RU2175117C1 - Sensor for measurement of longitudinal force - Google Patents

Abstract

FIELD: measurement technology; conversion of mechanical magnitudes to electric signal. SUBSTANCE: sensor includes terminal force-sensing units 2 and 3 made integral with center sensing unit 4 separated from force-sensing units by two opposite transversal slots 5 and 6; sensor is also provided with resistance strain gage for measurement of deformation of sensing unit. Sensing unit is made in form of rectangular parallelepiped whose lateral faces adjoining transversal slots have of square (A, B, C, D). Parallelepiped has through cylindrical hole 9 in center of square which is perpendicular to longitudinal axis of sensor. Resistance strain gage is located inside through hole; this gage includes flexible measuring beam 11 with resistance strain gages 20 mounted perpendicularly relative to longitudinal axis of sensor and symmetrically relative to it; resistance strain gage includes also two supports which connect ends of measuring beam with inner wall of cylindrical holes in areas adjoining points E and F of intersection of diagonal of square lateral face with wall of above-mentioned hole. EFFECT: reduced measurement error; increased service life of sensor. 8 cl, 2 dwg

Description

 The invention relates to measuring technique and can be used in devices for protecting load-lifting machines and mechanisms from overloads, in high-precision tensometric scales, and also as a converter of mechanical quantities (pressure, displacement, deformation, force) into an electric signal in various industries.

 A known sensor for measuring forces, containing an elastic element in the form of a hollow cylinder having end and middle supporting parts connected by a cylindrical sensing element. Strain gages are installed on the inner surface of the cylindrical sensitive element and are connected to a control and measuring electronic threshold device (see patent of the Russian Federation N 2081809 C1, B 66 C 23/88, 06/20/1997). This sensor has insufficient sensitivity, since tolerances on the manufacture of a cylindrical sensitive element significantly affect the measurement accuracy.

Also known is a sensor for measuring forces, containing a sensitive element in the form of a bar, to which power-sensing parts are attached on both sides. A through cylindrical hole is made in the beam, the axis of which is perpendicular to the longitudinal axis of the beam and the direction of the measured force. The cylindrical hole has an annular partition symmetrically located relative to the longitudinal axis of the load. Strain gages are located on the inner cylindrical surface of the partition in areas offset 45 ^o relative to the longitudinal axis of the beam (see USSR author's certificate N 451928 A1, G 01 L 1/22, 11/30/1974). This arrangement of strain gauges makes it possible to record the maximum tensile and compression stresses on the wall of the hole in the partition. The error in measuring the force substantially depends on the size of the strain gauge, the accuracy of its fixing relative to the zone of maximum tensile and compression stresses, and the quality of gluing the strain gauge to the wall of the hole. The elastic properties of the adhesive joint are significantly dependent on temperature and deteriorate over time, which also increases the measurement error of the force.

Closest to the claimed invention in terms of essential features is a sensor for measuring longitudinal forces, containing end force-sensing parts made in one piece with the middle sensitive part, separated from the power-sensing parts by two counter transverse slots, and a strain gauge device for measuring the deformation of the sensitive part. Slots are made up to the axis of symmetry of the sensor. For the formation of the sensitive part on the side surfaces of the middle part of the sensor at an angle of 45 ^o made two grooves. The power-receiving end parts have wedge-shaped endings with a wedge angle of 45 ^o , and the sensitive part is made in the form of an oblique platform located between the wedge-shaped ends. Strain gages are fixed on both sides of the oblique platform (see USSR author's certificate N 1696915 A1, G 01 L 1/22, 01/09/1991). The presence of an oblique pad ensures equal deformations along the entire cross section of the sensitive part and the same transverse stiffness along its length, which allows to reduce the error of the force measurement when the point of application of external force is displaced relative to the axis of symmetry of the sensor, and also ensures the independence of the measurement results from the dimensions of the strain gauge and its specific place of gluing on an oblique area of the sensitive part. However, the full realization of the advantages of a slanting platform will be determined by the accuracy of its manufacture and will substantially depend on the technological capabilities of the manufacturer, in particular, on the availability of a tool for forming a slanting platform. In this invention, the influence on the accuracy of measuring the force of the elastic characteristics of the adhesive joint remains, which increases the error in measuring the force with temperature and with a long sensor life. The most significant change in the characteristics of the adhesive joint occurs with cyclic changes in temperature in the range from -50 to +50 ^o C, which limits the use of this invention in devices operating outdoors (outdoors).

The problem to which the invention is directed is to create a sensor for measuring longitudinal forces with increased measurement accuracy, including when the point of application of force is displaced relative to the axis of the sensor, capable of maintaining increased measurement accuracy over the entire life cycle when the ambient temperature changes from -50 to +50 ^o C. Another objective of the invention is the creation of a high-precision sensor for measuring longitudinal forces with high manufacturability.

 The stated technical problems are solved by the fact that in the known sensor for measuring longitudinal forces, containing end force-sensing parts made in one piece with the middle sensitive part, separated from the power-sensing parts by two counter transverse slots, and a strain gauge device for measuring the deformation of the sensitive part, according to the invention, the sensitive part is made in the form of a rectangular parallelepiped, the side faces of which are adjacent to the transverse slots, have the shape of a quad at, in the parallelepiped in the center of the square there is a through cylindrical hole perpendicular to the longitudinal axis of the sensor, and the strain gauge device is located inside the through hole in the plane of longitudinal symmetry of the sensor and includes an elastic measuring beam with strain gauges installed perpendicular to the longitudinal axis of the sensor and symmetrically relative to it, and two supports connecting the ends of the measuring beam with the inner wall of the cylindrical hole in the areas adjacent to the points of intersection of agonals of a square lateral face with the wall of the indicated hole.

 In addition, the first support is made in the form of a protrusion on the inner wall of the cylindrical hole in the area adjacent to the point of intersection with the diagonal of the square side face, and the first end of the measuring beam is mounted directly on the specified protrusion, and the second support is made in the form of a protrusion on the inner wall of the cylindrical hole in the area adjacent to the diametrically opposite point of intersection of the diagonal of the square side face with the inner wall of the hole, and a power transmitting device connecting a protrusion with a second end of the measurement ravine.

 The power transmitting device can be made in the form of a platform and two tape rods connecting the platform with a protrusion.

 In addition, an additional protrusion is made on the inner surface of the wall of the cylindrical hole for mounting the circuit board of the terminals of the strain gauges, and in the wall of the cylindrical hole adjacent to the protrusion, a through hole is made for the hermetic leads of the wiring of the circuit board, while in the opposite wall of the cylindrical hole there is a compensating hole closed by a sealing a stub.

 The protrusions on the inner surface of the cylindrical hole and the power transmitting device, it is advisable to perform in one piece with the middle sensitive part.

 It is advisable to close the cylindrical through hole in the sensitive part of the sensor on both sides with sealing plugs.

 The measuring beam can be made of single-crystal silicon.

 The essence of the invention lies in the fact that the manufacture of the sensitive part of the sensor in the form of a rectangular parallelepiped, the side faces of which are adjacent to the transverse slots, have the shape of a square, and the execution in the parallelepiped in the center of the square of a through cylindrical hole perpendicular to the longitudinal axis of the sensor forms a symmetrical power circuit of the middle sensitive part, deforming similarly to the Roberval parallelogram, as a result of which, when loading with measured force, its opposite angles fragments are displaced parallel to each other, and the resultant force always passes through the center of the through cylindrical holes. The location of the strain gauge device inside the through hole in the plane of the longitudinal symmetry of the sensor and the inclusion of an elastic measuring beam with strain gauges mounted perpendicular to the longitudinal axis of the sensor and symmetrical about it, with the fastening of its ends to zones adjacent to the intersection points of the diagonal of the square side face with the inner wall a cylindrical hole, allows you to fully use the advantages of the proposed design of the middle sensitive part for eniya accuracy of measurement applied force, in particular, by increasing the base on which the measurement of the strain sensitive. This eliminates the influence on the accuracy of measuring the force of the elastic properties of the adhesive joint of the measuring beam with supports, since the force is transmitted to the measuring beam through normal stresses.

 The claimed design of the supports of the measuring beam and the power-transmitting device eliminates the bending of the end portion of the measuring beam, which ensures the invariable nature of the deformation of the measuring beam when loading the sensor with measured force, and also eliminates the possibility of destruction of the measuring beam when the external temperature changes, including during storage and operation of the sensor in unheated the premises.

 The execution of an additional protrusion on the inner surface of the wall of the cylindrical hole for mounting the circuit board of the terminals of the strain gauges and the through hole for the pressure leads of the circuit board in the sensitive part wall adjacent to the specified protrusion simplifies the installation of the measuring beam and makes the sensor more technological.

 The implementation in the opposite wall of the cylindrical hole of the compensating hole, closed with a sealing plug, maintains the symmetry of the sensitive part relative to the diagonal of the square side face and improves the accuracy of the measurement of force.

 The implementation of the power-transmitting device and the protrusions on the inner surface of the cylindrical hole in one piece with the middle sensitive part makes it more technological.

 Sealing a cylindrical hole protects the measuring beam and circuit board from the effects of the external environment and ensures that the characteristics of the sensor remain constant throughout its life.

 The implementation of a measuring beam made of single-crystal silicon reduces temperature errors in the measurement of longitudinal forces and increases the manufacturability of the sensor, since the sensor element that is the most vulnerable from the point of view of technology (measuring beam with strain gauges) can be manufactured and tested separately from the sensitive part of the sensor.

 The technical result from the use of the invention is to reduce the error in measuring forces and increase the life of the sensor.

 In FIG. 1 shows the proposed sensor without sealing plugs, General view; in FIG. 2 is a section I-I in FIG. 1.

 The sensor for measuring longitudinal forces comprises a housing 1 in the form of a rectangular parallelepiped having end force-sensing parts 2 and 3, made in one piece with the middle sensitive part 4, separated from the power-sensing parts by two counter transverse slots 5 and 6.

 The sensitive part 4 also has the shape of a rectangular parallelepiped. Its lateral faces 7 and 8, adjacent to the transverse slots 5 and 6, have the shape of a square ABCD. In the sensitive part 4, a through cylindrical hole 9 is made in the center of the square, perpendicular to the longitudinal axis of the sensor. In the power-sensing parts 2 and 3, threaded holes 10 are made for attaching to the sensor elements transmitting the measured force.

 The sensor has a strain gauge device for measuring the deformation of the sensitive part 4. The device contains an elastic measuring beam 11 with thinning 12 and two supports 13 and 14 located in the plane of longitudinal symmetry of the sensor, connecting the ends of the measuring beam with the inner wall of the cylindrical hole 9 in areas adjacent to points E and F is the intersection of the diagonal of the speaker with the wall of the hole 9. The measuring beam 11 is placed perpendicular to the longitudinal axis of the sensor and symmetrically relative to it.

 The first support 13 is a cantilevered protrusion 15 on the inner wall of the cylindrical hole in the area adjacent to point E. The first end of the measuring beam 11 is fixed directly to the site of the protrusion 15, for example, with glue. The second support 14 has a protrusion 16 on the inner wall of the cylindrical hole in the area adjacent to the diametrically opposite point F, and a power transmitting device 17 including a platform 18 and two tape rods 19 connecting the platform 18 with the protrusion 16. The second end of the measuring beam is fixed to platform 18, for example, with glue. The measuring beam 8 is made of monocrystalline silicon with diffusion strain gages 20 formed on it on loaded surfaces in the thinning zone 12. The strain gages 20 are combined into a four-arm active bridge circuit.

 On the inner surface of the wall of the cylindrical hole 9 in the plane of longitudinal symmetry of the sensor, an additional protrusion 21 is made for mounting the mounting plate 22 of the terminals of the strain gauges 20. In the adjacent wall of the protrusion 21 of the hole 9, a through hole 23 is made for the pressure leads 24 of the wiring harness. In the opposite wall of the hole 9, a compensating hole 25 is made, closed with a sealing plug 26.

 The protrusions 15, 16, 21 on the inner surface of the cylindrical hole and the power transmitting device 17 are made integral with the middle sensitive part 4. The cylindrical through hole 9 is closed on both sides with sealing plugs 27.

 The proposed sensor operates as follows.

 When the sensor is loaded with a measured tensile force P, the force-sensing parts 2 and 3 transmit the indicated force to the middle sensitive part 4, which is deformed by the specified force. The deformation of the middle part leads to a shift relative to each other of the points E and F of the intersection of the AC diagonal with the wall of the cylindrical hole 9. The offset of points E and F is transmitted to the measuring beam 11. The measuring beam 11 is bent and its deformation is transmitted to the strain gauges 20. The strain gauges change their resistance, there is an imbalance of the active bridge and on its measuring diagonal there is a voltage measured by the information-measuring unit. The displacement of the force P relative to the nominal position does not lead to the appearance of additional bending moments on the middle sensitive part, since the shoulder forces acting on the middle sensitive part remain unchanged.

 If the temperature changes during operation of the sensor, the temperature deformation of the measuring beam 11 will differ from similar deformations of the middle sensitive part 4. The difference in temperature deformations will lead to some bending of the measuring beam 11, which can be taken into account when restoring zero at the beginning of the measurement and will not lead to a deterioration in accuracy force measurements.

 The claimed invention can be manufactured industrially using modern materials and technologies, which confirms its industrial applicability.

Claims (8)

 1. The sensor for measuring longitudinal forces, containing the end force-sensing parts made in one piece with the middle sensitive part, separated from the power-sensing parts by two counter transverse slots, and a strain gauge device for measuring the deformation of the sensitive part, characterized in that the sensitive part is made in the form of a rectangular a parallelepiped, the side faces of which are adjacent to the transverse slots, have the shape of a square, in the parallelepiped in the center of the square there is a through a cylindrical hole perpendicular to the longitudinal axis of the sensor, and the strain gauge device is located inside the through hole and includes an elastic measuring beam with strain gauges installed perpendicular to the longitudinal axis of the sensor and symmetrical about it, and two supports connecting the ends of the measuring beam with the inner wall of the cylindrical hole in the zones adjacent to the intersection points of the diagonal of the square side face with the wall of the specified hole.  2. The sensor according to claim 1, characterized in that the first support is made in the form of a protrusion on the inner wall of the cylindrical hole in the area adjacent to the point of intersection of its diagonal square side face, and the first end of the measuring beam is mounted directly on the specified protrusion, and the second support made in the form of a protrusion on the inner wall of the cylindrical hole in the area adjacent to the diametrically opposite point of intersection of the diagonal of the square side face with the inner wall of the hole, and a power-transmitting device a connecting said protrusion with the second end of the measuring beam.  3. The sensor according to claim 2, characterized in that the power transmitting device is made in the form of a platform and two tape rods connecting the platform with the protrusion.  4. The sensor according to claim 1, characterized in that on the inner surface of the wall of the cylindrical hole there is an additional protrusion for mounting the circuit board of the terminals of the strain gauges, and in the adjacent wall of the protrusion of the cylindrical hole there is a through hole for the pressure leads of the wiring of the circuit board.  5. The sensor according to claim 4, characterized in that in the opposite wall of the cylindrical hole there is a compensating hole closed by a sealing plug.  6. The sensor according to claim 4, characterized in that the protrusions on the inner surface of the cylindrical hole and the power transmitting device are made in one piece with the middle sensitive part.  7. The sensor according to any one of claims 1 to 6, characterized in that the cylindrical hole is closed on both sides by sealing plugs.  8. The sensor according to claim 1, characterized in that the measuring beam is made of monocrystalline silicon.

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