The invention relates to a distance measuring device, in particular a magnetostrictive distance measuring device.
The basic principle is that a distance measuring element extends in longitudinal direction of the device along the distance to be measured, and a signal generating position generator is moveable in longitudinal direction relative to it.
In a magnetostrictive distance measuring device, the basic principle of such a device is refined in so far, as a wave conductor made from a electrically conductive and also magnetizable material extends in measuring direction, the longitudinal direction of the device, in particular, in a slightly taunt state.
A magnet is connected with the component, whose position in longitudinal direction is to be measured, or monitored, and is being moved by this component in longitudinal direction of the wave conductor without contacting, but at a sufficiently small distance.
A electrical impulse induced into the wave conductor causes a mechanical wave as an interaction with the magnet, which propagates along the wave conductor from the position of the magnet, and which is detected with respect to its runtime by the processing electronics, which are mostly located at the end of the wave conductor, from which the longitudinal position of the magnet, and thus of the component to be monitored, is known relative to the wave conductor.
Since such distance measuring devices often have to be used in machinery, also in production machinery, they have to comply with numerous requirements, like e.g. protection of the measuring device against mechanical damages and contamination, in particular against the penetration of moisture into the processing electronics, maintaining the original tension of the wave conductor, shielding electromagnetic radiation of the processing electronics towards the outside and the inside, ease of assembly and maintenance of the measuring device.
On the one hand, it is already known in this respect to receive the wave conductor in a supporting, but not overly dampening enclosure, and to use it as a wave conductor unit in this form.
On the other hand, it is already known to locate the wave conductor or the said wave conductor unit in a protected manner in the interior of a circumferentially closed hollow tubular profile, which can be manufactured as an extruded profile in a cost effective manner.
Thus the tubular profiles have to comply with different requirements depending on their intended use:
For this purpose, the outer contour, as well as the inner contour, of the profile had a defined shape. The inner contour was designed for receiving the wave conductor units, as well as the single or plural circuit boards, carrying the processing electronics. The contour designs, in particular of the inner contour, had to allow for different technical outfitting. For high sealing requirements, where the flat placement of a cover with a flat gasket onto the front face of the profile was not sufficient, the front end areas of the profile had to be milled into a contour without a shoulder, into which a cover with an accordingly shaped protrusion, whose outer circumference had an annual groove for receiving an O-ring, could be inserted, what allowed for much improved sealing.
Without a shoulder in this context means that the respective interior contour has no concave or convex protrusions or indentations, whose curvature radius is so small that a sealing O-ring moved over it, is permanently damaged and loses its sealing capability.
This milling, however, was time consuming and difficult, because of the 5 meter long profiles, in whose end areas these millings had to be performed.
Therefore, it is the object of the invention to provide a distance measuring device, which is simple and more cost effective to manufacture, while still fulfilling strict requirements with respect to leak tightness.
This object is accomplished through the features of the claims 1, 44 and 51. Advantageous embodiments can be derived from the dependant claims.
Through an inner contour of the profile without a shoulder over its entire length, an insert, required for the mechanical fixation of the components to be housed in the interior of the profile, is disposed at least torque proof in the inner contour of the metal profile without a shoulder, which can e.g. also be made from plastic, and wherein the inner contour of the insert can have grooves, in particular, undercut grooves, inner edges, outer edges, and shoulders.
Without a shoulder means in this context, that the inner contour of the profile can be sealed by a circumferential seal, acting radially from the inside to the outside against this inner contour, e.g. an O-ring inserted into an outer circumferential groove of a respective protrusion of an end cover reaching into the interior of the profile. This means that the inner contour of the profile can certainly have inflections and curves, concave and convex, which however cannot have a curvature radius in the cross section plane of the profile that is so small that the sealing abutment of an O-ring at the profile and at the inward protruding component, which carries the O-ring, is prevented, or through the strong curvature, its premature fatigue and damaging and, thereby non tightness, has to be a concern.
For manufacturing the distance measuring device, this insert, having the designed interior contour, is provided shorter than the surrounding metal profile, and inserted in front or together with the wave conductor unit and/or the printed circuit boards of the processing control unit, axially and in the right rotation position, into the interior of the profile, or in a profile, made from two clam shells, inserted in between, and fixated in rotation position and, preferably also in longitudinal direction at this position, either due to an oversize, a radially outward directed inner tension or simply through gluing. The axial positioning is thereby performed, so that in the axial end areas end cavities remain in the interior profile without shoulder, which are not occupied by the insert, and which have such an axial length, so that the respectively designed protrusions of the end covers can be inserted, in whose outer circumference the one or several sealing O-rings are disposed in an outer circumferential groove in the protrusion, and which are sized in their cross section, so that the O-ring then contacts the interior circumference of the inner profile without a shoulder in a sealing manner.
For this purpose, the end covers are preferably mounted to the profile so they are detachable, e.g. through threaded connections, reaching through the cover into the profile, which can e.g. be bolted into the corner grooves of the outer contour of the profile with self threading bolts.
This way the profile is not damaged for the connection between cover and profile, so that the profile does not have to be exchanged subsequently, also when opening the distance measuring device.
The insert, which is normally made from plastic, has an outer contour, which fits into the inner contour of the profile in a form locking manner.
For this purpose, the outer contour of the insert can be adapted to the inner contour of the profile, in particular, over more than 180°, or it can also only have a largest diameter, which corresponds to the largest diameter of the inner contour of the profile, which is, however, spaced from the inner contour of the profile in the direction of the smaller diameter.
The latter also allows providing a universal insert with an elongated cross section, which can be inserted into various inner contours of different profiles, e.g. a profile approximately square on the outside with a circular inner contour, as well as, a profile that is flat on the outside with an elongated inner contour.
Preferably, the cross section of the insert is thus provided elastic, so that it can always adapt in a sufficiently precise manner with its outer circumference to the inner circumference of the profile, in spite of unavoidable manufacturing tolerances.
This is possible with a circumferentially closed cross section of the insert, in which it has e.g. indentations towards the inside, which are elastic, in particular, provided as one or several cavities of the wave conductor.
In particular, two opposing wave conductor cavities, which are open to the outside, have the advantage that the wave conductor unit, inserted into the wave conductor cavities, is elastic in lateral direction, thereby holding the insert through friction locking relative to the interior contour of the profile, when the sum of wave conductor unit and insert is oversized relative to the inner contour of the profile in lateral direction. Preferably, one wave conductor unit each is thus inserted in both wave conductor cavities for reasons of the elastic compression in radial direction, of which only one wave conductor unit has to be a functional wave conductor unit; the other one can only be made from the elastic encasement of a typical wave conductor unit, which is elastic in transversal direction.
For elastic contact at the profile, the insert can also have a circumferentially open profile.
When, for example, only one wave conductor shall be received in the insert, a receiving groove is sufficient, which is provided in the central area of the insert, preferably covering more than 180°, or even a circumferentially closed receiving groove for it, from which radially elastic struts can protrude sideward, like ribs from a sternum, which can also be adapted to the inner contour over more than 180°, without a circumferentially closed profile having to be provided as an insert, which is certainly the most stable variant that can be positioned best, but which also has the highest material requirement.
In a similar manner, the insert can have different cross section designs in different longitudinal sections, which can be manufactured through extrusion in a cost effective manner, instead of a constant overall cross section of the insert, which is constant over the entire longitudinal extension of the profile, besides the end cavity.
Thus, the rib shaped appendices, which cause the radially outward directed clamping in the interior profile without shoulder, can only be provided in larger longitudinal distances. In a similar manner, not only one, but several of them can be provided offset in longitudinal direction, whose distances are sized so that the intrinsic stability, e.g. of the wave conductor unit, is sufficient in between for the function of the entire distance measuring device.
An insertion into the profile is then possible through the single inserts, which are offset from each other in longitudinal direction, are previously mounted on the wave conductor unit at the correct distances in a longitudinally fixated, and preferably, also torque proof manner, and then inserted into the profile together with it.
The inner contour without shoulder preferably is a contour with sections made from partial circles, in particular, an oval contour or a slotted hole contour, ideally a circular contour.
Through the specific design of the outer contour of the profile, so that in an inner contour, partially covering the profile, but by more than 180°, a defined ability for positioning in transversal direction and also a rotatability of the profile is given, in spite of the fixation through common holding bands, clamps, supports, or similar holding devices, a fixation and at least after the coarse fixation, a rotation of the profile around the longitudinal axis can still be performed on the device as fine positioning, which greatly simplifies the assembly process.
In order to know, close to which spot of the circumference of the profile the wave conductor is positioned in the interior, a mark is therefore provided, either on the profile, or on the closing end cover.
In order to have mounting means at the outer circumference, preferably several outer grooves, which are open to the outside, are provided along the outer circumference, particularly distributed along the circumference in a symmetric manner. Preferably, these outer grooves are provided as so-called combination grooves, whose cross section is suited, on the one hand, for threading in the bolts in longitudinal direction, and, on the other hand, for inserting plate shaped elements, thus tension lugs, or the protrusions of the slide to be guided on the outside of the profile in transversal direction.
For this purpose, the combination grooves are preferably provided shaped as vases, having a circular segment shaped cross section in the deeper positioned area of the groove, where the groove also preferably has a flat bottom, and where a neck expands in V-shape, and to the outside from this deeper located area, so that the tightest spot of the combination groove is the transition between the neck and the lower area.
Thus preferably four outer grooves, in particular combination grooves, are provided distributed over the circumference of the profile, and thus preferably, symmetrical to the longitudinal central plane, and additionally also to the perpendicular transversal center plane.
The inner contour of the insert is determined through the requirement that at least a wave conductor cavity and at least a pair of circuit board grooves have to be present there, preferably two of each, in order to allow a redundant design of the distance measuring device, thus with two wave conductor units and two respective associated circuit boards with processing electronics located thereon.
Thus, the wave conductor cavity is an undercut groove, preferably provided with an interior circumference, shaped as a circular arc, whose interior diameter is selected, so that the wave conductor unit, which is normally cylindrical, can be inserted in a longitudinal direction in a form locking manner, and cannot slide out in lateral direction. The wave conductor cavity is thus open to the interior cavity of the profile, like the printed circuit board grooves, which are located opposite to each other as pairs, between which the circuit boards can be inserted with their longitudinal side rims.
The position fixation in longitudinal direction is thus performed on the printed circuit boards through friction locking through one or two elastic, extended threads, which are inserted along the longitudinal edges of the circuit board in the base of the groove, like e.g. rubber or silicon, or a respective hose, which is released at the desired location after longitudinal positioning, and through the subsequent lateral expansion of the elastic hose or elastic thread, the printed circuit board is wedged between the printed circuit board grooves.
The wave conductor unit, on the other hand, has a friction coefficient, which is large enough by itself, relative to the interior circumference of the wave conductor cavity, in order not to move by itself anymore after insertion in longitudinal direction, since it preferably also comprises a slippage inhibiting elastic hose, e.g. from silicon, also at its outer circumference, which can also be stretched for inserting the wave conductor unit.
The circuit board grooves are thus either provided, so that the circuit boards to be inserted respectively in parallel to each other, are located, transversal to the longitudinal center plane, which is defined by the middle of the profile and the middle of the at least one wave conductor cavity, and through the connection line between two wave conductor cavities.
The other possibility is to position the printed circuit board grooves, so that the respective circuit boards, inserted therein are located parallel to the longitudinal central plane, certainly laterally offset relative to the wave conductor cavities.
Preferably also the circuit board grooves are provided as undercut grooves, in particular as combination grooves.
Depending on the primary goal, the profile itself can have a wall thickness as constant as possible on all sides of the circumference, thus with a thickness deviation of ±30% at the most, in particular ±20% at the most, or, to the contrary, accumulate a maximum amount of material, besides the necessary cavities in the interior, thus for housing the printed circuit boards and the components located thereon, and the wave conductor units, so that the wall thickness measured in radial direction at the thickest location amounts to at least 3 times, better 5 times, the wall thickness at the thinnest location.
Preferably, the inner contour has two, in particular opposing, wave conductor cavities and two, better three, pairs of printed circuit board grooves, in particular also for the disposition of printed circuit boards with different widths.
The inner contour is thus symmetrical, preferably to the longitudinal center plane, in particular and/or to the transversal center plane.
On the face side, the profile is closed through end covers, wherein from at least one of the end covers, preferably with a redundant design, possibly even from both end covers, electrical cables are run out, in order to transmit the signals to a processing unit.
The end cover is preferably located on the front face of the profile, and is bolted onto it, with a gasket in between, by bolting it through respectively disposed bolt holes of the end cover a threaded connection into the outer grooves of the profile is performed via customary self cutting screws, e.g. sheet metal screws, or self tapping bolts, whereby the gasket leads around without interruption, e.g. within the bolt pattern. An O-ring seal can be provided in an outer circumferential groove of the adapted protrusion of the cover, which reaches into the profile, and then seals relative to the inner circumferential contour of the profile, while a cover plate, which is connected with the protrusion, in particular in one piece, abuts to the front face of the profile in a blunt manner.
The passage of the cable through the cover plate is performed through a respective cable bore, into which a cable grommet is threaded, or through a cable grommet, which is formed integrally with the end cover. Instead of a run-out cable, a connector unit can also be located directly in the cable grommet, which, in turn, seals with an O-ring relative to the interior circumference of the grommet, or which is also glued, so that a connection of the device via a connector unit becomes possible.
The cover plate and/or the profile are preferably comprised of electrically conductive material, in particular metal, in particular zinc. Due to the at least segment wise round outer circumference of the profile, or even a protective tube surrounding the profile, the mounting can be performed at the surroundings, either of the profile, or the tube through customary mounting means, like pipe clamps, supports, tension lugs, or similar, wherein the tension lugs have an eccentric bore for putting in the threading, in order to already be able to provide an engagement into the outer groove, through rotating the tension lug, when a loose bolted connection has been established.
Elements triggering the signal, which are moveable in longitudinal direction along the device, mostly a slide with a magnet, can either be guided at a surrounding component, and have no contact with the profile or the protective tube, surrounding the profile, or can be guided along the profile or protective tube in a form locking manner.
It is a possibility to have the slide engage into the respective outer grooves of the profile in a form locking manner, thus guiding it along the outer circumference.
The outer contour of the profile is preferably polygonal, in particular rectangular.
The outer surfaces of the profile are particularly flat, in particular multi segmented outer surfaces, wherein, as it is already known, only the outer areas of these outer surfaces form partial outer surfaces, which are parallel to each other, and wherein the remaining central part is recessed relative to it. When placed against an opposite planar surface, thus only the rim areas come in contact, so that in a non flat opposite surface a safe, defined contact is provided.
To each outer surface two offset, thus a pair of outer grooves, in particular identical outer grooves, is assigned, wherein these are particular corner grooves, located in the corner areas of the outer profile.
Additionally, in one of the outer surfaces, in particular exactly in its center, a center groove is located, so that the outer groove is symmetrical to the longitudinal center plane of the profile, extending through the middle groove.
The corner grooves and/or the middle grooves are preferably undercut, wherein the corner grooves have flanks, which extend in parallel to one of the outer surfaces.
Since the corner grooves are preferably provided, symmetrical to the bisecting line of the corner, in which it is disposed, each corner groove then has two such flanks, extending in parallel respectively to one of the adjacent outer surfaces, through which the corner grooves have a particularly triangular or trapezoid basic shape. Thereby, the free ending protrusions, formed by the flanks parallel to the outer surface, which receive the corner groove between them, are spaced apart so far, so that between the free end of such protrusion, measured in the extension of the protrusion, relative to the opposite protrusion of the same corner groove, an offset remains.
Similar to the corner grooves, preferably also the center grooves are provided symmetrical to its center plane, in this case the center plane of the entire profile. The center groove is preferably provided with two indentations pointing away from each other at an oblique angle, forming a floor in between, and thus forming an approximately roof shaped cross section of the center groove. The floor of the middle groove between the two deeper reaching indentations constitutes a part or the entirety of the depressed central area of the respective outer surface, in which the center groove is located.
Along the outer contour of the profile, a slide can be moved, which is held in an interlocking manner, by the outer contour of the profile in all directions transversal to the longitudinal direction.
Typically, the slide is then run along one of the outer surfaces, and for this purpose, engages in a form locking manner, either into the middle groove, or into the corner grooves disposed on both sides of the desired outer surface.
In both cases, it is normally desired, that the respective outer surface, along which the slide is being moved, is mostly covered by the slide, in order to avoid contamination of this outer surface. For this purpose, the slide has an approximately roof shaped cross section, which covers the respective outer surface, and abuts to it at a surface, that is as large as possible, or has only a very small offset relative to it.
If the slide is guided in the middle groove, it engages into the indentations of the center groove with respective protrusions, but it has an offset from their center floor for reducing friction. In particular, the protrusions of the slide reaching into the indentations, have a rounded or round cross section, in order to minimize the contact surfaces between protrusions and indentations.
Through providing combination grooves in the outer contour of the cross section of the protective profile different objectives are achieved simultaneously.
Through being able to insert plate shaped elements into the combination grooves in transversal direction, the protective profile can be mounted at any location of its longitudinal extension through tension lugs, which engage into the combination grooves with their plate shaped sections, to a receiving component, possibly also with different spacing of the bolt pattern relative to the protective profile.
Since self cutting screws can be screwed into these combination grooves in longitudinal direction from the front face, the same combination grooves can be used e.g. for screwing down e.g. blunt end covers onto the face sides of the protective profile, whereby a very simple and cost efficient method for sealing the interior cavity of the protective profile, e.g. with a flat gasket placed in between, can be accomplished, in particular, when one of the end covers has a cable grommet for connecting the processing electronics in the interior of the protective profile. In particular in this case, no element protrudes beyond the outer contour of the protective profile in a lateral manner.
Interior Contour of the Insert:
The contour of the circumferentially enclosed insert is determined through at least one wave conductor cavity, and at least one pair of circuit board grooves, having to be present there, preferably two of each, in order to allow a redundant configuration of the distance measuring device, thus with two wave conductor units, and two respective associated circuit boards with processing electronics located thereon.
The wave conductor cavity is thus a groove with an internal circumference provided as a circular arc, in particular an undercut groove, whose interior diameter is selected, so that the typically cylindrical wave conductor unit can be inserted in longitudinal direction in a form locking manner, and cannot slide out in lateral direction.
The wave conductor cavity can be provided on the outside of the profile of the insert, whereby a cavity appropriate for the wave conductor is created after inserting the insert into the profile.
The wave conductor cavity can also be provided in the interior of the insert, and is then typically a circumferentially closed wave conductor cavity, or at least an open, but undercut wave conductor cavity, in order to hold the wave conductor unit in the lateral direction in a form locked manner.
Also, the printed circuit board grooves, provided in the inner contour of the insert, are provided open towards the interior.
The position fixation in longitudinal direction thus is performed through friction locking, at the circuit boards through one or two elastic strings, e.g. made from rubber or silicon, inserted along the longitudinal edges of the circuit board in the base of the groove, or a respective hose, which is released after longitudinal positioning at the desired location, wedging the circuit board between the circuit board grooves through the subsequent lateral expansion of the elastic hose or the elastic string.
The wave conductor unit on the other hand thus has a sufficiently large friction coefficient relative to the interior circumference of the wave conductor cavity, in order not to move freely anymore, after insertion in longitudinal direction, since it preferably also has a slippage inhibiting and elastic hose, e.g. made from silicon at its outer circumference, which can also be stretched for inserting the wave conductor unit.
The circuit board grooves are thus either configured, so that the circuit boards to be placed therein are either located parallel to each other, transversal to the longitudinal central plane, which is defined by the center of the profile, and the center of the at least one wave conductor cavity, or through the connection line between two wave conductor cavities.
The other possibility is to dispose the printed circuit board grooves, so that the respective circuit boards, inserted therein, are located parallel to the longitudinal center plane, of course laterally offset to the wave conductor cavities.
Preferably also the printed circuit board grooves are provided as undercut grooves, in particular as combination grooves.
Depending on the primary goal, the profile can have a wall thickness that is as constant as possible on all sides of the circumference, thus with a variation of the thickness of maximally ±30%, in particular maximally ±20%, or contrary to that, in spite of the necessary cavities in the interior, thus for housing the circuit board, and the components located thereon, and the wave conductor units, accumulate as much material as possible, so that the wall thickness measured in radial direction at the thickest location is at least 3 times, better 5 times, the thickness at the thinnest location.
Preferably the interior contour of the insert has two, in particular opposing, wave conductor cavities, and 2, better 3 pairs of circuit board grooves, in particular also for the disposition of circuit boards with different widths.
The interior contour is thus symmetrical, preferably to the longitudinal central plane, in particular and/or to the transversal center plane.
The interior contour of the insert, in particular of the tubular profile mentioned subsequently, is preferably depicted twice mirror symmetrical, thus symmetrical to the middle, on the one hand, relative to the longitudinal center plane of the outer contour, and, on the other hand, to a transversal plane, located at a right angle relative to it.
Additionally, the cross section of the conductor groove is substantially larger than the cross section of the circuit board grooves, since the smallest free cross section of the printed circuit board grooves corresponds to the thickness of the circuit board materials, in particular of the material of the circuit board holders, which will be described later. These grooves of the interior contour serve for inserting the components, which belong to the processing electronics of the distance measuring device. A wave conductor unit can be inserted in one or even both conductor grooves. Into the conductor grooves printed circuit boards, which carry components of the processing unit, or printed circuit board holder, to which this one or plural printed circuit boards of the processing electronics are mounted, can be inserted. In addition, these printed circuit board grooves can be used for bolting components, in particular covers, to the front face, due to their shape, through self tapping bolts being threadable into the open face ends of these grooves.
A sliding in longitudinal direction of such components in the circuit board grooves is prevented by slip inhibiting material, in particular by an O-ring inserted around the inserted printed circuit boards, or printed circuit board holders, which is received into the cross section of the printed circuit board grooves.
Thus it is possible, through the selection of the length of the tubular profile, slightly longer than the intended length of the wave conductor, to house the processing electronics, also completely within the circumferentially closed tubular profile.
The contour of the insert only has a single first main cavity for receiving the wave conductor in a first preferred embodiment, and a second main cavity for receiving the processing electronics, in particular provided as one or several circuit boards, wherein the first and the second main cavity are connected via a bottleneck, or completely separate from each other, which gives additional stability to the protective profile.
The outer contour of the profile is preferably at least three times as wide, as it is high, wherein the combination grooves are preferably arranged in pairs, only on the narrow sides, and thus with corresponding distances to the respective broad sides. In another embodiment, the combination grooves can also be located in the corner area between broad sides and narrow sides of the outer contour, so that plate shaped elements can then be inserted into the combination grooves parallel to the narrow side, and also in parallel to the broad side.
The combination grooves themselves have an internal contour, which is at least partially shaped as a semicircle, or has bulges, which reach towards the inside beyond a theoretical circular interior contour. The combination grooves particularly have an interior contour with a circular arc shape, which extends over more than 250°, whose open side expands to the outside shaped as a cone.
Combination grooves, which are disposed in the corner area of the outer contour, have a substantially triangular interior cavity, which is formed by protrusions, which are parallel to the adjacent side surfaces, which do not reach other completely, wherein two protrusions preferably reach upwards from the bottom surface of the approximately triangular interior cavity, in parallel to its center, which serve for cutting the threads of bolts threaded into the combination groove, without the entire cross section of the combination groove being deformed thereby.
Embodiments of the invention are subsequently described in more detail. The figures show the following:
a: a cross section through the device, similar to
b: a cross section through the insert, according to
a: a cross section through an embodiment similar to
b: the profile according to
c: the insert according to
d-4h: analog inserts according to the one of
In
The interior contour 54 of the profile 1 is thus without shoulder and, in this case, also circular, in order to be able to perform the sealing relative to the closing covers 29 at the end sections.
This sealing is performed by the closing cover 29 having a cover plate 46, on the one hand, which is placed onto the front face 22 of the profile 1 in a blunt manner, and which has pass-through holes in its corner area for passing through the bolts 42, which are inserted into the profile 1, thus its outer grooves 6, in particular its corner grooves 7, through which the closing cover 29 is firmly pressed onto the front face 22.
From the cover plate 46, a protrusion 45 protrudes forward in longitudinal direction 10, into the interior cavity 14 of the profile 1, wherein the outer contour of the protrusion 45 is slightly smaller than the shoulderless inner contour 54 of the profile 1.
Thereby, it is possible in the outer circumference of this protrusion 45, to provide one or even several annular grooves 28 in axial direction behind each other, and to insert a respective O-ring 24 therein, which is sized so that it presses against the interior contour 54 of the profile 1 during the insertion of the protrusion 45, and thereby seals the closing cover 29 relative to the profile 1 in a reliable manner. Since this seal is located in the interior of the profile 1, and not at the gaps between the cover plate 46 and the front face 22 of the profile 1, which are visible from the outside, the sealing action is much stronger and easily resists the impact of e.g. a pressure washer.
The plastic insert 50 is a circumferentially closed tubular profile with an outer contour 55 fitting into the inner contour 54 of the profile 1, and can be safely positioned there, possibly through additional gluing in longitudinal direction, and with respect to its rotation position. The inner contour 4 of the insert 50 is thus shaped accordingly, as described in the following, in order to receive the functional components as e.g. the wave conductor 2 and one or several circuit boards 23, which carry the processing electronics 12.
The insert 50 is thereby sized shorter than the profile 1, and positioned in its center longitudinal area of the profile 1, so that end cavities 47a, b are created in the end sections of the profile 1, into which the insert 50 does not protrude, and which are thus available for insertion of the protrusion 45 of the closing cover 29. The end cavities 47a, b can thus be required in different sizes, due to different designs of the two end covers, in particular with or without pass-through of cables from the interior cavity 14 of the profile 1.
The outer contour 55 of the insert 50 is shown in
The wave conductor cavities 20 are used for inserting the stick shaped or hose shaped wave conductor unit 2, whose outer circumference is typically circular, which is to extend substantially over the entire length of the insert 50, and in whose interior the wave conductor 3 is located. Accordingly, the wave conductor cavity 20 is a circumferentially closed cavity 20 with a corresponding, also circular inner cross section (
Thus, both wave conductor cavities 20 and 20′ preferably oppose each other.
Thus, the insert 50 is positioned in the profile 1, so that the wave conductor cavities 20, in which a wave conductor unit 2 is actually located (with grooves 20′, open to the outside, preferably in both), directly under the center groove 16, which is formed in the outer contour of the profile 1, the other wave conductor cavity 20′ serves the insertion of another wave conductor unit 2, in case of a redundant design of the distance measuring device.
Between the wave conductor cavities 20 or 20′, a plurality of circuit board grooves 19 is formed in the inner contour 4, which are sized and positioned to receive the longitudinal edges of the circuit boards 23, on whose middle section the processing electronics 12 are formed, in a form locking manner.
The circuit boards 23 are inserted, certainly before attaching the closing covers 29, between two opposing circuit board grooves, and fixated in longitudinal direction. Several such pairs of circuit board grooves 19 are distributed over the circumference of the insert 50, which allow for the insertion of circuit boards 23 with different widths at different locations of the cross section of the insert 50, and selectively also in an orientation parallel to the connection plane between the two wave conductor cavities 20, and also transversal to it.
While only one such circuit board 23 is shown in
Via the electrical conductors 40, a connection of the wave conductor 3 disposed in the wave conductor unit 2, as well as the reverse conductor, is performed via a respective conductor with the circuit board 23, from where conductors 40 lead towards the outside, in case of
The outer contour of the profile 1 is approximately square, corresponding to the circular inner contour, with outer surfaces disposed at a right angle relative to each other, which have a shallow concave fillet in their center area, and thereby only abut or contact at a flat surface of the environment only with their rim areas. These side surfaces are provided as protrusions 17, protruding over the area provided as corner grooves 7, whereby an undercut corner groove with an approximately triangular or trapezoid cross section is created. Through two bulges from the floor of the corner grooves 7, each offset with respect to its center, these corner grooves 7 serve a double function.
On the one hand, they are used to threading in self threading bolts, which are used for bolting down the closing cover 29 in longitudinal direction, wherein the threads, among other places, cut into the bumps 18, but also into the inner corners of the flanks 17.
Thereby, the detachability of the closing covers 29 is assured, so that also during repairs at the distance measuring device, it can then subsequently be sealed tight again without having to exchange the profile.
As shown in
On one of the flat outer sides, the flat middle groove is provided deeper and more undercut, therefore, the wall thickness of the profile 1 has to be larger in this area, and facilitates the form locking guidance of a slide 11 in longitudinal direction, in which the magnet 32 is housed, which constitutes the positioning element for the measurement device, and influences the wave conductor unit 2.
The
Otherwise, the goal, the assembly and the interior design are analogous. The comprised differences are the following:
In
The profile 1′ does not have a center groove, so that the position indicating magnet has to be guided contactless, possibly guided by another component, preferably at a distance along the outside of the profile 1 in longitudinal direction 10.
Also here, the profile 1′ in
The profile 1′ has outer grooves, not shaped as corner grooves, but disposed in pairs, respectively in the narrow sides of the profile 1′, which is preferably placed and mounted in the insert and onto the base with a broad side.
The grooves are provided as combination grooves 51, and have an undercut, in particular vase shaped cross section with an also rectangular indentation in the base of the groove.
Thereby, they fulfill the same double function as the corner grooves of the solution, according to
A marker 44, shaped as a longitudinal groove is machined into both broad sides of the outer surface of the respective location of the profile 1′, where the wave conductor unit 2 shall be located, when the distance measuring device is completely assembled, which is shown with a hose in the solution of
A substantial difference of the insert 50′, shown in
Correspondingly, the outer contour 55′ of the insert 50 is not adapted to the inner contour 56′ over the entire circumference of the profile 1′, which has an inner contour formed as an elongated hole in this solution.
Instead, the outer contour is provided as a hollow fillet in one of the narrow sides of the insert 50, so that a circular wave conductor cavity 20 is generated in the profile 1′ after inserting the insert 50′, between this concave fillet and the associated narrow side of the long hole shaped inner contour 54 of the profile 1′.
Thus, due to the circumferentially closed profile of the insert 50′, the wave conductor cavity 20 is separated in lateral direction from the interior cavity of the insert 50′, in which the circuit board 23 is disposed in assembled state, again through insertion between two circuit board grooves 19 provided as pairs. The circuit boards 23 are preferably provided here only in a plane parallel to the broad side of the insert 50′, but also there at least two pairs of circuit board grooves 19 are provided for inserting two circuit boards with different widths.
The disposition of the wave conductor cavity 20 outside of the interior cavity of the insert 50 is possible in any embodiment, thus also with the embodiment of
The insert 50′, according to
While in the insert 50′ according to
Also the inner cavity 14 has another design, whereby the circuit board grooves 19 are only located in the narrow sides of the interior cavity 14, and in particular, the entire insert 50′ is symmetrical to its longitudinal center plane.
The embodiment of the insert 50′ according to
Independent from that, the interior cavity 14 can thereby be provided nonsymmetrical, and have a design according to
The
In the
While a typical cable grommet 25 was provided in
The closing cover 29′, according to
Irrespective of this design detail, each closing cover 29 of this design has a protrusion 45, reaching from the cover plate 46 into the interior of the profile, whose outer circumference fits into the inner contour of the profile 1 or 1′.
In the outer circumference of the protrusion 45, an annular groove 28, or even several of them axially behind each other are provided, for inserting an O-ring 24, then protruding beyond the annular groove 28 towards the outside, which constitutes the seal relative to the interior circumference of the profile 1.
The
The views of the
This is possible, since the insert 50″ provided with wave conductor units 2 or a respective non functioning dummy 2′ of a wave conductor unit has a maximum diameter, which does not only fit into the largest interior diameter of the flat profile 1′, but also into the circular interior diameter of the profile 1, and which is supported in both of them in lateral direction via the elastic wave conductor unit 2, on the one hand, and the dummy 2′ inserted into the other wave conductor cavity of a wave conductor unit, or an analog element, elastic transversal direction, extending in longitudinal direction, e.g. an elastic hose, in which at least one of the two protrudes radially to the outside from the respective wave conductor cavity 20, and which supports itself in the inner contour 54 of the profile 1.
1, 1′ Profile
2 Wave conductor unit
3 Wave conductor
4 Inner contour (of 50)
5 Outer contour (of 50)
6 Corner grooves (combination grooves)
8 Lateral direction
9 Longitudinal center plane
10 Longitudinal direction
11 Slide
12 Processing electronics
13 Lateral center plane
15 String
16 Center groove
17 Flank
18,18′ Bulge
19 Circuit board groove
20 Wave conductor cavity
21 Enveloping circle
22 Front face
23 Circuit board
24 O-ring
25,25′ Cable grommet
25
a Interior thread
26 Connector passage
26
a Outer thread
27 Tension lugs
28 Annular groove
29,29′ Closing cover
30 Connector
31 Tube clamp
32 Magnet
33 Support
34 First main cavity
35 Second main cavity
37 Screwed connection (of the tension lugs)
38 Serrated hose
40 Conductor
42 Bolt
43 Clamping elements
44 Marking
45 Protrusion (of 29)
46 Cover plate
47
a,b End cavity
48 Cable
50,50′ Plastic insert
51 Combination groove
52 Protrusion
53 Bridge
54 Inner contour (profile 1)
55,55′ Outer contour of the closing cover 29
Number | Date | Country | Kind |
---|---|---|---|
10 2004 062 968.4 | Dec 2004 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2005/014099 | 12/28/2005 | WO | 00 | 8/10/2007 |