CS213055B1 - Scale of the linear inductive measuring device - Google Patents

Abstract

A linear inductive measuring device scale which is formed as a planar meander shaped double strip (3) mounted on insulating material, the double strip formed as two conducting branches (3) connected at one end by a conducting portion (7), the branches having mirror symmetry, the meander spacing (t) and width of each branch being constant, the branches being axially parallel to each other and to the longitudinal scale axis. The branch meanders may be axially offset one to another by an amount less than half of the meander spacing (t). The branch meanders may also be angled with respect to the axis or may be offset and angled. <IMAGE>

Description

⁽⁵⁴⁾ Linear Scale indizetivního CD ^ ⁰ Equipment incorporates a sealing window

The present invention relates to a linear inductive scraping device. Solves the design of the scaling that changes the periodic error of the abrasion device at any length ·

It is an object of the present invention to provide a meander surface winding of the scale. in the shape of two branches, at one end of the scale conductively connected and juxtaposed parallel to the longitudinal axis of the scale, the spacing and meander width of the two branches being equal • The two winding branches are positioned symmetrically with respect to the reinforcing scale less than half the mendiri wave pitch. The position of the main ones. the wires of both branches with respect to the longitudinal axis of the scale may be perpendicular or inclined with a similar condition ·

Especially in large NC machine tools and machining centers for chip machining including electroerosive machining

213 055

The invention relates to a measure of a linear inductive metering device.

The known inductive metering devices, for which the trade name inductosyn is also used, consist of two members, one of which embodies the length measure and called the scale and the other, substantially sliced, is called the rider. The AC signal is transmitted by inducing a meander-shaped flat winding that is in planes opposite to each other. The scale has one circuit and the slider has two circuits. Either the rider or the scale is drunk. The device works as a transformer whose output signal changes amplitude and phase, or just phase according to the method depending on the mutual displacement of both

Members against each other. The metering is carried out by a projection that is perpendicular to the diameter of the conductors and maintains a constant mmzer between the two members. The principle of scale construction is known, the flat winding of which consists of the main conductors perpendicular to the measuring movement with an exact pitch of, for example, 1. mm and the couplings that form a meander with the main conductors · Both the main conductors and the couplings take the form of a transmitted signal that repeats with a meander pitch that is twice the pitch of the main conductors. In order to be able to reward any selected part of the meandiri pitch, the signal corresponding to the pitch must be intalibrated. An error occurs in interpolation, the main reason being that the interpolated signal is not simply related to the mutual relocation of the two terms. This error is systematic and is called a periodic error, unlike a sum error, expressing inaccuracy over the full length of the string. The coherence of the signal and the mutual reflection of the two elements is determined by the power supply and evaluation of the signal and for any power supply and evaluation it is influenced by the design of the scale meander. It is known to depend on the ratio of conductor width to pitch, the ratio of the length of the main conductor to the length of the meander, where and at what distance the conductor is laid from the meander.

the mating end of the meander with the outlet. Since the meander-shaped conductor has, in addition to ohmic resistance, a capacitance relative to the substrate to which it is applied, and since the scale is usually longer in length than the term, it also depends on where the scale length is measured. The out-of-jaw scales occupied by the rider are an asymmetric proportional resistive and capacitive load. At large earthing disturbances, disturbing alternating voltages from foreign magnetic fields are induced to scale and the effects of different earth potentials are applied. These facts aggravate the periodic error so much that a solution is sought to limit it. Two solutions are known which can reduce the periodic error by changing the winding design on a scale. The S-tarsi uses on both sides of the meander one shielding conductor with a sense of measuring movement. The signal induced into the meander returns from its end with the aforementioned waters. This is where the meander lies within the spruce to send out the effect of an alternating interfering field. Imagine a slider as a primary part of a transformer or as a generator, then with its movement along the scale, the distribution of the winding resistances of the remaining parts before and after the generator is varied. As the distribution of resistances changes, the distribution of capacitances with respect to the ground also changes, and the variations in inductance can be neglected in the multi-winding shape of the winding used. The electronic device, connected to the terminals of the town, has a symmetrical input with a grounded center, then up to <^ 1 ^ 4 ^ 2 ^ asymmetric scale to balance this input and change the amplitude and periodic errors to the length of the town, scale can be an error several times <^^ 8 ^ than at the beginning. The choice of an optimum winding geomeery resulting in an acceptable periodic error is only applicable in a small part of the scale. Another known solution is used for construction

213 155 _n scale of two parallel conductors biflearly calm on both sides SQrshlon * mdrfl · This thought meander is such that the resulting year of the main conductors is again broken by the giant conductors are connected at the end of the scale · This saying has an advantage over 9 symmetrical. Petit, however, arises in double meander couplings · Inferior couplings are longer than internal and are flowing through streams of obnoxious senses. The main conductors are different lengths to one side of the meander and therefore the required sine wave of the Inductive coupling cannot be achieved. Mowing is extremely demanding on the rider's mounting accuracy, and the flow effect to reduce periodic error through this scale design is problematic. Dependence of the periodic error * · scale length is eliminated, but the periodic error is greater than the length of the scale.

These disadvantages are overcome by the scale according to the invention having a meandering flat winding Insulated on a strip-shaped support and formed by two meander-shaped branches arranged side by side parallel to the longitudinal axis of the scale o at one end of the scale. The relative position of the two strands in the direction of the longitudinal axis of the scale corresponds to the alignment of the opposing main conductors of the two strands with a tolerance of offset relative to each other by less than the pitch of adjacent main conductors. The opposing main conductors are perpendicular to the longitudinal scale of the scale or are combined by the value given by the largest dimension of the perpendicular projections of the contours of the opposing main conductors in the direction of the longitudinal axis of the scale, less than the pitch of adjacent main conductors. In doing so, the sum of the offset between the two branches in the direction of the longitudinal axis of the scale and the largest dimension of the perpendicular projections of the contours of the opposing main conductors as they slope towards the longitudinal axis of the scale shall be less than the pitch of adjacent main conductors.

A novel effect of the invention is that it keeps an acceptable periodic error constant up to the longest lengths of scales used today, i.e., up to several meters. An acceptable periodic error is due to the fact that the solution utilizes a known simple meander whose optimal proportions are known and allow the use of proven compensated rider designs. The constant periodic error value is achieved by having the scale having two winding branches so connected to one circuit that their passive parts remain symmetrical at any position of the slider having a connection with both windings between the beginning and end of the scale. to eliminate the effects of rainy magnetic fields affecting both winding branches at the same time · Advantages remain when the rider or scale is powered · In the first case, the scale output signal to the preamplifier is symmetrical to the preamplifier inputs. both inputs equally proportional to the slider displacement. In the second case, the tern is similarly ·

The effect of the invention is retained even if the meanders of the two branches are offset from each other by a value of £, so that the main conductors of the two branches do not connect to each other. meander height and pitch. The offset allows working and up to gray conductors, which is sometimes technologically advantageous and brings some material savings ·

The effect of the invention is retained even if the main conductors of the two branches are not perpendicular to the longitudinal axis of the scale and the position of the rider's path does not change. Angles and Blinds of the main conductors of both branches

213 035 can be selected differently in such a way that the higher harmonic components during the periodic error with the winding eo are most fully compliant. The smallest limiting value of the angles with the oblique results from the fact that the perpendicular projection of the contours of the main conductors is mmi than the pitch of the main conductors. It will be appreciated that the effect of the slant angle on the effective conductor width will be the same when the angle is a certain value. greater than or equal to 90 °. SoSDetermination and misalignment of loo conductors with constant effect. Use at the same time when the sum of the two effects does not override the value of «0X110811 of the mains conductor.

. The economic advantage of the invention is that it increases the accuracy of the long co-ordinates of the inductosyne encoders. Precisely, the increase consists in a periodic increase in periodic error and a limitation of its variability and scale length.

1 shows a cross-sectional view of the scale according to the invention, FIG. 3 shows a basic embodiment of the scale according to the invention, FIG. 3 shows an alternative way of depicting the mutual movement of the two branches; both branches - iimrt £.

In cross-section, any strip-shaped support 1 is marked in FIG. 1 on which a winding is mounted in a known manner on the insulation layer 2. consisting of two. branch J, made in a known manner, e.g. Talkto created winding yeah ncsiteOem length measures and creates a scale. Both branches J are formed by meanders consisting of main conductors 6, the pitches t of which are embodied in the measure and the meander is formed by connectors 2. Both branches J are conductively connected at one end - in the manner of a connector -. - so that the two branches are in series J strength and outlets 8 »· 2 -i alternative embodiment, the two branches mutually offset in the longitudinal direction of the scale value в mměí than yo mite t'sousedních main guide jo I chose ^a fourth possible náoorněno seěltaeetí Hlavnice ^h naklontaím conductors ⁴ at an angle ^H ° and ^β, růonýc ^h from 90 °. I maximize the tilt value. is given by the largest dimension of the perpendicular projections of the contours of the opposing main conductors ⁴ in the direction of the longitudinal axis of the lipstick, always less than the pitch m of the adjacent main conductors 4. It is also possible to make the scale non-angled by using the possibility of offset and simultaneous inclination of the iodine branch J, the sum of the magnitude of the mutual offset of the two branches J in the longitudinal direction. the axis of the gauge and the largest dimension of the perpendicular projections of the contours of the opposing main conductors ⁴ - in the case of their inclination to the longitudinal axis of the gauge, the knife must have a pitch of adjacent main conductors 4.

The use of these devices is particularly suitable for large machine tools such as machining centers, horizontal boring machines, milling machines and the like. even in ee environments with sinusoidal interfering fields, eg. in oloUrooalsive curvature.

Claims (5)

SUBJECT OF THE INVENTION 1. A scaling device of a nanouktinnhoo rfaer machine with a single-sided, insulated-on nool-shaped strip, characterized in that the winding is formed by two meander-shaped branches (3) arranged parallel to one another along the longitudinal axis of the scale and the conductors (4) of the main conductors (4) of the two branches (3) being identical. 213 055 The scale according to claim 1, characterized in that the relative position of the two branches (3) in the direction of the longitudinal axis of the scale corresponds to the continuity of the opposite main conductors (4) with a tolerance of mutual offset by a value (s) less than the pitch (t) (4) · Scale according to Claims 1 and 2, characterized in that the main conductors (4) of the two branches (3) are perpendicular to the longitudinal axis of the scale. 4. A scale according to claim 1, characterized in that the main conductors (4) of the two branches (3) are inclined with respect to the scale base by angles (ο < _ζ β) different from 90 ° and whose maximum inclination is given by the largest dimension of perpendicular projections. the contours of the opposed main conductors (4) in the direction of the longitudinal axis of the scale, less than the pitch (t) of the adjacent main conductors (4). Scale according to Claims 1, 2 and 4, characterized in that the sum of the relative spacing of the branches (3) in the direction of the longitudinal axis of the scale and the largest dimension of the perpendicular projections of the contours of the opposite main conductors (4) when lowered to the longitudinal axis of the scale is less than the pitch (t) adjacent main conductors (4) ·