening the movable part of an electrical measuring device, including the deformation of the damping springs by a predetermined force and fixing the ends of the same on them, characterized in that, in order to increase the manufacturer to carry, it first fixes the outer ends of the straps on the damping springs , and the subsequent deformation of the damping springs by a given force is produced by acting on the electric measuring device by a periodic vertical vibration acceleration in the direction of 32А086 The research institutes of a wedge, whose amplitude is monotonously increased to the nominal value, after which the J-acceleration effect is stopped and the electrical measuring instrument is held until the fixed coating hardens and the nominal amplitude amplitude is determined from the Q ratio A g / o: - where A - the nominal value of the amplitude of the vibration acceleration.