FR2899680A1 - LINEAR MEASURING DEVICE OR ARTICULATED METER WITH RODS WITH MAGNETS - Google Patents

Abstract

Articulated linear measuring device or articulated meter (100) comprising a plurality of rods (A), non-metallic material and articulated together, among these rods (A) are defined terminal rods (1, 10), the rods being graduated and numbered on their two opposing flat faces (11, 12), internal and external, characterized in that at least one of the rods (1, 10, 90, A) is associated with at least one magnetic element (M ) generating a magnetic attraction force with respect to at least one of said opposite flat faces (11, 12) of said rod (1, 10, 90, A), said magnetic element (M) being suitable for adhering this rod to a ferrous metal surface of a body (C) during a measurement.

Description

The object of the present invention is a linear measuring device

  or splint meter for performing accurate measurements especially in the presence of a metal surface. Articulated linear measuring devices are known, commonly called articulated or branched meters, constituted by a plurality of rods 15 hinged together, where the graduation on each side starts from the free end of one of these terminal rods. Since the measuring operation is carried out by unfolding or spreading the graduated rods starting from a situation in which they are at least partially superimposed, said rods being unfolded until reaching the desired length on the body to be measured, the operator must intuitively use one hand to immobilize the meter during the measurement (having the other to open the meter). It follows that the measurement is made with difficulty because of the movement of the different rods on the body to be measured, the movement which tends to misalign the rods themselves, making the measurement obtained imprecise. This occurs especially when the body to be measured has a smooth, metal surface on which the rods of the meter rest, and on which such rods can slide easily. The object of the present invention is to provide the user with an articulated meter which, in the presence of a metal surface from which or on which a measurement is to be made, enables a user to perform such a measurement in such a way that accurate and correct even without mobilizing hands.

  Another aim is to propose an articulated meter of the type cited which makes it possible, when carrying out a measurement of the type indicated above, to perform other operations that are generally simultaneous or following the measurement itself, such as the mark of signs corresponding to certain desired points or in particular positions. These objects as well as others that will emerge more clearly for the skilled person, are achieved by a linear measuring device or articulated meter comprising a plurality of rods, non-metallic material and articulated among them among these rods, rods are defined end plates, the rods being graduated and numbered on their two opposite flat faces, internal and external, characterized in that at least one of the rods is associated with at least one magnetic element generating a magnetic attraction force with respect to least one of said opposite flat faces of said rod, said magnetic member being suitable for adhering said rod to a ferrous metal surface of a body during a measurement. These and other features of the present invention will become apparent from reading the following description of the preferred embodiments given hereinafter by way of non-limiting example, with reference to the accompanying drawings, in which: FIG. 1 shows a top view of a meter according to the invention in a position of use; Figure 2 shows a side view of the meter of Figure 1; Figure 3 shows a section taken on line 3-3 of Figure 1; Figure 4 shows a side view, partly in section of a first variant of a portion of the meter of Figure 1; Figure 5 shows a partially sectional view of a second variant of the meter of Figure 1; Figure 6 shows a longitudinal sectional view of a third variant of the meter of Figure 1; and Fig. 7 is a partial front perspective view of another variant of the invention; and FIG. 8 is a perspective view of another variant of the invention. In these figures, reference numeral 100 indicates the articulated meter. This comprises a plurality of rods A hinged together and made of a non-metallic material, such as wood or a plastic material, for example nylon, ABS optionally filled with glass fibers. To optimize the production cost of the device according to the invention in the case where it is made of plastic material, it is advantageously obtained by injection molding. Suitably, the graduation and the numbering of the meter begin on the inner face 11 and from the free end 10B of the terminal rod 10 (the other end rods being indicated with the reference number 1 and with a free end 1B ). Also each intermediate rod between the terminal rods has an inner face 11 and an outer 12, said rod being hinged relative to the adjacent rod by means of a connecting pin. The meter includes extreme end pins indicated by reference numeral 1 and reference numeral 10 in the figures, such end rods having corresponding free ends 1B and 10B and having an end 1A and 10A articulated with respect to the rod adjacent. The outer face 12 of the rod 1 where the numbering and the graduation starting on the face 11 of the rod 10 end is visible when the meter is closed. According to the invention, at least one of said end rods 1 and 10 mentioned above, preferably both, and: advantageously to all the rods A, at least one magnetic element or permanent magnet indicated is associated with the letter reference M in the figures. Such magnets allow the corresponding rod of the meter 100 to be held immobile and integral with a metal surface of a ferrous body during a measurement performed on the latter without mobilizing the hands of the operator, thus facilitating the eventual simultaneous marking of such a surface or the positioning on the latter of the elements to be associated, for example in predetermined specific positions of the body mentioned above. This is achieved by virtue of the magnetic attraction force which is generated between each magnet and such ferrous surface. Each magnetic element M is integral with the corresponding rod so as to be preferably parallel and advantageously coplanar with the face 11 or 12 of the latter to which it is associated; this is done in order to still allow a regular support of the meter on the body to be measured. More particularly, in a first embodiment of the invention shown in the figures, corresponding to the outer face 12 of the end rod 10, at least one cavity or location 16 (both shown in FIG. a magnet M. The latter is fixed in the cavity or location 16 in any known manner, for example by means of an adhesive, and has a flat face 17, turned towards the face 12 of this rod and parallel to the latter. Such a flat face 17 of the magnet is preferably coplanar with that of the rod but may also be slightly recessed relative to the latter in order to create on such a face 12 a recess relative to the magnet M The protrusion of the magnet M from the location 16 should be such that it does not interfere with the closure of the meter. The magnet M may have the width K of the rod with which it is associated, or may have a width less than this or have a cylindrical shape with a diameter smaller than this width K. According to a variant, the two faces 11 and at least 12 of the end rods 1 and 10 of the meter 100 are provided with magnets M, possibly arranged in the corresponding locations 16 arranged between these faces and placed at a distance and offset between them along a longitudinal axis. W of the stem. Alternatively, each magnet M has the same thickness as the rod with which it is associated and has opposite faces parallel and preferably coplanar with the faces 11 and 12 of the rod. In this case, suitably, the magnets are positioned along the rods so as not to face each other when the meter is closed. In addition, each magnet M may have a spatial arrangement with respect to the axis W, -5 oriented in any way and therefore orthogonal or oblique with respect to such an axis or along it. The latter solution is shown in Figure 7 where a magnetic element M, for example ribbon-shaped is inserted in the corresponding location 16, having a position along the axis W mentioned above. Alternatively, such a magnetic element, (it is repeated, may be associated with the terminal rods 1 and 10 but may also be associated with each rod A of the meter 100, may be a ribbon-shaped element wide and long as the rod placed on at least one face 11 or 12 of the shank Such a magnetic tape-shaped element in such a case is also graduated and numbered in that it defines the face of the shank itself. shown in detail in Figure 3, the magnetic member M is inserted in the location 16 between a rod (1, 10, 90), arranged relative to the hinge and connecting pin 31 which engages said rod 90 with the adjacent rod (indicated at reference numeral 80 in Fig. 2) As shown in Fig. 3, advantageously this location is arranged in the housing 30 (where present) which contains the stud head 31A connection 31 mentioned In such a housing 30, a bearing 37 is arranged on which the magnetic element M. is supported. The stud 31 is close to the end 90B of the rod 90. In such a mode, since In the course of carrying out a measurement, the meter 100 may be arranged as in FIG. 2 and that the group of rods A bears with the end 90B of the rod 90 (before last rod) on the body C to measure (ferrous metal material), the presence of the magnet M near this end having a flat face 17 parallel or adjacent to the same plane as the outer face 12 of the rod 90, improves the anchoring of the rod group A and therefore the meter on the metal surface, especially if it is vertical, regardless of the orientation of the meter on said surface.

  Similarly, as has been said, the fact of providing each rod (or only a few rods of the meter) of one or more magnets M housed in the appropriate locations 16 in the thickness of the corresponding rod having a face plane 17 parallel or coincident with the outer face 12 of the rod itself, ensures the attachment of all the rods, in a horizontal or any orientation on the vertical metal surface, even with a meter fully open. With the invention illustrated, the objective is to achieve a graduated scale adhering to a ferrous metal surface, easily used in that the articulated meter can be placed in a pocket, extremely low cost and a great practice being given that the use of the invention is that of a common hinged meter. In addition, it has the advantage of leaving the hands of the operator free during the measurement. As has been said, also the inner face 11 of the end rods 1 and 10 and possibly even other intermediate rods may have one or more magnets M with the flat surface 17 parallel or adjacent to the plane of the face 11. This solution can prove advantageous in that the piece to be measured is shaped bearing in which it may be more convenient to position the group of rods A relative to the height of the bearing.

  In this case, suitably and advantageously, even the graduation and the numbering on its outer face 12 leave the end 10B of the end rod 10, so that by adhering its face 11 on the bearing surface, can read the measurement on the opposite side 12. To ensure the magnetic adhesion of the terminal rod 10 (or that of the rod 1) also via the side 15 of its end 10B, as shown in Figure 4, we provides the insertion of a magnetic element M in a blind cavity 50 engaged in its side 15 of the rod 10, possibly making this rod in a greater thickness relative to the others to be able to contain the magnet, and having the magnet M on its solid face 17 parallel to or adjacent to the end plane 10B perpendicular to the faces 11, 12.

  A last variant, shown in Figure 8, proposes the possibility that the magnet M is positioned on a side 60 of the rod corresponding to the thickness of the latter. Another possible variant is illustrated in FIG. 5, where the magnet M is fixed to the end rod 1, 10 via a support 70 rising from the external face and fastened in a known manner. at the terminal stem; the magnet has the flat face 17 parallel or adjacent to the plane of the end 1B perpendicular to the graduated faces 11 and 12 of the terminal rod. This embodiment of the invention is useful for adhering the terminal rod of the meter 100 frontally on a metal surface (for example a beam) while the other surfaces close to it (for example the uprights). are not metallic. Another variant of the invention is illustrated in FIG. 6, in which the end rod 10 (or 1) is to be shortened by a portion 1 in order to be able to fix, by means of the appropriate studs 21, a support 20 endowed with two fins 23 disposed along the axis W; in the example, the fins are provided with two lowerings 24 and they fit into the appropriate abutments 10K provided in the faces 11 and 12 to ensure the flatness with the latter. The support 20 is provided with cavities or suitable locations in which are inserted and fixed one or more magnetic elements M having a flat surface 17 parallel or adjacent to the plane of the face 12 and the face 11; a location is also provided in a side 150 parallel to that 15 of the rod. In the abutments 24, the appropriate studs 21 are placed to engage the abovementioned support 20 with the corresponding rod. Various solutions have been described with respect to the invention. Still others are possible, such as that which provides for the realization of at least the end rods 1 and 10 of plastic, containing, embedded in the latter, magnetic elements; this solution, obtained using the molding known per se, makes it possible to have a meter 100 with an identical appearance to the known meters, but anyway presenting (unlike the latter) the magnetic elements according to the invention. It is clear, however, that modifications may be made to the linear measuring apparatus heretofore described without departing from the scope of the present invention.

Claims (26)

  1. Articulated linear measuring device or articulated meter (100) comprising a plurality of rods (A), non-metallic material and articulated among them among these rods (A), are defined terminal rods (1, 10), the rods being graduated and numbered on their two opposing flat faces (11, 12), internal and external, characterized in that at least one of the rods (1, 10, 90, A) is associated with at least one magnetic element (M) generating a magnetic attraction force with respect to at least one of said opposite flat faces (11, 12) of said rod (1, 10, 90, A), said magnetic element (M) being suitable for making adhere this rod to a ferrous metal surface of a body (C) during a measurement.   2. Linear measuring device according to claim 1, characterized in that each magnetic element (M) represents a flat face (17) parallel to the opposite faces (11, 12) of the corresponding rod (1, 10, 90, A). .   Linear measuring device according to claim 2, characterized in that said magnetic element (M) is inserted into a blind location or cavity (16) in the rod (1, 10, 90, A) and often on at least one of the opposite flat faces (11, 12) of this rod (1, 10, 90, A).   4. Linear measuring device according to claim 3, characterized in that said magnetic element (M) has a thickness equal to that of the respective location (16) and its flat face (17) is coplanar with the flat face (11). , 12) of the rod in which this location (16) opens.   5. Linear measuring device according to claim 3, characterized in that said location (16) has a depth greater than the thickness of the magnetic element (M), the flat face (17) of the latter being embedded in - 9-10- the corresponding rod and being on an inner plane to the parallel flat faces (11, 12) of this rod.   6. Linear measuring device according to claim 2, characterized in that the magnetic element has a thickness equal to that of the relative rod (1, 10, 90, A) and therefore passes through the rod.   7. Linear measuring device according to claim 3, characterized in that the two parallel flat faces (11, 12) of the rod comprise locations (16) for the magnetic elements (M).   8. linear measuring device according to claim 7, characterized in that said locations (16) on the parallel flat faces (11, 12) of the rod (1, 10) are at a distance and offset between them along the longitudinal axis (W) of the latter.   9. Linear measuring device according to claim 2, characterized in that the magnetic element (M) is inside the corresponding rod (1, 10, 90, A).   Linear measuring device according to claim 9, characterized in that the magnetic element (M) is arranged in a location (16) having a position along the longitudinal axis (W) of this rod (1, 10). , 90, A), said member having a ribbon shaped conformation and thus elongated.   Linear measuring device according to Claim 2, characterized in that the magnetic element (M) covers the flat face (11,   12) of the corresponding rod. 12. Linear measuring device according to claim 11, characterized in that said magnetic element (M) is in the form of a ribbon, graduated and numbered.   Linear measuring device according to claim 3, characterized in that the location (16) for the magnetic element (M) is made with respect to a housing (30) for a connecting pin (31) which connects articulating said rod (1, 10, 90, A) to an adjacent rod (A, 90, 80) of the linear measuring device (100).   14. Linear measuring device according to claim 1, characterized in that the terminal rods (1, 10) have a magnetic element (M) on one side (15) with respect to their free ends (1B, 10B) orthogonal to the faces. opposed plates (11, 12), said element being in a location (16) arranged in the thickness of the rod.   Linear measuring device according to claim 14, characterized in that the location (16) for the magnetic element (10) is provided in a support (70) rising from and fixed to the outer body ( 12) of the terminal stem.   16. Linear measuring device according to claim 1, characterized in that at least one rod (90) different from the terminal rods (1, 10) has a magnetic element (M) near its free end (90B).   17. Linear measuring device according to claim 1, characterized in that these magnetic elements (M) are placed near the end corresponding to those in which are placed connecting studs (31), around which the rods (1) , 10, 90, A) rotate and through which these rods are connected.   Linear measuring device according to claim 1, characterized in that the magnetic element (M) is inserted in a recessed position in the lateral side (60) which unites the inner and outer faces (11, 12) of the rod. and has a flat face (17) parallel or coplanar with the edge face itself (60).   19. Linear measuring device according to claim 1, characterized in that it comprises a support (20) for at least one magnetic element (M), said support (20) being associated with the free end (1B, 10B). the end rod (1, 10), the latter being shortened by a length (10) equal to the length of this support (20). the latter having at least one location (16) for said magnetic element (M), the latter, inserted in this location, having a flat face (17) parallel and coplanar with the opposite flat face corresponding to the rod (1, 10) .   Linear measuring device according to claim 19, characterized in that said support (20) comprises at least one flat fin (23) arranged along the longitudinal axis (W) of the rod (1, 10) and inserted in a location or lowering (10K) of the corresponding rod (1, 10) and fixed thereon by means of studs (21) to be coplanar with this rod.   21. Linear measuring device according to claim 19, characterized in that said support (20) comprises a location (16) for a magnetic element placed on the free edge (150) parallel to the edge (15) of the terminal rod (1). , 10).   22. Linear measuring device according to claim 1, characterized in that the rods are made of plastics material. 10-13-   23. Linear measuring device according to claim 1, characterized in that the rods are made of wood.   24. Linear measuring device according to claim 1, characterized in that the end rods (10, 1) are of greater thickness relative to the intermediate rods.   25. Linear measuring device according to claim 1, characterized in that each magnetic element (M) has a curved surface.   26. Linear measuring device according to claim 1, characterized in that each magnetic element (M) is embedded in the thickness of the rod.