• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
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    • 专利摘要:
    The invention relates to a device 10 for measuring the spacing between opposite surfaces of adjacent parts 16, 18, the device comprising a main body 20 with a first blade 32 fixed relative to the main body and a second blade 44 movable relative to the main body. The blades are biased in a first direction so as to move them away from each other to bring reference surfaces of the blades into contact with respective ones of the opposing surfaces. An electronic control system obtains a measurement representing a distance between the reference surfaces that is displayed on a screen 22. The blades 32, 44 are offset from one another in a direction perpendicular to said first direction and the second blade 44 can be moved against the biasing force to an insertion position in which the blades 32, 44 are substantially coplanar vis-à-vis the other. The biasing force can automatically bring the reference surfaces into alignment with the opposing surfaces. Advantageously, the reference surfaces are engaged with the opposing surfaces with sufficient force to support the entire weight of the device.
    公开号:FR3065066A1
    申请号:FR1852949
    申请日:2018-04-05
    公开日:2018-10-12
    发明作者:Jeff Brindle;Daniel Mcwhirk
    申请人:Bentley Motors Ltd;
    IPC主号:
    专利说明:

    ® FRENCH REPUBLIC
    NATIONAL INSTITUTE OF INDUSTRIAL PROPERTY © Publication number:
    (to be used only for reproduction orders) (© National registration number
    065 066
    52949
    COURBEVOIE © Int Cl 8 : G 01 B 5/14 (2017.01)
    PATENT INVENTION APPLICATION
    A1
    ©) Date of filing: 05.04.18. © Applicant (s): BENTLEY MOTORS LIMITED - GB. (30) Priority: 11.04.17 GB 1705816.5. @ Inventor (s): BRINDLE JEFF and MCWHIRK DANIEL. ©) Date of public availability of the request: 12.10.18 Bulletin 18/41. (© List of documents cited in the report of preliminary research: The latter was not established on the date of publication of the request. (© References to other national documents @ Holder (s): BENTLEY MOTORS LIMITED. related: ©) Extension request (s): © Agent (s): RENT & ABELLO.
    INTERVAL MEASURING DEVICE AND SYSTEM.
    FR 3 065 066 - A1
    The invention relates to a device 10 for measuring the spacing between opposite surfaces of adjacent parts 16, 18, the device comprising a main body 20 with a first blade 32 fixed relative to the main body and a second blade 44 movable relative to to the main body. The blades are biased in a first direction so as to move them away from each other in order to bring the reference surfaces of the blades in contact with respective surfaces among the opposite surfaces. An electronic control system obtains a measurement representing a distance between the reference surfaces which is displayed on a screen 22. The blades 32, 44 are offset with respect to each other in a direction perpendicular to said first direction and the second blade 44 can be moved against the biasing force to an insertion position in which the blades 32, 44 are essentially coplanar with one another. The biasing force can automatically bring the reference surfaces into alignment with the opposite surfaces. Advantageously, the reference surfaces are engaged with the opposite surfaces with sufficient force to support the entire weight of the device.

    Spacing measurement device and system Technical field of the invention
    The present invention relates to improvements made to or relating to a measuring device for measuring the spacing between opposite surfaces of adjacent parts. Aspects of the present invention relate to a self-aligning measurement device and, in particular, but not exclusively, to a measurement device for performing hands-free reading. Another aspect of the invention relates to a system which can be adapted to measure the spacing between opposite surfaces of adjacent rooms and / or the coplanarity of external surfaces of rooms.
    Background of the invention
    It is often necessary to accurately measure the spacing between opposite surfaces of adjacent rooms. For example, in the automotive sector, it is necessary to measure the spacing between edges of adjacent body panels in order to ensure the quality of assembly. This is of particular concern in the luxury vehicle market, where very tight tolerances are applied to ensure that the gaps between adjacent body panels are small and even. It is also necessary to measure the relative coplanarity between the exterior surfaces of adjacent body panels.
    Various known devices are used to measure the spacing between opposite surfaces of adjacent parts. The thickness gauges include a plurality of "blades" or "fingers" of various thicknesses. These can be used individually or in combinations and placed between the opposing surfaces of two parts to measure the spacing between them. Obtaining an accurate measurement using thickness gauges is highly dependent on the individual's ability to ensure that the blades are inserted at the correct angle and to assess the correct fit.
    Another known device for measuring spacings is the caliper. The calipers include two spouts, one fixed relative to a graduated ruler and the other movable relative to the graduated ruler. Reference surfaces of the spouts are placed in contact with the opposite surfaces defining the spacing to be measured and the distance between the reference surfaces of the spouts is read from a combination of the graduated ruler and a first associated with the spout mobile in order to obtain a measurement of the spacing. The precise use of a vernier caliper also requires great skill. The beaks must be inserted in the correct orientation with the reference surfaces parallel to the opposite surfaces and the caliper must be kept stable while the measurement is read. The calipers can alternatively use a mechanical rack and pinion system, the relative spacing between the two spouts being indicated on a dial gauge and to be identified by a user. Dial gauges provide indications that are easier to interpret than a first one, but are likely to give rise to errors if the reading is not carried out from a correct position. More recently, we have witnessed the development of digital calipers which incorporate an electronic transducer used to convert a distance between the movable spout and an electronic signal proportional to the distance between the reference surfaces of the spouts and a screen used to display the resulting measurement. The electronic transducer will often employ inductive, capacitive or magnetic position detection technology. The digital calipers have the advantage that the measured spacing can be read more easily but always depend on the operator's ability to position them correctly.
    Since current devices are often controlled largely by hand, errors caused by users are inevitable. For example, the calipers include movable and often narrow spouts, and improper alignment of such devices with respect to opposite surfaces can easily occur, resulting in inaccurate measurements.
    An objective of the present invention is, therefore, to provide a different measuring device, used to measure the spacing between opposite surfaces of adjacent parts, which overcomes and / or at least partially mitigates the drawbacks of known measuring devices.
    Another object of the invention is to provide a measuring device for measuring the spacing between opposite surfaces of adjacent parts which is capable of aligning itself essentially automatically.
    Yet another objective of the invention is to provide a measuring device used to measure the spacing between opposite surfaces of adjacent parts which does not need to be maintained once put in place to perform a measurement.
    The invention also aims to provide a measurement system which can be configured to measure the spacing between opposite surfaces of adjacent rooms and / or the coplanarity of external surfaces of the rooms.
    Summary of the invention
    Aspects of the invention relate to a measuring device and a measuring system.
    A first aspect of the invention relates to a device for measuring the spacing between opposite surfaces of adjacent parts, the device comprising a main body, at least a first blade fixedly attached to the main body and at least a second blade movably attached to the main body, the first blade (s) defining a first reference surface intended to come into contact with a first of the opposite surfaces and the second blade (s) defining a second reference surface intended to come into contact with the other of the opposite surfaces, the device comprising a digital screen and an electronic control means serving to obtain a measurement representing a distance between the first and second reference surfaces and to display the measurement on the digital screen, the device comprising an elastic stress structure used to apply u does not force tending to move the first and second blades in a direction so as to move them away from each other in order to bring the first and second reference surfaces in contact with respective surfaces among the opposite surfaces during the use, the first and second blades being offset with respect to each other in a second direction perpendicular to the first direction, the second blade being able to be moved against the biasing force in a third direction opposite to the first direction to an insertion position in which the first blade or blades and the second blade (s) are essentially coplanar with one another.
    The elastic biasing structure can apply sufficient biasing force so that, during use, the first and second reference surfaces are automatically brought into alignment with the opposite surfaces of the parts. This reduces the risk of the device being misaligned when a measurement is made.
    The elastic biasing structure can apply sufficient biasing force so that, in use, the first and second reference surfaces are engaged with opposing surfaces of the workpieces with enough force to support essentially the entire weight of the device. This further reduces the risk of the device being misaligned when a measurement is made and allows a user to read the measurement primarily in hands-free mode.
    In one embodiment, the first blades are two in number, the first reference surfaces defined by the first blades being coplanar. In this case, there may be only one second blade centrally disposed between the first two blades.
    Each blade has a width of 3 mm or more. The blades can all be of the same width or at least one / some can be of different widths.
    The device can weigh from 20 g to 40 g, and the elastic biasing means can apply a biasing force of at least 3 N to 6 N. The device can weigh from 25 g to 35 g, and the elastic biasing means may apply a biasing force of at least 4 N to 5 N. The main body may be made of light materials, such as polymeric materials.
    In one embodiment, the device includes a slider attached for the purpose of linear movement relative to the main body, the second blade (s) being fixedly attached to the slider. In one embodiment, the electronic control means includes a transducer structure for generating a first signal proportional to the position / spacing of the cursor relative to the main body (e.g. relative to a reference position of the cursor).
    The main body can define a third flat reference surface intended to come into contact with an external surface of a first part during reuse.
    In one embodiment, the device comprises a fastening structure intended to receive an additional measuring device used to measure the coplanarity of the external surfaces of the adjacent parts during reuse. In one embodiment, the fastening structure comprises a fastening element projecting in the first direction from an end of the main body beyond the first blade (s) so that, when use, when the blades are placed in the space between opposite surfaces of first and second adjacent parts with the third reference surface in contact with an external surface of a first of the adjacent parts, the fastening element extends above the outside surface of a second of the adjacent pieces. The fastener may define a fourth reference at a predetermined distance from the third reference surface, measured perpendicular to the plane of the third reference surface. The fastener may define an opening for receiving a cursor from the additional measuring device when in use. At least one magnet can be integrated within the attachment element.
    A second aspect of the invention relates to a measurement system comprising a first measurement device configured to measure the spacing between opposite surfaces of a pair of adjacent parts and a second measurement device configured to measure the coplanarity of exterior surfaces of the pair of adjacent parts in combination with the first device, the second device being adapted to be releasably attached to the first device.
    Each of the first and second measuring devices can be a digital measuring device comprising an electronic control system comprising a screen used to display a measurement.
    The first measuring device can be configured to be able to measure the spacing between opposite surfaces of a pair of adjacent parts when used with or without the second measuring device.
    In one embodiment, the system includes a quick-attach fastener structure that allows the second device to be attached to the first device without using tools.
    The system may include a magnetic fastener structure for securing the second measurement device to the first measurement device. In one embodiment, the first measuring device has a first fastening element and the second measuring device has a second fastening element, the first and second fastening elements being able to be engaged one with the other to place the second measuring device on the first measuring device, at least one magnet being integrated into each of the first and second fastening elements, the magnets being configured so that, when the first and second elements d 'fastener are joined in a desired orientation, the magnets in the first and second fastening elements attract each other so as to hold the second measuring device in place on the first measuring device.
    The first measuring device can be a measuring device according to the first aspect of the invention. In one embodiment thereof, in which the first measuring device defines a third planar reference surface intended to come into contact with an external surface of a first part during use, the second measuring device comprises a second main body, a second cursor movable relative to the second main body, one end of the second cursor projecting from the second main body and defining a fourth reference intended to come into contact with an external surface of a second of the parts adjacent in use, the second device comprising a digital screen and electronic control means used to obtain a measurement representing a distance between the fourth reference and the third reference surface and to display the measurement on the digital screen.
    Detailed description of the invention
    So that the invention is more clearly understood, an embodiment of it will now be described, by way of example only, with reference to the accompanying drawings, among which:
    Figure 1 is a perspective view, from the front and from one side, of an embodiment of a measuring device according to one aspect of the embodiment;
    Figure 2 is a perspective view, from the rear and on the opposite side, of the measurement device of Figure 1;
    Figure 3 is a plan view, from the front, of the measurement device of Figures 1 and 2, when used to measure the spacing between opposite surfaces of adjacent parts;
    Figure 4 is a view, from the side of the measurement device of Figure 3, with the adjacent parts shown in cross section to illustrate the engagement of the device blades in the space between opposite surfaces of the parts;
    Figure 5 is a perspective view of the device of Figures 1 to 4, with an end cover attached to the blades;
    Figure 6 is an exploded perspective view of the device and the end cover of Figure 5;
    FIG. 7 is an exploded perspective view of an embodiment of a measurement system according to an aspect of the invention and which can be configured to measure the spacing between opposite surfaces of adjacent parts and / or the coplanarity of exterior surfaces of rooms;
    Figure 8 is a perspective view of the measurement system of Figure 7 in an assembled state;
    Figure 9 is another perspective view of the assembled measurement system of Figure 7;
    Figure 10 is a plan view from above of the assembled measurement system of Figures 7 to 9 when used to measure the spacing between opposite surfaces of adjacent rooms and the coplanarity of exterior surfaces of rooms; and Figure 11 is a view from the side of the measurement system of Figure 10, with the adjacent parts shown in cross section to illustrate how the system engages with the parts in use.
    In the following description, similar reference numbers will be assigned to similar parts, but increased by 100 for each embodiment.
    A first embodiment of a measuring device 10 in accordance with one aspect of the invention will now be described with reference to Figures 1 to 5.
    The measuring device 10 is a digital gauge intended to be used to measure the spacing between opposite surfaces 12, 14 of adjacent parts 16, 18. The measuring device 10 is particularly suitable for measuring the spacing between panels adjacent to a motor vehicle body. However, the measuring device can be used for other applications and could be modified accordingly.
    The measuring device 10 comprises a main body 20 which contains various electronic control components comprising a display screen 22. The main body 20 comprises a base 24 and a cover 26 removably attached to the base. An outer surface 28 of the base 24, which forms a rear face of the main body 20, is planar and defines a reference surface intended to come into contact with an outer surface 30 of a first part 16 during use.
    A pair of first blades 32 are attached to an end face 34 of the base 24 at a first end of the main body. The end face 34 is essentially planar and extends transversely with respect to the main body 20. The first blades 32 are identical to each other, and are in the form of thin and flat plates. The first blades 32 are spaced apart from each other, each toward a side of the main body, and protrude beyond the rear face 28 of the main body. The projecting part of each blade 32 defines a reference surface 36 which, in this embodiment, is oriented inward towards the main body. The reference surfaces 36 of the first blades 32 are aligned so as to be coplanar with one another along the plane of the end face 34 of the main body so that they align parallel to the opposite surface 12 of the first of the adjacent parts 16 during use.
    An elongated slider 38 is attached to the main body 20 for the purpose of linear movement relative to the main body in a longitudinal direction. The cursor is aligned with the center of the main body 20 such that a longitudinal axis of the cursor is parallel to and in alignment with a longitudinal axis of the main body 20. The larger part of the slider 38 is located inside the main body 20 between the base 24 and the cover 26. However, an opening 40 at the first end of the main body allows a first end region 42 of the cursor to protrude outside the main body between the first spaced blades 32. A second blade 44 is fixedly attached to the first end of the slider. The second blade 44 is similar to the first blades 32 in that it is in the form of a thin, flat plate which projects beyond the rear face 28 of the main body. The second blade 44 is aligned parallel to the first blades 32 and a face 46 oriented towards the outside of the second blade 44 defines a reference surface intended to come into contact with the opposite surface 14 of the second part 18 during use. . The reference surface 46 of the second blade 44, in this embodiment, is oriented outward, in a direction away from the main body 20. The first blades 32 and the second blade 44 have essentially the same thickness the relative to each other.
    The cursor 38 is resiliently biased by a tension spring 48 so that it moves in the direction of the arrow A so that the second blade 44 is spread outward relative to the first blades 32. The cursor 38 can however be moved manually in the direction opposite to arrow A in order to bring the second blade 44 to an insertion position in which it is close to, or in alignment with, the first blades 32, purposes of inserting the blades in the space between the opposite surfaces 12, 14 of the adjacent parts. The tension spring 48 acts between the main body 20 and the slider 38 and, in this embodiment, is a helical spring engaged, at one end, with an opening 50 in the base 24 and, at the level of the other end, with a hook or a projection 52 on the cursor. The movement of the cursor 38 in the direction of the arrow A is limited by means of corresponding stops (not shown) on the cursor 38 and the main body or another stop structure and the device is configured so that the spring 48 is still under tension, even when the cursor is completely removed. The range of movement of the cursor 38 is selected appropriately according to the maximum size of the space to be measured. Although a tension spring 28 is used to bias the cursor 38 in the present embodiment, any suitable means of biasing the cursor 38 can be adopted, including other forms of springs, such as a compression spring , or an elastomeric band. Providing that the first and second blades are coplanar in the insertion position allows the blades to be inserted in the smallest possible spacing, dictated only by the thickness of the blades. However, when the device is intended to be used to measure spacings which are always greater than the thickness of the blades, the second blade could be slightly offset with respect to the first blades in the insertion position, provided that the blades are close enough to be able to be inserted in the smallest spacing that we plan to measure using the device.
    The electronic control system located in the main body 20 includes means for determining the spacing / position of the cursor 38 relative to the main housing 20 (e.g. relative to a reference position of the cursor in the main body ) and a processing means for using the spacing / position data in order to obtain a measurement indicating the interval between the reference surfaces 36 of the first blades 32 and the reference surface 46 of the second blade 44, measured in a longitudinal direction of the cursor (that is to say in the direction of movement A, perpendicular to the plane in which the reference surfaces of the first blades are located). The electronic control system also includes means for displaying the measurement obtained on the display screen 22. The distance / position of the cursor 38 can be detected using any suitable means. This could include a transducer which produces a first signal proportional to the spacing / position of the cursor 38 relative to the main body and the electronic control system may include processing means acting using an appropriate algorithm in order to determining the distance between the reference surfaces 32 of the first blades and the reference surface 44 of the second blade, as a function of the signal from the transducer.
    The display screen 22 is housed in an opening 54 in a wall 56 of the cover which defines a front face of the main body so that it is easy to see the screen during use of the device. Various controls for the device are also located on the front panel, including an on / off switch 58, a measurement unit selection switch 60 and a reset switch 62. A power supply for the electronic control system is located inside the main body 20 and can be in the form of a battery which can be replaceable.
    The electronic control system can be configured to display the measurement in any desired length units, such as mm or inches and the like. In the present embodiment, a user can selectively change the units in which the measurement is displayed among a plurality of options using the measurement unit selection switch 60.
    To calibrate the device 10, the reset switch 62 is depressed while the device is on and the second blade 44 is held in a calibration position. The calibration position may be a position in which the reference surface 46 of the second blade 44 is coplanar with respect to the reference surfaces 36 of the first blades 32, which would be equivalent to a zero distance between the reference surfaces and, therefore, at zero spacing. However, this is not essential and the reference surface 46 of the second blade 44 can be offset from the reference surfaces 36 of the first blades 32 in the calibration position, with the electronic control configured to take account for the offset. For example, the second blade 44 could be aligned so as to be coplanar with the first blades 32 in the calibration position so that the reference surfaces 36, 46 are offset by the thickness of the blades 32 , 44. The device 10 may be provided with a jig for holding the second blade 44 in the correct calibration position relative to the main body 20 while the device is calibrated. Figures 5 and 6 illustrate an end cover 60 which can be releasably attached to the first end of the device 10 and which has a stop serving to hold the second blade in the calibration position. The end cover 60 covers the blades 32, 44 and can be attached to the device when it is not in use in order to protect the blades 32, 44 and allow the device to be recalibrated before use.
    The use of the device 10 to measure a spacing between opposite faces 12, 14 of adjacent parts 16, 18 will now be described with particular reference to Figures 3 and 4.
    The device 10 is started and, if necessary, recalibrated using the end cover 60 as described above. Once the end cover has been removed, the device can be put in place with one hand, usually the right hand. The operator places his thumb on the second blade 44 and his fingers on the opposite end of the main body and pushes the cursor 38 inwards so as to bring the second blade 44 to a position in which it is sufficiently close. first blades 32 to allow the blades to be inserted into the gap between the opposing surfaces 12, 14 of the first and second adjacent pieces 16, 18. The operator places the device 10 so that the rear face 28 of the body main is near the outer surface of a first of the parts 12 and places the blades in the space between the opposite surfaces 12, 14. Once the blades 32, 44 inserted in the space, the operator applies a slight pressure so that the rear face 28 of the main body comes into contact with the external surface 30 of the first part 12 and releases the slider 38 so that the spring 48 urges cursor 38 outwards. As the cursor moves outward in the direction of arrow A, the reference surface 46 of the second blade 44 is brought into contact with the opposite surface 14 of the second part 18 and a reaction force guarantees that the reference surfaces 36 of the first blades 32 are brought into contact with the opposite surface 12 of the first part 16, if this was not already the case.
    The spring 48 applies a sufficient biasing force so that the blades 32, 44 are securely engaged between the opposite surfaces 12, 14. This automatically brings the reference surfaces of the blades 32, 44 in parallel alignment with the opposite surfaces 12, 14 so that the device is correctly aligned for precise measurement of the spacing. This process is facilitated by the use of blades 32, 44 which are relatively wide, as measured in a plane parallel to the opposite surfaces. The biasing force applied by the spring 48 is sufficient so that, with the blades engaged between the opposite surfaces 12, 14, the operator only has to apply a minimum force to the main body to keep the device in place for that the measurement is read, this guarantees a minimal influence of the operator on the accuracy of the measurement. In fact, in a particularly advantageous structure, the biasing force applied by the spring 48 is sufficient for the engagement force to be able to support the weight of the device 10 so that an operator does not have at all maintaining the device once the blades are in contact with the opposite surfaces 12, 14. Thus, the operator can drop the device 10 once it is in place and read the measurement in hands-free mode. This is advantageous not only from a practical point of view, since the operator can thus read and record the measurement without having to hold the device 10 in place, but also reduces the errors caused by the operator since the device is aligned and positioned automatically. In one embodiment, the biasing force applied by the spring 48 is sufficient for the engagement force to be able to support the weight of the device 10, even when the opposite surfaces 12, 14 extend essentially vertically.
    It will be understood that it is not necessary to follow exactly the above process and that an operator can hold and manipulate the device 10 in various ways in order to set it up to measure a spacing between opposite surfaces of adjacent parts . For example, an operator could position the device 10 with his two hands.
    The width W of the blades 32, 44 is selected appropriately to ensure that they align correctly with the opposing surfaces 12, 14 and taking into account the profile of the opposing surfaces. When the device is intended to be used to measure the spacing between opposing surfaces which are generally straight and parallel to each other, relatively wide blades can be used, but if it is likely that the opposite surfaces are curved, thinner blades may then be necessary. Generally, the device 10 is intended primarily for use in measuring a spacing between opposite surfaces that are straight and parallel, at least in the region in which the device 10 is applied. The blades 32, 44 can all have the same width or can have different widths. In one embodiment, the first blades 32 have the same width relative to one another and the second blade 44 has a different width. In embodiments, each of the blades may have a width of 3mm, 4mm, 5mm, 6mm, 7mm, 8mm, 10mm, 11mm, 12mm or more.
    The blades 32, 44 must be thinner than the smallest spacing to be measured but strong enough not to bend under the load of the spring. The blades 32, 44 can be made of any suitable material, within the limits imposed by the constraint mentioned above, including, without limitation: metal, polymeric materials and composite materials. In one embodiment, the blades 32, 44 are made of a quenched steel wedging material and can have a thickness of at least 0.2 mm, or at least 0.3 mm or at least 0.4 mm.
    So that the engaging force applied by the spring 48 can support the weight of the device 10 without using an excessively high restoring force, the device 10 is advantageously configured to be relatively light. Thus, although the main body 20 can be made of any suitable material, it is advantageously made from light materials. For example, the base 24 and the cover 26 can be molded from polymeric materials.
    In one embodiment, the device has a total length in the range of 60 to 70 mm and a width in the range of 25 to 35 mm. In one embodiment, the device weighs 30 g and the spring applies a force lying in the range from 3 N to 6 N over the range of movement of the cursor 38. However, it will be understood that it is possible to vary the weight of the device with an appropriate change in the restoring force. In one embodiment, the device has a weight in the range of 20 g to 40 g, or in the range of 25 g to 35 g.
    In the embodiment illustrated in Figures 1 to 4, the cursor 38 is biased by the spring 48 so that it moves in the direction of the arrow A so that the second blade 44 is moved outward, so as to move away from the first end of the main body 20. However, in a modified version of the device 10, the direction of movement of the cursor 38 is reversed so that the spring 48 pulls the cursor 38 inward in the direction opposite to arrow A. In this case, the outer surfaces 64 of the first blades 32 define reference surfaces intended to come into contact with the opposite surface 14 of the second blade 18 and the interior surface 66 of the second blade 44 defines a reference surface intended to come into contact with the opposite surface 12 of the first part 16. In this modified device 10, part of the cursor can protrude from a end of main body 20 opposite the end at which the blades are attached and be provided with a formation, such as a tab, which can be manipulated by a user in order to move the cursor so as to align the first and second blades for insertion into the measured spacing.
    Figures 6 to 8 illustrate a system of measuring devices 100 according to one aspect of the invention which can be used to measure the spacing between opposite surfaces of adjacent rooms and / or the coplanarity of the external surfaces of adjacent rooms. The system 100 is particularly suitable for measuring the spacing between adjacent panels of a motor vehicle body or their coplanarity. However, the system can be used for other applications and could be modified accordingly.
    The system of measuring devices 100 comprises a first measuring device 110 ’and a second measuring device 110’ which can be releasably attached to the first device 110 ’. The first measuring device 110 ’is configured to measure the spacing between opposite surfaces 112, 114 of adjacent parts 116, 118 and can be used independently of the second measuring device 110”. The second measurement device 110 is configured to measure the coplanarity of exterior surfaces 130, 130 ′ of two adjacent parts when it is used in combination with the first measurement device 110 ’.
    The first measuring device 110 ’is constructed and implemented essentially in the manner described above with respect to the modified version of the measuring device 10 of the first embodiment. Consequently, the first measurement device 110 ’comprises a first main body 120’ which contains various electronic control components including a first display screen 122 ’. The first main body 120 'includes a first base 124' and a first cover 126 'removably attached to the first base. An outer surface 128 'of the first base 124', which forms a rear face of the first main body 120 ', is planar and defines a reference surface intended to come into contact with an outer surface 130 of a first of the adjacent parts 116 when using.
    A pair of first blades 132 are attached to an end face 134 ’of the first base 124’ at a first end of the first main body 120 ’. The end face 134 ’is essentially flat and extends transversely with respect to the first main body 120’. The first blades 132 ’are identical to each other in that they are in the form of thin and flat plates. The first blades 132 ’are spaced apart, one toward each side of the first main body 120’, and protrude beyond the rear face 128 ’of the first main body. The projecting part of each blade 132 defines a reference surface 136 which, in this embodiment, is oriented outward in a direction away from the first main body 120 ’. The reference surfaces 136 of the first blades 132 are aligned so as to be coplanar with one another and parallel to the planar end face 134 ′ of the first main body, so that they align parallel to opposite surfaces 112, 114 of adjacent pieces 116, 118 during use.
    A first elongated cursor 138 ′ is attached to the first main body 120 ′ for the purpose of linear displacement relative to the first main body in a longitudinal direction, perpendicular to the plane of the reference surfaces 136 of the first blades 132. The cursor is aligned in the center of the first main body 120 'so that a longitudinal axis of the cursor is parallel to and in alignment with a longitudinal axis of the first main body 120'. Most of the slider 138 'is located inside the main body 120' of the first unit between the first base 124 'and the first cover 126'. However, an opening 140 'in the first base at the first end of the first main body 120' allows a first end region of the first slider 138 'to protrude outside the first main body 120' between the first blades 132 spaced apart. A second blade 144 is fixedly attached to the first end 142 'of the first slider 138'. The second blade 144 is similar to the first blades 132 in that it is in the form of a thin, flat plate which projects beyond the rear face 128 ’of the first main body 120’. The second blade 144 is aligned parallel to the first blades 132 and a face 146 oriented towards the inside of the second blade 144 defines a reference surface intended to come into contact with the opposite surface 112 of a first of the adjacent parts 116 during use. The reference surface 146 of the second blade 144, in this embodiment, is oriented inward, towards the first main body 120 ’. The first blades 132 and the second blade 144 have essentially the same thickness with respect to each other.
    The first slider 138 'is resiliently biased so that it moves in the direction of the arrow B so that the second blade 144 is spread inward, towards the first main body 120', relative to the first blades 132. The first slider 138 'can be moved manually in the direction opposite to arrow B in order to bring the second blade 144 close to, or in alignment with, the first blades 132, for insertion of the blades in the spacing between opposite surfaces 112, 114 of adjacent pieces. The movement of the first cursor 138 ’in the direction of arrow B is limited by means of corresponding stops (not shown) on the cursor and the first main body or some other stop structure. The first cursor 138 ′ can be stressed by any suitable structure, including any one of those mentioned above for the stress of the cursor 38 in the first embodiment of a measuring device 10. The range movement of the first cursor 138 'is appropriately selected according to the maximum size of the spacing to be measured. The opening 140 'is sized and shaped appropriately to allow the desired range of movement of the first slider 138'.
    As with the device 10 of the first embodiment, the electronic control system in the first measuring device 110 'comprises means intended to determine the spacing / position of the first cursor 138' relative to the first main housing 120 'and processing means for using the spacing / position data to obtain a measurement indicating the interval between the reference surfaces 136 of the first blades 132 and the reference surface 146 of the second blade 144, measured in the direction of movement of the first cursor 138 ′ (for example in the direction of the longitudinal axis of the main body / cursor, perpendicular to the planes of the reference surfaces of the blades), and means for displaying the measurement obtained on the first screen d 'display 122'. For details about the control system, the reader should consult the description of the first embodiment 10 above.
    As with the first embodiment of a measuring device 10 according to one aspect of the invention, the biasing force applied to the first slider 138 'is sufficient for the blades 132, 144 to be securely engaged between the surfaces opposites 112, 114. This automatically brings the reference surfaces of the blades 132, 144 in parallel alignment with the opposing surfaces 112, 114 so that the device is properly aligned for accurate measurement of the spacing. At least when the first device 110 ′ is used alone to measure a spacing, the applied biasing force is sufficient so that, with the blades engaged between the opposite surfaces 112, 1Γ4, the operator only has to apply one minimum force at first main body 110 'to hold the device in place while the spacing measurement is read. This guarantees minimal operator influence on the measurement accuracy. In fact, in a particularly advantageous structure, the applied biasing force is sufficient for the engagement force to be able to support the weight of the first measuring device 110 ′ so that an operator does not have at all maintaining the device once the blades are in contact with opposite surfaces 112, 114. In one embodiment, the applied biasing force is sufficient for the engagement force to be able to support the weight of the first device 110 ′ even when the opposite surfaces 12,14 extend essentially vertically.
    The first measuring device 110 'differs from the device 10 according to the first embodiment in that it comprises a first fastening element 168' to which the second measuring device 110 'is attached. The first fastening element 168 'is in the form of a member or a fin which projects outwards in a longitudinal direction from the main body 120' / slider 138 'from the end face 134 'from the first base 124'. The first fastener 168 'is configured to extend above the exterior surface 130' of a second of the adjacent parts 118 when the first measuring device 110 'is placed with its main body 120' on the surface exterior 130 of the first of the adjacent pieces 116 and the blades 132, 144 in the spacing between the opposite surfaces 112, 114 of the pieces. An upper or forward-facing surface 170 of the first fastening element is substantially planar and defines a reference surface which is located at a known interval from the rear-facing external reference surface 128 ' from the base 124 'of the first unit. A lower or rearward facing surface 172 of the first attachment member 168 'is spaced upward / forwardly from the rearwardly facing outer surface 128' of the first base 124 ' a suitable distance to allow the greatest degree of offset provided between the exterior surfaces 130, 130 'of adjacent parts 116, 118 to be measured. The first fastening element 168 ′ has an opening 173 which extends from the upper surface 170 to the lower surface 172 and through which an end portion of a cursor 138 ”of the second measuring device 110” can pass. , as explained below.
    The second measuring device 110 "is similar to the first measuring device 110", the latter comprising a second main body 120 "which contains various electronic control components including a second display screen 122". The second main body 120 ”includes a second base 124” and a second cover 126 ”which can be removably attached to the second base.
    A second elongated slider or piston 138 ”is attached to the second main body 120” for the purpose of linear displacement relative to the main body in a longitudinal direction. The second cursor 138 "is aligned with the center of the second main body 120" so that a longitudinal axis of the cursor is parallel to and in alignment with a longitudinal axis of the second main body 120 ". Most of the second slider 138 "is located inside the second main body 120" between the second base 124 "and the second cover 126". However, an opening 140 "at the first end of the second main body 120" allows a first end region 142 "of the second slider 138" to protrude outside the second main body 120 ".
    An end face 174 at the first end region of the second slider 138 ”defines a reference surface intended to come into contact with an external surface 130 ′ of a second of the adjacent parts 118 during use and extends in a plane perpendicular to the axis of the cursor 138 ”. The second slider 138 ”is resiliently biased by a tension spring, or other biasing structure, in the direction of the arrow C (perpendicular to the direction of movement B of the first slider 138 in the system envisaged) so that the first end region 142 ”is moved so as to move it away from the main body 120” so that, in use, the end face 174 is biased towards the external surface 130 ”of the second adjacent parts 18. However, the second cursor 138 ”can be moved manually in the opposite direction against the biasing force in order to move the end face 174 so as to approach it from the main body 120”. The range of movement of the second slider 138 ”is limited by means of stops acting between the second main body 120” and the second slider 138 ”.
    The second main body 120 "has a second fastening element 168" at its first end which is made so as to form part of the base 124 ". The second fastening element 168 ”is in the form of a member or a fin extending parallel to an end face of the main body 120”, that is to say transversely to the main body in a plane perpendicular to the axis / direction of movement of the second cursor 138 ”. An opening 176 extends through the second fastening element 168 ", through which the second slider 138" passes. An outer surface 178 of the second fastening element 168 ”is planar, extending on a plane perpendicular to the axis / direction of movement of the second unit, and is configured to be placed on the upper surface / oriented toward the 'before 170 of the first attachment member 168' when the second device 110 'is attached to the first device 110'. The structure is configured so that, when the second device 110 ”is attached to the first device 110 ', the external surface 178 of the second attachment element 168” defines a reference which is located at a known distance from the rear face / the reference surface 128 'of the first main body 120'. Consequently, when the rear face 128 ′ of the first main body 120 ′ is in contact with the external surface 130 of the first of the adjacent parts 116, the reference surface 178 of the second fastening element 168 ″ is positioned at a known distance above the outer surface 130 of the first of the adjacent pieces 116. In addition, since the reference surface 178 is fixed relative to the second main body 120 ”, the second main body 120” is also positioned at a distance known above the external surface 130 of the first of the adjacent parts 116.
    The second measuring device 110 "comprises an electronic control system placed in the second main body 120" which is similar to that of the first measuring device 110 ’and similar to that of the measuring device 10 of the first embodiment. The control system includes means for determining the spacing / position of the second slider 138 ”relative to the second main body 120” (eg relative to a reference such as the reference surface 178) and means for processing to use the spacing / position data to obtain a measurement indicating the distance measured in the axial direction of the second cursor 138 ”between the end face 174 of the second cursor 138” and the reference plane of the rear face 128 ′ of the first main body, this indicating the coplanarity of the exterior surfaces 130, 130 ′ of the adjacent parts.
    In order to securely attach the second 110 "measuring device to the first 110" measuring device, at least one magnet is integrated in each of the first and second 168 ", 168" fastening elements. The structure is configured in such a way that the poles of the magnet (s) in one of the fastening elements 168 'are placed opposite to the poles of the magnet (s) in the other fastening element 168 ”So that when the second fastener 168” is positioned in the correct orientation desired on the first fastener 168 ', the magnets attract each other and hold the second device 110 ”firmly in place on the first device 110 '. This constitutes a simple quick-fixing connection used to attach the second device 110 ”to the first device 110 ', which does not require the use of tools for assembly or disassembly and which guarantees that the second device 110” is always attached to the first unit 110 'in the correct orientation. Other quick-fix connection structures could be adopted, such as the use of releasable elastic fasteners or a twist connection such as a bayonet coupling or the like. In this case, mechanical structures can be used to ensure that the second 110 "device is attached to the first 110" device in the correct orientation. This could include combined formations on the two fasteners which can only be assembled in a desired orientation, for example.
    The second measurement device 110 "includes controls similar on the front face of the main body 120" to those of the first measurement device 110 'and of the device 10 according to the first embodiment, including an on / off switch 158 ", a 160 ”measurement unit selector switch, and a 162” reset switch. A power supply for the electronic control system is located inside the 120 ”main body of the second unit and can be in the form of a replaceable battery.
    The second measurement device 110 ”can be calibrated in a similar manner to the first device 110 'and to device 10 of the first embodiment by holding the second cursor 138” at a designated calibration position relative to the second main body 120 ”and pressing the reset switch. The calibration position can be a position in which the end face 174 of the second slider 138 ”is spaced axially from the reference surface 178 of the second fastening member 168” by a distance which is equal to the vertical interval between the rear face 128 'of the base 124' and the upper reference surface 170 of the first fastening member 168 ', this being the position that the second slider 138 ”would adopt during use if the outer surfaces 130, 130 ′ of the adjacent parts were coplanar. However, this is not essential and the control system can be configured to calibrate the second measuring device 110 "with its cursor 138" in any predetermined position relative to the main body 120 ".
    In use, the first measuring device 110 'can be used alone to measure the spacing between the opposing surfaces 112, 114 of the adjacent pieces in a similar manner to that described above with respect to the first embodiment 10, with the first main body 120 ′ of the rear surface 128 ′ in contact with the external surface 130 of the first part 116. In order to then measure the relative coplanarity of the external surfaces 130, 130 ′ of the parts, the second measuring device 110 'is started and calibrated, if necessary. While the first measuring device 110 ’is still in place on the first of the adjacent parts, the second measuring device 110’ is assembled on the first measuring device 110 ’as described above. Once the two devices have been assembled, the second slider 138 "projects through the opening in the first fastening member 168" and its end face 174 comes into contact with the external surface 130 "of the second of the parts. The second device control system 110 ”detects the spacing / position of the second cursor 138” relative to the second main body 120 ”and uses this data to determine the coplanarity of the exterior surfaces of the adjacent rooms and the resulting measurement is displayed on the second screen 122 '.
    By measuring the spacing by means of the first measuring device 110 ′ alone initially, the measurement can be carried out essentially in hands-free mode, as mentioned in connection with the first embodiment of a device 10, this minimizing the risks that a user is causing measurement error by misaligning the first unit. Subsequently, when the second measuring device 110 "is fixed, the engagement force applied to the blades of the first device 110 'may not be sufficient to support the cumulative weight of the first and second devices 110', 110", especially with the second 110 ”device protruding outward when used on vertically oriented surfaces, and the operator may need to hold the devices in place, at least to some extent. However, the risk that the user incorrectly aligns the device when measuring the coplanarity is much less, since it is only necessary to hold the rear face 128 ′ for the first device 110 ′ flush with the external surface 130 of the first piece.
    In another method, the first and second devices 110 ’, 110” can be initially assembled and both moved so that they are in place to measure both spacing and coplanarity at the same time. Although the user may have to support the assembled devices 110 ', 110 ”to a certain extent, the stressing of the blades 132, 144 so that they are in contact with the opposite surfaces 112, 114 of the adjacent parts will guarantee that the blades are properly aligned with the opposite surface and will reduce the risk of errors being introduced due to improper alignment.
    The above embodiments are described by way of example only. Many variations are possible without departing from the scope of the invention as defined in the appended claims. For example, although the various reference surfaces in the disclosed embodiments are shown as smooth planar surfaces, this is not essential. A surface of a part intended to act as a reference may include a plurality of convex elements or raised contact points having outermost ends situated in a common plane so as to define a reference surface. For example, the rear face 28, 128 ′ of the base of the spacing measuring device 10, 110 ′ which is placed on the external surface 30, 130 of a first of the adjacent parts could include a certain number of protrusions, such as as ribs or bumps, the outer ends of the protrusions all being aligned in a common plane for the purpose of contact with the outer surface 30, 130 of the first of the adjacent parts. Similarly, the reference surfaces of the blades need not be planar and could be ribbed, dented, or otherwise shaped, as long as they have elements aligned in a common plane for contact purposes. with the appropriate surface of the parts being measured.
    权利要求:
    Claims (15)
    [1" id="c-fr-0001]
    1. Device for measuring the spacing between opposite surfaces of adjacent parts, the device comprising a main body, at least a first blade fixedly attached to the main body and at least a second blade attached for movement purposes relative to the main body, the first blade or blades defining a first reference surface intended to come into contact with a first of the opposite surfaces and the second blade or blades defining a second reference surface intended to come into contact with the other of the opposite surfaces, the device comprising a digital screen and an electronic control means serving to obtain a measurement representing a distance between the first and second reference surfaces and to display the measurement on the digital screen, the device comprising an elastic loading structure used to apply a force tending to displace the p first and second blades in a first direction so as to move them apart from each other in order to bring the first surface and the reference surfaces in contact with respective surfaces among the opposite surfaces during use, the first and second blade being offset from each other in a second direction perpendicular to the first direction, the second blade being adapted to be moved against the biasing force in a third direction opposite to the first direction to an insertion position in which the first blade or blades and the second blade (s) are essentially coplanar with one another.
    [2" id="c-fr-0002]
    2. Measuring device according to claim 1, in which the elastic stress structure applies a sufficient stress force so that, during use, the first and second reference surfaces are automatically brought into alignment with the opposite surfaces of the parts. adjacent.
    [3" id="c-fr-0003]
    The measuring device according to claim 1 or claim 2, wherein the elastic biasing structure applies a sufficient biasing force so that, during use, the first and second reference surfaces are engaged with the surfaces. opposite adjacent pieces with enough force to support essentially the entire weight of the device.
    [4" id="c-fr-0004]
    4. Measuring device according to any one of claims 1 to 3, in which the first blades are two in number, the first reference surfaces defined by the first blades being coplanar with one another. other.
    [5" id="c-fr-0005]
    5. Measuring device according to claim 4, in which a second blade is present and disposed centrally between the first two blades.
    [6" id="c-fr-0006]
    6. Measuring device according to any one of the preceding claims, in which each blade has a width of 3 mm or more.
    [7" id="c-fr-0007]
    7. Measuring device according to any one of the preceding claims, the device weighing from 20 g to 40 g, and the elastic biasing means applying a biasing force of at least 3 N.
    [8" id="c-fr-0008]
    8. Measuring device according to any one of the preceding claims, the device comprising a cursor attached for the purpose of linear displacement relative to the main body, the second blade or blades being fixedly attached to the cursor.
    [9" id="c-fr-0009]
    9. Measuring device according to claim 8, in which the electronic control means comprises a transducer structure used to generate a first signal proportional to the position / spacing of the cursor relative to the main body.
    [10" id="c-fr-0010]
    10. Measuring device according to any one of the preceding claims, in which the main body defines a third planar reference surface intended to come into contact with an external surface of a first part during use.
    [11" id="c-fr-0011]
    11. Measuring device according to claim 10, the device comprising a fastening structure intended to receive an additional measuring device used to measure the coplanarity of the external surfaces of the adjacent parts during use.
    [12" id="c-fr-0012]
    12. Measuring device according to claim 11, in which the fastening structure comprises a fastening element projecting in said first direction from an end of the main body beyond the first blade or blades so that that, in use, when the blades are placed in the space between opposite surfaces of first and second adjacent parts with the third reference surface in contact with an outer surface of a first of the adjacent parts, the element fastener extends above the outer surface of one second of the adjacent pieces.
    [13" id="c-fr-0013]
    13. Device according to claim 12, in which the attachment element defines a fourth reference at a predetermined distance from the third reference surface, measured perpendicular to the plane of the third reference surface.
    [14" id="c-fr-0014]
    14. Device according to claim 12 or claim 13, in which the attachment element defines an opening intended to receive a cursor from the additional measuring device during use.
    [15" id="c-fr-0015]
    15. Device according to any one of claims 12 to 14, wherein at least one magnet is integrated within the attachment element.
    1/7
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    同族专利:
    公开号 | 公开日
    GB2561366A|2018-10-17|
    GB2561366B|2021-09-29|
    DE202018101857U1|2018-07-12|
    GB201705816D0|2017-05-24|
    引用文献:
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    FR2994930B1|2012-09-04|2014-08-22|Peugeot Citroen Automobiles Sa|GUNGE WIDTH CONTROL TEMPLATE, BODY ELEMENT RETOUCHING TOOL COMPRISING SUCH A TEMPLATE, AND METHOD OF RETOUCHING A BODY COMPONENT.|
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    法律状态:
    2020-03-17| PLFP| Fee payment|Year of fee payment: 3 |
    2020-05-08| PLSC| Search report ready|Effective date: 20200508 |
    2021-03-31| PLFP| Fee payment|Year of fee payment: 4 |
    优先权:
    申请号 | 申请日 | 专利标题
    GB1705816.5A|GB2561366B|2017-04-11|2017-04-11|Gap measuring device and system|
    GB1705816.5|2017-04-11|
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