JP5275507B1 - Strain body and weight measuring device - Google Patents

Abstract

The present invention provides a strain generating body that can be miniaturized, ensure mechanical strength, and have high dimensional accuracy in thickness and width.
A strain generating body that is used in a load cell for measuring a weight and deforms when a load is transmitted is formed by powder metallurgy. The strain body has a line-symmetric shape and a uniform thickness, is arranged in the center and extends in the same direction as the symmetry axis, and has a rectangular strain region having one end and the other end, and is parallel to the symmetry axis. Two first arm portions that extend, a first connection portion that extends in a direction transverse to the axis of symmetry and is connected to one end of the strain region and the first arm portion, and closer to the strain region than the first arm portion Two second arm portions arranged and extending parallel to the symmetry axis, and a second connection portion extending in a direction crossing the symmetry axis and connected to the other end of the strain region and the second arm portion, One of the pair of one arm part and the pair of the second arm part receives a load in the vertical direction with respect to the strain body, and the other of the pair of the first arm part and the second arm part is a support body. It is comprised so that it may be fixed to.
[Selection] Figure 9

Description

  The present invention relates to a strain generating body that is used in a load cell for measuring weight and deforms when a load is transmitted thereto, and a weight measuring device having the strain generating body.

  A weight measuring device, for example a scale, has at least one load cell through which a load applied to the platform is transmitted. The load cell has a strain body deformed by a load and a plurality of strain gauges attached to the strain body. Patent Literature 1 discloses such a strain generating body.

Japanese Patent No. 2977278

  The strain generating body is made of a high-strength metal and is generally formed by punching with high mass productivity. However, in the punching process, since the width of the punched portion needs to be equal to or greater than the thickness, there is a restriction that the size of the strain generating body that can be manufactured becomes large. In addition, it is difficult to create a complicated shape such as a small gap. In order to reduce the strain body that can be manufactured by punching or create a complicated shape, it is possible to make the strain body thin or to use a low-strength metal material. The mechanical strength of is reduced. In punching, since it is a high-strength metal material, sagging, fractured surfaces, and burrs are generated in the punched section, and it is difficult to make the thickness and width of the strain generating body uniform. The accuracy of weighing is limited.

  Therefore, the present invention provides a strain generating body that can be reduced in size, ensure mechanical strength, and have high dimensional accuracy in thickness and width, and a weight measuring device having the strain generating body.

  The strain body according to the present invention is a strain body that is used in a load cell for measuring weight and deforms when a load is transmitted, and is formed by powder metallurgy. In the present invention, since the strain body is formed by powder metallurgy, the strain body can be reduced in size and mechanical strength can be ensured. Further, since the dimensional accuracy of the thickness and width of the strain generating body is high, the accuracy of load cell weight measurement is improved.

Oite the present invention, the strain body is used to the load cell measuring the weight, a strain body which load is deformed is transmitted, while being formed by powder metallurgy, uniform axisymmetrical shape A rectangular strain region having one end and the other end disposed in the center and extending in the same direction as the symmetry axis, two first arm portions extending in parallel with the symmetry axis, A first connecting portion extending in a direction crossing a symmetry axis and connected to the one end of the strain region and the first arm portion; and the symmetry axis disposed closer to the strain region than the first arm portion. Two second arm portions extending in parallel with each other, and a second connecting portion extending in a direction crossing the axis of symmetry and connected to the other end of the strain region and the second arm portion, One of the first arm pair and the second arm pair receives a load in a direction perpendicular to the strain body, The other of the first arm portion pair and the second arm portion pair is configured to be fixed to a support, and the distance between the first arm portion and the second arm portion, and An interval between the second arm portion and the strain region is not more than half of the thickness.

In the present invention , an interval between the first arm portion and the second arm portion, and an interval between the second arm portion and the strain region are not more than half of the thickness. By reducing these intervals, the strain generating body can be reduced in size. For high-strength metal materials suitable for strain-generating bodies, these distances can be made only as large as the thickness of the strain-generating body by punching, and cannot be made narrower than that. It is possible to reduce the size of the strain body by reducing the thickness.
In the present invention , the strain body may be obtained by pressing and sintering a metal powder, or may be obtained by a metal powder injection molding method. That is, in the first aspect, the powder metallurgy technique may be press-molding and sintering metal powder, or metal powder injection molding.

  Preferably, the length of each of the first arm portions in the direction perpendicular to the symmetry axis of the strain generating body is equal to 1 of the length of the strain region in the direction crossing the symmetry axis of the strain generating body. 3 times or more. A first through hole is formed in each of the first arm portions, and it is possible to screw to other parts using these through holes. If the distance between the outer side surfaces of the two first arm portions is large, the residual stress in the first arm portion due to the tightening torque generated when the screws are fastened can be reduced. Since this residual stress adversely affects the accuracy of load cell weight measurement, it is desirable that the residual stress be small. The length of each of the first arm portions in the direction perpendicular to the symmetry axis of the strain body is 1.3 times or more of the length of the strain region in the direction across the symmetry axis of the strain body. If so, the residual stress can be reduced and the accuracy of the load cell weight measurement can be improved.

  Preferably, the length of the first connecting portion in the direction parallel to the symmetry axis of the strain body is 1.4 times the length of the strain region in the direction crossing the symmetry axis of the strain body. . A first through hole is formed in each of the first arm portions, and it is possible to screw to other parts using these through holes. If the length of the first connecting portion in the direction parallel to the symmetry axis is large, the residual stress in the first arm portion due to the tightening torque generated when the screw is fastened can be reduced. Since this residual stress adversely affects the accuracy of load cell weight measurement, it is desirable that the residual stress be small. If the length of the first connecting portion in the direction parallel to the symmetry axis of the strain body is not less than 1.4 times the length of the strain region in the direction crossing the symmetry axis of the strain body, Residual stress is reduced, and the accuracy of load cell weight measurement can be improved.

  A second through hole may be formed in each of the second arm portions.

  The weight measuring device according to the present invention includes a load cell including the strain body and a plurality of strain gauges attached to the strain body and generating a signal corresponding to the deformation of the strain body.

It is the perspective view which looked at the weight measuring device which concerns on embodiment of this invention from diagonally upward. It is the perspective view which looked at the weight measuring apparatus of FIG. 1 from diagonally downward. It is a top view of the weight measuring apparatus of FIG. It is a top view which shows the load cell assembly in the weight measuring apparatus of FIG. FIG. 3 is a perspective view of the load cell assembly disassembled. It is a top view which shows the load transmission member in the said load cell assembly. It is the perspective view which looked at the said load transmission member from the bottom. It is the perspective view which looked at the strain body in the said load cell assembly from diagonally upward. It is a bottom view of the strain body. It is the bottom view of the said load transmission member couple | bonded and the said strain body. It is a top view which shows the said distortion body and bridge | bridging combined. It is a top view which shows the said bridge | bridging. FIG. 12 is a side view of the strain generating body and the bridge of FIG. It is a top view which shows the leg in the said load cell assembly, and an elastic support member. It is a perspective view of the leg and the elastic support member. It is a top view of the said elastic support member. It is a top view of the said leg. It is a bottom view of the leg. It is a front view of the said leg. It is a side view of the said leg. It is a side view of the load cell in the load cell assembly. FIG. 4 is a cross-sectional view taken along line XXI-XXI in FIG. 3. It is a table | surface which shows the experimental result which investigated the relationship between the hardness of the said elastic support member, and the durability of the said load cell assembly. It is a graph which shows the experimental result which investigated the relationship between the hardness of the said elastic support member, and a weight measurement error. It is a figure which shows the stress distribution which generate | occur | produces in the said strain body at the time of a weight measurement. It is a perspective view which shows the carpet leg which can be attached to the said leg. It is sectional drawing of the weight measuring apparatus which concerns on other embodiment. It is a graph which shows the experimental result which investigated the relationship between the dimension of the said strain body and the weight measurement error. It is a graph which shows the experimental result which investigated the relationship between the dimension of the said strain body and the weight measurement error. It is a graph which shows the experimental result which investigated the relationship between the dimension of the said strain body and the weight measurement error.

Embodiments according to the present invention will be described below with reference to the accompanying drawings.
1 and 2 show a weight measuring apparatus according to an embodiment of the present invention. The weight measuring device 1 is a body scale that measures the weight of a human and a body composition meter that measures a body composition such as a human body fat percentage. The weight measuring device 1 includes a housing 11, and the housing 11 includes a platform 12 and a base 15 fixed to the platform 12. As shown in FIG. 1, the platform 12 has a substantially flat top surface that is oriented to spread horizontally when weighing. A human stands upright on the upper surface of the platform 12. That is, an object is placed on the platform 12 and a load is applied to the object.

  As shown in FIG. 2, the base 15 is substantially rectangular and is made of a rigid material such as stainless steel or resin. Legs 16 are arranged at the four corners of the bottom surface of the base 15. When measuring the weight, these legs 16 are brought into contact with the floor. Another part may be interposed between the leg 16 and the floor. The leg 16 is a support member that supports the weight measuring device 1 and also a leg of a load cell to be described later. At the time of weight measurement, the entire casing 11 including the platform 12 and the base 15 is displaced according to the weight on the platform 12 with respect to the legs 16 supported on the floor.

  A power switch 17 that activates the weight measuring device 1 is attached to the housing 11, and the power switch 17 protrudes from the side surface of the platform 12. Since the weight measuring device 1 is used as a body composition meter, a plurality of electrode plates 18 are provided on the upper surface of the platform 12 as shown in FIG. These electrode plates 18 are used for measuring the bioelectrical impedance of the subject. These electrode plates 18 are stepped on with both feet of the subject on the platform 12.

  FIG. 3 is a plan view of the weight measuring apparatus 1, and the illustration of the electrode plate 18 is omitted in FIG. As shown in FIG. 3, the platform 12 includes a box-shaped inner cover 13 formed of a rigid metal material such as steel, and an outer cover 14 formed of resin disposed outside the inner cover 13. With. The outer cover 14 is an exterior of the platform 12 and insulates the inner cover 13 and the electrode plate 18 made of metal.

  The weight measuring device 1 includes a handle unit 19. The handle unit 19 is connected to the housing 11 via a cable (not shown). The handle unit 19 includes a central operation box 20 and grips 21 and 22 extending on both sides of the operation box 20. The operation box 20 is provided with a display 23 for displaying the weight and body composition of the subject and operation buttons 24 and 25. Each of the grips 21 and 22 is provided with an electrode used for measuring the bioelectrical impedance of the subject. These electrodes are grasped with both hands of the subject on the platform 12. Although the weight measuring apparatus 1 according to the embodiment is also used as a body composition meter, the electrode plate 18 and the handle unit 19 are not necessarily required because the present invention relates to weight measurement.

  As shown in FIG. 3, the inner cover 13 of the platform 12 defines a receiving space 27 with a base 15 connected to the platform 12. In the housing space 27, four load cell assemblies 30 for measuring the weight are arranged. However, the legs 16 of the load cell assembly 30 protrude downward from the base 15 as shown in FIG.

  A substrate 28 on which a processing circuit for processing a signal supplied from a strain gauge of the load cell assembly 30 is mounted is disposed inside the accommodation space 27. The substrate 28 and the strain gauge are connected by a cable 29. The processing circuitry on the substrate 28 calculates the weight of the subject based on the signal supplied from the strain gauge of the load cell assembly 30. The processing circuit on the substrate 28 is electrically connected to the electrode plate 18 of the platform 12 and the electrode of the handle unit 19, and based on the subject's weight and changes in bioelectrical impedance at various locations, the subject's body composition Calculate The calculated weight and body composition are displayed on the display 23.

  As shown in FIGS. 4 and 5, each load cell assembly 30 includes a load transmission member (load cell holder) 32 and a load cell 34. The load transmission member 32 is made of a hard material such as resin. The load transmission member 32 covers the load cell 34 and is detachably attached to the load cell 34. The load transmitting member 32 is detachably attached to the inner cover 13 of the platform 12. The load transmission member 32 transmits the load transmitted from the platform 12 to the strain body 36 of the load cell 34.

  As shown in FIG. 5, the load cell 34 includes a strain generating body 36 that is deformed when a load is transmitted from the platform 12, a plurality of strain gauges 38 attached to the strain generating body 36, and a bridge that supports the strain generating body 36. 40 and a leg 16 that supports the bridge 40. More precisely, the bridge 40 is supported by the elastic support member 42 (FIGS. 14 and 15), and the elastic support member 42 is supported by the legs 16, but the elastic support member 42 does not appear in FIG. The cable 29 of the strain gauge 38 is bonded to the strain body 36 with a tape 50.

  As shown in the perspective view seen from diagonally above in FIG. 8 and the bottom view in FIG. 9, the strain body 36 is a single member having a line-symmetric shape and a uniform thickness. The strain body 36 is formed of a plate material having a high rigidity such as carbon tool steel. The strain body 36 includes a strain region 361 disposed in the center, two first arm portions 362, two second arm portions 364, and a first region that connects the strain region 361 and the first arm portion 362. A connection portion 363 and a second connection portion 365 that connects the strain region 361 and the second arm portion 364 are provided.

  The strain region 361 is a rectangular portion extending in the same direction as the symmetry axis of the strain body 36 and having one end 361a and the other end 361b. The strain region 361 is a region that is most deformed by a load transmitted from the platform 12 via the load transmitting member 32. A strain gauge 38 is attached to the strain region 361 (see FIG. 5). On the upper surface of the strain region 361, a mark 368 serving as a guide for attaching the strain gauge 38 is provided.

  The two first arm portions 362 extend in parallel with the symmetry axis of the strain body 36. The first connecting portion 363 extends in a direction perpendicular to the symmetry axis of the strain generating body 361 and is connected to one end 361 a of the strain region 361 and both the first arm portions 362.

  The two second arm portions 364 are disposed closer to the strain region 361 than the first arm portion 362 and extend parallel to the symmetry axis of the strain body 361. The second connecting portion 365 extends in a direction perpendicularly crossing the symmetry axis of the strain generating body 361 and is connected to the other end 361 b of the strain region 361 and the second arm portion 364.

  One end portion of each of the first arm portions 362 is formed in a semicircular shape, and a circular first through hole 366 is formed in this end portion. One end portion of each of the second arm portions 364 is also formed in a semicircular shape, and a circular second through hole 367 is formed at this end portion. The central axes of the first through hole 366 and the second through hole 367 are arranged on a straight line that perpendicularly intersects the axis of symmetry of the strain generating body 36. The strain generating body 36 has a substantially J-shaped groove 369 and a substantially J-shaped symmetrical groove 369 on both sides of the strain area 361, and each groove 369 includes the strain area 361, the first arm portion 362, and the first arm 362. It is surrounded by the connecting portion 363, the second arm portion 364, and the second connecting portion 365.

  In a state where the second arm portion 364 is supported by a support body (bridge 40 to be described later) disposed below the strain body 36, the load transmitting member 32 concentrates a downward load in the vertical direction from above. The distortion region 361 is deformed by being given to the one arm portion 362 (curved in an S shape when viewed from the side, that is, the direction parallel to the paper surface of FIG. 9). The strain gauge 38 generates a signal corresponding to the deformation of the strain region 361 of the strain generating body 36.

  In this embodiment, a downward load in the vertical direction is applied to the first arm portion 362 intensively from above by the load transmitting member 32. The second arm portion 364 is fixed to a support body (a bridge 40 described later) disposed below the strain body 36. However, the strain body 36 itself is not limited to such an application, but a vertical load is applied to the second arm portion 364 so that the first arm portion 362 is fixed to the support body. In addition, the strain body 36 may be used. That is, one of the pair of the first arm part 362 and the pair of the second arm part 364 receives a load in the vertical direction with respect to the strain body 36, and the pair of the first arm part 362 and the second arm part 364. The other of the pair is configured to be fixed to the support. In any case, the strain generating body 36 is used in such a manner that the strain region 361 is greatly curved in an S shape.

  As shown in FIGS. 4 to 6, the load transmitting member 32 includes an octagonal upper wall 321. The upper wall 321 contacts the inner cover 13 (FIG. 3) of the platform 12. A plurality of protrusions 322, 323, 324, and 325 are formed on the upper surface of the upper wall 321. These protrusions 322, 323, 324, and 325 are hooked into holes (not shown) formed in the inner cover 13. In this way, the load transmission member 32 is detachably attached to the inner cover 13 of the platform 12. The upper wall 321 is disposed in parallel to the upper surface of the platform 12. The upper wall 321 covers the entire strain body 36.

  As shown in FIGS. 5, 7, and 10, the load transmission member 32 includes two side walls 326 that extend downward from the upper wall 321. As shown in the bottom view of FIG. 10, each of the side walls 326 includes a lower region 327 that faces the first arm portion 362 of the strain body 36. Each of the lower regions 327 faces a flat lower contact surface 327a that comes into surface contact with a part of the first arm portion 362 of the strain-generating body 36, and does not contact the first arm portion 362 of the strain-generating body 36. And a flat lower non-contact surface 327b. The lower contact surface 327 a and the lower non-contact surface 327 b extend in parallel with the symmetry axis of the strain body 36. Further, the lower contact surface 327a and the lower non-contact surface 327b are arranged in parallel to the upper wall 321 and thus the upper surface of the platform 12, and are thus directed to spread horizontally during weight measurement. A step is provided between the lower contact surface 327a and the lower non-contact surface 327b.

  As shown in the bottom view of FIG. 10, each of the first arm portions 362 of the strain body 36 has a first through hole 366 that is oriented so that the axis extends in the vertical direction during weight measurement. Each lower region 327 of the side wall 326 of the load transmitting member 32 is provided with a protrusion 328 that is inserted into the first through hole 366. The lower contact surface 327a also extends around the protrusion 328. The load transmission member 32 further includes two outer side walls 329 disposed outside the two side walls 326 and extending in parallel with the two side walls 326, and the outer side wall 329 includes a first arm portion of the strain body 36. A hook 330 on which 362 is hung is formed.

  As shown in FIG. 7, the load transmission member 32 further includes an end wall 331 that connects the two side walls 326. A notch 332 is formed in the end wall 331, and the cable 29 of the strain gauge 38 is passed through the notch 332 (FIG. 5).

  As shown in FIGS. 11 and 13, the strain body 36 is fixed to and supported by the bridge 40. The bridge 40 is a single member formed from a rigid material such as steel. As shown in FIGS. 12 and 13, the bridge 40 is a substantially uniform thickness plate having an approximately octagonal outline, and has a substantially flat upper surface 401 and a substantially flat lower surface 402. The upper surface 401 and the lower surface 402 are oriented so as to spread horizontally during weight measurement.

  The bridge 40 is formed with bosses 403 having a circular outline at two locations. The boss 403 can be formed by pressing, for example. The surfaces of the two bosses 403 are substantially flat and are in contact with the lower surface of the strain generating body 36 (the surface on which the strain gauge 38 is not attached). A through hole 404 is formed in the center of each boss 403.

  The two through holes 404 of the bridge 40 are respectively overlapped with the two second through holes 367 of the strain body 36, and the rivet 410 passes through the through hole 404 and the second through hole 367. The strain body 36 and the bridge 40 are fixed by two rivets 410. As shown in FIG. 13, in the present embodiment, one end of the rivet 410 protrudes from the upper surface of the strain body 36, and the other head of the rivet 410 is in the space behind the boss 403 of the bridge 40. The bridge 40 is not protruded from the lower surface 402. If the protruding amount of the rivet 410 is sufficiently small, the elastic support member 42 described later is in close contact with the lower surface 402 of the bridge 40 without being broken or deformed by the rivet 410.

  The boss 403 of the bridge 40 serves as a spacer that secures a space between the strain body 36 and the upper surface 401 of the bridge 40. That is, even if the strain body 36 is deformed, the first connecting portion 363 of the strain body 36 is prevented from hitting the upper surface 401 of the bridge 40.

  The bridge 40 is formed with oval through holes 406 and 407. The through holes 406 and 407 are used for attachment to the legs 16 described later.

  The bridge 40 is supported by an elastic support member 42 shown in FIGS. 14 and 15, and the elastic support member 42 is supported by the legs 16. The elastic support member 42 is a single member made of rubber. As shown in FIGS. 14 to 16, the elastic support member 42 includes an upper part 421 having a substantially rectangular parallelepiped shape and arcuate ends in the longitudinal direction, and a lower part 422 having a substantially rectangular parallelepiped shape and arcuate ends in the longitudinal direction. With. The length of the upper portion 421 in the longitudinal direction is larger than that of the lower portion 422, and the width of the upper portion 421 is smaller than that of the lower portion 422.

  In this embodiment, the upper surface of the elastic support member 42 is substantially flat. However, the upper surface of the elastic support member 42 may be arcuate, or the upper surface may be uneven. The lower surface 402 of the bridge 40 is in close contact with the upper surface of the elastic support member 42. The bridge 40 is disposed with respect to the elastic support member 42 so that the two rivets 410 are aligned in the longitudinal direction of the elastic support member 42. A lower portion 422 of the elastic support member 42 is fitted into the leg 16, and the elastic support member 42 is supported by the leg 16.

  As shown in FIGS. 14, 15, and 17 to 20, the leg 16 includes a columnar leg main body 161 and a ring-shaped edge 164 disposed around the leg main body 161. A bridge 40 is placed on the leg body 161. A concave portion 162 is formed on the upper surface of the leg main body 161, and a portion into which the lower portion 422 of the elastic support member 42 is fitted is formed in the concave portion 162. As shown in FIG. 17, a plurality of substantially rectangular long holes 163 are formed on the lower surface of the concave portion 162, and a lattice-like pattern appears on the lower surface of the concave portion 162 because of these long holes 163. Further, the leg body 161 is placed and supported on the floor such that the lower surface thereof is in direct contact with the floor. However, another part (for example, a carpet leg to be described later) may be interposed between the leg body 161 and the floor. The leg 16 is a single member made of resin, for example.

  As shown in FIGS. 14, 15, 17, and 18, the leg main body 161 and the edge portion 164 are coupled by four curved elastic coupling portions 165, 166, 167, and 168. The elastic connecting portions 165, 166, 167, and 168 are arranged at an angular interval of about 90 degrees, and each of the elastic connecting portions 165, 166, 167, and 168 is connected to the inner periphery of the edge portion 164. It has a vertically long S-shaped outer part and an inner part on an arc plate connected to the outer periphery of the upper end of the leg main body 161. The elastic connecting portions 165, 166, 167, and 168 are formed thin and thin. In particular, among the elastic coupling portions 165, 166, 167, 168, the vertically long S-shaped outer portions 165a, 166a, 167a, 168a close to the edge portion 164 are formed on the inner portions 165b, 166b, It is thinner and thinner than 167b and 168b. Therefore, the elastic connecting portions 165, 166, 167, and 168, particularly the outer portions 165a, 166a, 167a, and 168a, have extremely high flexibility. In the present embodiment, the elastic coupling portions 165, 166, 167, and 168 have a curved shape, but are not necessarily limited to this, and may be, for example, a linear shape.

  The leg 16 has two first protrusions 170 and 171 that protrude inward from the edge portion 164. Further, the leg 16 is integrally connected to the inner side portion 165b of the elastic connecting portion 165, a second protrusion 172 protruding from the elastic connecting portion 165 in the circumferential direction around the axis of the leg main body 161, and the elastic connecting portion 166. A second protrusion 173 that is integrally connected to the inner portion 166b and protrudes from the elastic connecting portion 166 in the circumferential direction around the axis of the leg body 161, and an elastic connecting portion that is integrally connected to the inner portion 167b of the elastic connecting portion 167. A second protrusion 174 projecting in the circumferential direction centering on the axis of the leg main body 161 from 167 and an inner portion 168b of the elastic connecting portion 168 are integrally connected and centered on the axis of the leg main body 161 from the elastic connecting portion 168 And a second protrusion 175 protruding in the circumferential direction. The first protrusion 170 is between the second protrusions 172 and 173, and the second protrusions 172 and 173 are adjacent to the first protrusion 170 in the circumferential direction centering on the axis of the leg main body 161. The first protrusion 171 is between the second protrusions 174 and 175, and the second protrusions 174 and 175 are adjacent to the first protrusion 171 in the circumferential direction centering on the axis of the leg main body 161. The first protrusions 170, 171 and the second protrusions 172, 173, 174, 175 serve as detents that restrict relative rotation of the leg body 161 with respect to the edge portion 164.

  A bridge 40 is attached to the edge portion 164 of the leg 16. The first protrusions 170 and 171 formed on the edge portion 164 are provided with convex portions 180 and 181 that are cylindrical and protrude upward. As shown in FIG. 5, the convex portions 180 and 181 are inserted into the through holes 406 and 407 of the bridge 40. Further, hooks 182 and 183 are formed on the edge portion 164 of the leg 16, and the hooks 182 and 183 restrict the bridge 40 from moving upward. Therefore, the vertical movement and horizontal movement (linear movement and rotational movement) of the bridge 40 relative to the edge portion 164 of the leg 16 are limited. In other words, the relative vertical movement and horizontal movement (linear movement and rotational movement) of the edge 164 with respect to the bridge 40 are restricted.

  FIG. 22 is a cross-sectional view of the periphery of one load cell assembly 30 of the weight measuring apparatus 1. In FIG. 22, an arrow indicates a load. The load applied to the outer cover 14 of the platform 12 is transmitted to the strain generating body 36 through the inner cover 13 and the load transmitting member 32. Then, it is transmitted from the strain body 36 via the bridge 40 to the elastic support member 42, further transmitted to the leg body 161 of the leg 16 and received on the floor.

  In this embodiment, the elastic support member 42 supports the bridge 40. The bridge 40 has a substantially flat lower surface that is oriented to spread horizontally during weight measurement. At the time of measuring the weight, the upper surface of the elastic support member 42 is brought into close contact with the substantially flat lower surface of the bridge 40. Therefore, even if an excessive load is applied to the weight measuring device 1 or a repeated load is applied, the possibility that the load is locally concentrated and a part of the component is destroyed is reduced. Measurement accuracy can be maintained. Also, since there are no protrusions where loads concentrate locally and parts where the protrusions contact, there is no need to use expensive materials or heat treatment to increase hardness for such parts. The manufacturing cost of the apparatus 1 can be reduced.

  Moreover, the posture of the strain generating body 36 is properly maintained by the elastic deformation of the elastic support member 42. For example, if the heights of the two first arm portions 362 of the strain body 36 are different or the heights of the two second arm portions 364 are different, the accuracy of weight measurement is lowered. However, such a situation is reduced or prevented by the elastic deformation of the elastic support member 42. Further, since the elastic support member 42 has an impact mitigation performance, even if an impact is applied to the weight measuring device 1, the occurrence of backlash of parts of the weight measuring device 1 is reduced or prevented, and the weight measuring device 1 has a long life. Is secured.

  In the leg 16, the leg main body 161 where the load concentrates and the edge part 164 that restricts the movement of the bridge 40 or the like are connected by elastic connecting parts 165, 166, 167, 168 having high flexibility. Due to the highly flexible elastic connecting portions 165, 166, 167, and 168, an extra force is prevented from being applied to the leg body 161 from the edge portion 164.

  In the weight measuring device 1, the base 15 is connected to the platform 12 and defines a receiving space 27 together with the platform 12. The accommodation space 27 accommodates most of the load cell assembly 30 (including the upper portion of the leg 16, the load transmission member 32, the strain body 36, the strain gauge 38, the bridge 40, and the elastic support member 42). However, as shown in FIG. 22, the base 15 has a base through hole 15a, and the lower portion of the leg 16 protrudes from the accommodating space 27 to the lower side of the base 15 through the base through hole 15a. Is not fixed to the base 15, and the base 15 is displaced with the platform 12 in the vertical direction with respect to the legs 16.

  In a structure in which the leg is fixed to the base or the platform (a structure different from this embodiment), the strain body interposed between the leg and the platform is caused by the load applied to the strain body from the platform and the base. It will be deformed according to the force applied to the distorted body. When a load is applied to the platform, the base deforms slightly, so that the force applied from the base to the strain body can vary depending on the posture of the base. In addition, since the strain body is deformed by the load and the base and the leg are pulled together, the load applied to the strain body changes. Further, when an elastic support member is provided as in this embodiment, the force with which the base and the leg are pulled is further increased due to the elastic compression deformation of the elastic support member. These lower the measurement accuracy of the weight measured by the weight measuring device.

  On the other hand, in this embodiment, the legs 16 are not fixed to the base 15 and the platform 12 but are independent from the base 15 and the platform 12, and the base 15 and the platform 12 are both displaced with respect to the legs 16. The strain body 36 interposed between the leg 16 and the platform 12 is deformed according to the load applied from the platform 12 to the strain body 36 and the force applied to the strain body 36 from the floor on which the legs 16 are placed. become. However, the present embodiment is not limited to one in which the legs 16 are independent from the base 15 and the platform 12. The present invention can be applied even when the leg 16 is fixed to the base 15 or the platform 12.

  The elastic support member 42 is formed of rubber, but the elastic support member may be formed of another elastic body, for example, a spring. The reason why the elastic support member 42 made of rubber is used in this embodiment is that rubber generally has high durability against repeated loads, and even if the legs 16 and the bridge 40 are inclined with respect to the horizontal plane during weight measurement, the rubber is measured. This is because the error is small. Thereby, even if the floor is slightly inclined or the weight measuring device is slightly inclined with respect to the floor, the accuracy of measuring the weight measured by the weight measuring device 1 is sufficiently ensured.

  FIG. 23 is a table showing the results of a durability test of the load cell assembly 30 using the elastic support member 42 formed of different rubber. In the experiment, a load of 50 kgf was repeatedly applied to the single load cell assembly 30 20,000 times.

  There was no problem in the load cell assembly 30 using the elastic support member 42 formed of rubber having a shore hardness of A90 and A80. In the load cell assembly 30 using the elastic support member 42 formed of rubber having a Shore hardness A70, cracks occurred in the legs 16 formed of resin, but considering the number of times a general scale is used. It is acceptable for use as the weight measuring device 1. In the load cell assembly 30 using the elastic support member 42 formed of rubber having a shore hardness A60, cracks of the legs 16 formed of resin occurred so as to be visible from the outside. Therefore, it was judged that the elastic support member having a Shore hardness A60 was inferior. This is because, in the elastic support member 42 formed of rubber that is too soft, the compression of the elastic support member 42 in the vertical direction is too large, the elastic support member 42 is excessively spread in the horizontal direction, and the elastic support member 42 is fitted. This is to give a large force to push the leg 16 (see FIG. 15).

  FIG. 24 is a graph showing the experimental results of examining the relationship between the hardness of the elastic support member 42 and the weight measurement error. In the experiment, a load was applied so that distortion was applied to the casing 11 of the weight measuring apparatus 1, and the weight measurement value was examined. The system in which the casing 11 of the weight measuring device 1 is distorted is a system in which a flat wooden board with a soft rubber is placed on the platform 12 and a weight is placed on the wooden board. This is a method that approximates the state of No.12. As shown in FIG. 24, when the housing 11 is distorted, an error with respect to the load occurs. The harder the rubber, the greater the error. Further, from a rule of thumb, it is considered that the same result is obtained when the leg 16 and thus the weight measuring device 1 is inclined due to the inclination of the floor. However, according to the experimental results shown in FIG. 24, it is determined that the weight measurement error regarding the rubber having the Shore hardness A70 to A90 is not so large even at the load of 150 kgf, and there is no practical problem. For a rubber with a shore hardness of A90, the error is about 80 gf when the load is 150 kgf, and the error is about 60 gf when the load is 125 kgf. It is conceivable that the measurement accuracy is lower with a rubber harder than the Shore hardness A90.

  From the above experimental results related to FIGS. 23 and 24, the hardness of the elastic support member 42 is preferably Shore hardness A70 to A90. When the hardness of the elastic support member 42 made of rubber is Shore hardness A70 to A90, the durability against repeated loads is high, and even if the legs 16 and the bridge 40 are inclined with respect to the horizontal plane during weight measurement, the measurement is possible. Small error.

  The hardness of the elastic support member 42 is more preferably a Shore hardness A75 to A85. In the experiment related to FIG. 23, in the load cell assembly 30 using the elastic support member 42 formed of rubber having a shore hardness A70, cracks occurred in the legs 16 formed of resin, but rubber having a shore hardness A80 was used. Since there was no problem in the load cell assembly 30 using the elastic support member 42 formed in (1), rubber having a high hardness of Shore hardness A75 or higher is considered to be better in terms of durability. In the experiment related to FIG. 24, for a rubber with a Shore hardness A90, the error is about 60 gf at a load of 125 kgf, and for a rubber with a Shore hardness A80, the error is about 30 gf at a load of 125 kgf. Assuming that the allowable error at a load of 125 kgf is 50 gf, a rubber having a hardness of Shore A85 or less is considered preferable.

  As described above with reference to FIG. 10, each of the lower regions 327 of the side wall 326 includes a flat lower contact surface 327 a that is in surface contact with a part of the first arm portion 362 of the strain generating body 36, and the strain generating body. And a flat lower non-contact surface 327b facing each other without contacting the first arm portion 362. A step is provided between the lower contact surface 327a and the lower non-contact surface 327b. The lower contact surface 327a is in surface contact with a part of the first arm portion 362 of the strain body 36 and is directed so as to spread horizontally during weight measurement. The lower contact surface 327a extends in a direction parallel to the symmetry axis of the strain body 36, which is the direction in which the first arm portion 362 extends. Therefore, when a load is applied to the platform 12, the change in posture of the two first arm portions 362 receiving the load from the platform 12 in the strain generating body 36 is small. Moreover, the lower region 327 of the two side walls 326 is provided with not only the lower contact surface 327a but also the lower non-contact surface 327b. That is, only a part (lower contact surface 327a) of the lower region 327 is in surface contact with a part of the first arm portion 362 of the strain body 36, and the other part (lower non-contact surface 327b) is the first. Face one arm 362 without contacting. As described above, the lower contact surface 327a that contacts the first arm portion 362 of the two side walls 326 of the load transmitting member 32 is limited. Therefore, the first arm portion 362 and the lower contact surface 327a of the strain body 36 are limited. Touches on a surface with a very narrow width in a form close to line contact. When the first arm portion 362 of the strain generating body 36 and the lower contact surface 327a are in contact with a surface having a very wide width, a portion of the first arm portion 362 of the strain generating body 36 where the load is concentrated is present. It varies depending on the magnitude of the load. However, in this embodiment, the first arm portion 362 of the strain generating body 36 and the lower contact surface 327a are in contact with a surface having a very narrow width in a form close to a line contact. The portion of the first arm portion 362 where the load concentrates hardly varies depending on the magnitude of the load. In addition, a portion corresponding to the lower non-contact surface 327 b that does not contact the first arm portion 362 out of the two side walls 326 ensures a large thickness of the side wall 326 and suppresses deformation of the load transmission member 32. To contribute. Therefore, in this embodiment, when a load is applied to the platform 12, regardless of the magnitude of the load, the posture change of at least two arms that receive the load from the platform 12 out of the strain generating body 36 is extremely high. The measurement accuracy of the weight measuring device 1 is ensured.

  Each of the first arm portions 362 has a first through hole 366 that is directed to extend in the vertical direction when measuring the weight, and each of the lower regions 327 of the side wall 326 of the load transmission member 32 has a first through hole 366. A protrusion 328 to be inserted into the through hole 366 is provided, and the lower contact surface 327 a extends around the protrusion 328. By fitting the projections 328 into the first through holes 366 that are directed to extend in the vertical direction when measuring the weight, the horizontal movement of the strain generating body 36 and the load transmitting member 32 is prevented. . Further, since the lower contact surface 327a spreads around the protrusion 328 fitted into the first through hole 366, even if a load is applied to a position biased from the protrusion 328 of the load transmitting member 32, the strain generating body The first arm portion 362 of 36 and the lower contact surface 327a are in contact with each other on a horizontal surface, and the measurement accuracy of the weight measuring device 1 is ensured.

  FIG. 25 is a diagram showing a stress distribution generated in the strain body 36 during the weight measurement. The stress distribution was obtained by computer simulation. Region A1 is a region with the lowest stress, and region A5 is a region with the highest stress. The smaller the number assigned to the region A, the smaller the generated stress. As is clear from the comparison between FIG. 10 and FIG. 25, the lower contact surface 327a of the lower region 327 of the side wall 326 of the load transmitting member 32 is a portion corresponding to the low stress regions A1, A2 of the strain generating body 36 (distortion). Touch the small part). Accordingly, the regions A1 and A2 of the strain generating body 36 receive a load from the lower contact surface 327a of the lower region 327 of the side wall 326 of the load transmitting member 32 in a stable posture, and the measurement accuracy of the weight measuring device 1 is ensured.

  As described above with reference to FIG. 10, the load transmission member 32 further includes two outer side walls 329 that are disposed outside the two side walls 326 and extend in parallel with the two side walls 326. A hook 330 on which the first arm portion 362 of the strain body 36 is hung is formed. When the strain generating body 36 is hooked on the hook 330 of the load transmitting member 32, the strain generating body 36 and the load transmitting member 32 can be attached to and removed from the platform 12 as a unit. Therefore, handling of these parts is easy.

  As described above with reference to FIGS. 14, 15, 17, and 18, the leg 16 includes two first protrusions 170 and 171 that protrude inward from the edge portion 164, and an elastic coupling portion 165. 166, 167, 168 and second protrusions 172, 173, 174, 175 integrally connected. The first protrusion 170 is between the second protrusions 172 and 173, and the second protrusions 172 and 173 are adjacent to the first protrusion 170 in the circumferential direction centering on the axis of the leg main body 161. The first protrusion 171 is between the second protrusions 174 and 175, and the second protrusions 174 and 175 are adjacent to the first protrusion 171 in the circumferential direction centering on the axis of the leg main body 161. For this reason, even when a large torque is applied to the leg main body 161 in a state in which the rotation of the edge 164 around the axis is restricted, the first protrusion 170 contacts the second protrusion 172 or 173, The protrusion 171 contacts the second protrusion 174 or 175, restricts the rotation of the leg body 161 and thus the deformation of the elastic connecting portions 165, 166, 167, 168, and elastic connecting portions 165 arranged around the leg main body 161. The destruction of 166, 167, 168 is prevented.

  As described above with reference to FIG. 5, the convex portions 180 and 181 of the edge portion 164 of the leg 16 are inserted into the through holes 406 and 407 of the bridge 40, and the relative horizontal movement of the edge portion 164 with respect to the bridge 40 is performed. (Linear movement and rotational movement) are limited. As described above, the strain body 36 is fixed to the bridge 40 by the rivet 410 (see FIGS. 11 and 22). The strain generating body 36 is restricted from relative movement in the horizontal direction with respect to the load transmitting member 32 by fitting the two protrusions 328 of the load transmitting member 32 into the two first through holes 366 of the strain generating body 36. As shown, it is attached to the load transmitting member 32 (see FIGS. 10 and 22). The load transmission member 32 is prevented from moving relative to the platform 12 by the projections 322, 323, 324, and 325 (see FIGS. 4 to 6) being hooked on the inner cover 13 of the platform 12. Therefore, the edge portion 164 of the leg 16 is restricted so as not to rotate relative to the platform 12. That is, in the configuration of the weight measuring device 1, the rotation around the axis of the edge portion 164 is restricted by the bridge 40, the strain body 36, the load transmission member 32, and the platform 12. Therefore, when the leg 16 does not have the first protrusions 170 and 171 and the second protrusions 172, 173, 174, and 175, if a large torque is applied to the leg body 161, the elastic connecting portions 165, 166, 167 , 168 may be destroyed. However, even if a large torque is applied to the leg main body 161 by the action of the first protrusions 170 and 171 and the second protrusions 172, 173, 174 and 175, the rotation of the leg main body 161 and the elastic coupling portions 165 and 166 and The deformation of 167 and 168 is limited, and the breakage of the elastic connecting portions 165, 166, 167, and 168 arranged around the leg main body 161 is prevented.

  The effects of the first protrusions 170 and 171 and the second protrusions 172, 173, 174, and 175 are particularly useful when a carpet leg is attached to the leg 16. FIG. 26 is a perspective view showing the carpet leg 60. The carpet leg 60 is a substantially disk-shaped part made of, for example, resin, and has a flat lower surface 61. A plurality of protrusions 62 project upward from the center of the upper portion of the carpet leg 60. These protrusions 62 are respectively inserted into a plurality of holes 185 formed on the lower surface of the leg main body 161 of the leg 16. In this way, the carpet leg 60 is detachably attached to the leg main body 161. The diameter of the carpet leg 60 is much larger than the diameter of the leg body 161. Therefore, when the carpet leg 60 is attached to the leg body 161, a large torque is easily applied from the carpet leg 60 to the leg body 161. The first protrusions 170, 171 and the second protrusions 172, 173, 174, 175 serve as a detent that restricts the relative rotation of the leg body 161 with respect to the edge portion 164, so that a large torque is applied to the leg body 161. Even if this is done, the elastic connecting portions 165, 166, 167, 168 are prevented from being broken.

  FIG. 27 is a cross-sectional view of the weight measuring apparatus 1 according to another embodiment, and is a view seen in the same manner as FIG. The weight measuring device 1 does not have the load transmitting member 32, and a load is directly applied to the strain generating body 36 from the platform 12. A boss 13a is formed on the lower surface of the inner cover 13 of the platform 12, and a screw hole is formed in the boss 13a. The first arm portion 362 of the strain body 36 is abutted against the boss 13a, and the screw 70 passing through the first through hole 366 formed in the first arm portion 362 is stopped in the screw hole of the boss 13a. . In this way, the strain body 36 is directly fixed to the inner cover 13.

  In FIG. 27, the arrow indicates the load. The load applied to the outer cover 14 of the platform 12 is transmitted to the strain generating body 36 through the inner cover 13. Then, it is transmitted from the strain body 36 via the bridge 40 to the elastic support member 42, further transmitted to the leg body 161 of the leg 16 and received on the floor.

  In any of the embodiments, the strain generating body 36 is preferably formed by powder metallurgy. By forming by powder metallurgy, the strain generating body 36 can be reduced in size and mechanical strength can be ensured as compared with punching. Further, since the dimensional accuracy of the thickness and width of the strain generating body 36 is high, the accuracy of the load cell weight measurement is improved. As a method of powder metallurgy, a metal powder may be press-molded and sintered, or a metal powder injection molding method (MIM) may be used.

  With reference to FIG. 9, the preferable dimension of the strain body 36 is demonstrated. Preferably, the gap G1 between the first arm part 362 and the second arm part 364 and the gap G2 between the second arm part 364 and the strain region 361 are less than half the thickness of the strain body 36. . By reducing these intervals G1 and G2, the strain generating body 36 can be reduced in size (particularly, the lateral length in FIG. 9 can be shortened). In a high-strength metal material suitable for a strain generating body, in the punching process, the distance between them can be made only to the same extent as the thickness of the strain generating body 36, and cannot be made thinner than that. However, in powder metallurgy, it is possible to reduce these intervals and reduce the size of the strain generating body 36.

  Preferably, the length L1 of each of the first arm portions 362 in the direction perpendicular to the symmetry axis of the strain generating body 36 is 1.... Of the length L2 of the strain region 361 in the direction crossing the symmetry axis of the strain generating body 36. 3 times or more. A first through hole 366 is formed in each of the first arm portions 362, and other parts (inner cover 13 in the embodiment of FIG. 27) are made using the through holes of the first through hole 366. It is possible to screw on. If the distance L1 between the outer side surfaces of the two first arm portions 362 is large, the residual stress in the first arm portion 362 due to the tightening torque generated when the screw 70 is fastened can be reduced. Since this residual stress adversely affects the accuracy of load cell weight measurement, it is desirable that the residual stress be small. Each length L1 of the first arm portion 362 in the direction perpendicular to the symmetry axis of the strain body 36 is 1.3 times or more of the length L2 of the strain region 361 in the direction crossing the symmetry axis of the strain body 36. If so, the residual stress can be reduced and the accuracy of the load cell weight measurement can be improved.

  Preferably, the length L3 of the first connecting portion 363 in the direction parallel to the symmetry axis of the strain body 36 is 1.4 times the length L2 of the strain region 361 in the direction crossing the symmetry axis of the strain body 36. That's it. If the length L3 of the first connecting portion 363 in the direction parallel to the symmetry axis of the strain generating body 36 is large, the residual stress in the first arm portion 362 due to the tightening torque generated when the screw 70 is fastened is reduced. be able to. Since this residual stress adversely affects the accuracy of load cell weight measurement, it is desirable that the residual stress be small. The length L3 of the first connecting portion 363 in the direction parallel to the symmetry axis of the strain generating body 36 is not less than 1.4 times the length L2 of the strain region 361 in the direction crossing the symmetry axis of the strain generating body 36. For example, the residual stress can be reduced and the accuracy of the load cell weight measurement can be improved.

  28 to 30 are graphs showing the results of examining the weight measurement error by changing the interval L1 and the length L3. FIG. 28 shows the relationship between the tightening torque of the screw 70 and the weight measurement error when L1 / L2 = 86% and L3 / L2 = 86%. FIG. 29 shows the relationship between the tightening torque of the screw 70 and the weight measurement error when L1 / L2 = 93% and L3 / L2 = 100%. FIG. 30 shows the relationship between the tightening torque (1.0 Nm, 2.0 Nm, 2.5 Nm) of the screw 70 and the weight measurement error when L1 / L2 = 130% and L3 / L2 = 140%. As is clear from these figures, the measurement error increases as the tightening torque increases. This is because the residual stress in the first arm portion 362 caused by the tightening torque generated when the screw 70 is fastened has an adverse effect on the measurement. However, the weight measurement error when L1 / L2 = 130% and L3 / L2 = 140% shown in FIG. 30 is significantly smaller than the other results shown in FIGS. Therefore, it can be understood that a remarkable effect is achieved when L1 is 1.3 times or more of L2 and L3 is 1.4 times or more of L2.

  As described above, the strain body 36 may be manufactured by press-molding and sintering a metal powder, or may be manufactured by a metal powder injection molding method. However, the inventor has found that it is preferable to produce the strain body 36 by pressing and sintering a specific type of material. A specific type of material is a metal powder containing at least vanadium (V) and chromium (Cr) and containing iron (Fe) as a main component. Hereinafter, this material will be described in detail.

  When chromium and vanadium are contained in the metal powder as the material of the strain generating body 36, the two first arm portions 362, the two second arm portions 364, the first connecting portion 363, and the second The inventor has found that the mechanical strength of the strain generating body 36 having a complicated shape having the connecting portion 365 and the like can be improved. As a result of trial and error, the inventor has found that a suitable strength can be secured when 10.8% or more of chromium is contained in the sintered metal (after sintering) in which the metal powder is sintered. On the other hand, when the amount of chromium is too large, the strength is reduced and the manufacturing cost is increased. As a result of trial and error, the inventor considers the balance between strength and cost, and it is appropriate that the chromium content of sintered metal (after sintering) sintered (after sintering) is 18.2% or less. I found out. Therefore, the sintered metal obtained by sintering the metal powder preferably contains 10.8% to 18.2% chromium.

  Further, as a result of trial and error, the inventor has found that when 0.1% or more of vanadium is contained in the sintered metal (after sintering) obtained by sintering the metal powder, a suitable strength can be secured. On the other hand, when there is too much quantity of vanadium, it will lead to the increase in manufacturing cost. In particular, since vanadium is a very expensive material, if the amount is too large, the cost is greatly increased. As a result of trial and error, the inventor considers a balance between strength and cost, and it is appropriate that the vanadium content of the sintered metal (after sintering) sintered metal powder (after sintering) is 0.5% or less. I found out. Therefore, it is preferable that the sintered metal obtained by sintering the metal powder contains 0.1% to 0.5% vanadium.

  If the metal powder that is the material of the strain generating body 36 contains carbon, the hardness of the strain generating body 36 is improved by heat treatment after the sintering process, and consequently the mechanical strength of the strain generating body 36 is improved. be able to. As a result of trial and error, the inventor has found that when 0.5% or more of carbon is contained in a sintered metal (after sintering) in which metal powder is sintered, a suitable strength can be secured. On the other hand, if the amount of carbon is too large, the shrinkage of the material increases during sintering and subsequent heat treatment, causing variations in the dimensions of the strain-generating body 36. When the material contraction is large, the strain generating body 36 having a complicated shape having two first arm portions 362, two second arm portions 364, a first connecting portion 363, a second connecting portion 365, and the like. Cannot be formed with high accuracy. As a result of trial and error, the inventor considers the balance between strength and cost, and if the content of carbon in the sintered metal after sintering the metal powder (after sintering) is 1.8% or less, It was found that it is suitable for suppressing variation. Therefore, it is preferable that the sintered metal obtained by sintering the metal powder contains 0.5% to 1.8% carbon.

  The weight measuring device that is a weight scale that can also be used as a body composition meter has been described above, but the present invention relates to weight measurement, and weight measuring devices that measure weights other than humans and their components are also within the scope of the present invention. Is in. In the embodiment, four load cell assemblies are provided in the weight measuring apparatus 1, but the number of load cell assemblies provided in the weight measuring apparatus is not limited to four.

1 weight measuring device,
11 housing, 12 platform, 13 inner cover, 13a boss, 14 outer cover,
15 base, 15a base through hole,
16 legs, 161 leg body, 162 recess, 163 oblong hole, 164 edge part, 165, 166, 167, 168 elastic connection part, 165a, 166a, 167a, 168a outer part,
165b, 166b, 167b, 168b inner part, 170, 171 first protrusion, 172, 173, 174, 175 second protrusion, 180, 181 convex part, 182, 183 hook,
17 Power switch,
18 electrode plate,
19 handle units, 20 operation boxes, 21 and 22 grips, 23 displays, 24 and 25 operation buttons,
27 containment space,
28 substrates,
29 cables,
30 load cell assembly,
32 Load transmitting member, 321 upper wall, 322, 323, 324, 325 protrusion, 326 side wall, 327 lower region, 327a lower contact surface, 327b lower non-contact surface, 328 protrusion, 329 outer side wall, 330 hook, 331 end wall, 332 Notch,
34 Load cell,
36 strain body,
361 strain region, 361a one end, 361b other end, 362 first arm, 363 first connection, 364 second arm, 365 second connection, 366 first through hole, 367 second Through hole, 368 mark, 369 groove,
38 Strain gauge,
40 bridge, 401 top surface, 402 bottom surface, 403 boss, 404 through hole, 406,407 through hole,
410 rivets,
42 elastic support member, 421 upper part, 422 lower part,
50 tapes,
60 carpet legs,
61 bottom surface,
62 protrusions,
70 screws.

Claims (9)

It is used as a load cell for measuring weight, and is a strain body that is deformed by transmission of a load,
Formed by powder metallurgy,
It has a line-symmetric shape and uniform thickness,
A rectangular strain region disposed in the center and extending in the same direction as the axis of symmetry and having one end and the other end;
Two first arms extending parallel to the axis of symmetry;
A first connecting part extending in a direction crossing the axis of symmetry and connected to the one end of the strain region and the first arm part;
Two second arm portions arranged closer to the strain region than the first arm portion and extending in parallel with the symmetry axis;
A second connecting portion extending in a direction crossing the axis of symmetry and connected to the other end of the strain region and the second arm portion;
One of the pair of the first arm part and the pair of the second arm part receives a load in a vertical direction with respect to the strain body, and the pair of the first arm part and the pair of the second arm part. The other is configured to be fixed to the support,
A strain generating body, wherein an interval between the first arm portion and the second arm portion and an interval between the second arm portion and the strain region are equal to or less than half of the thickness.   The strain generating body according to claim 1, which is obtained by press-molding and sintering a metal powder.   The strain generating body according to claim 1, which is obtained by a metal powder injection molding method. Said first arm portion is subjected to a load of the vertical direction with respect to the strain body, any of claims 1 to 3, wherein the second arm portion, characterized in that it is fixed to the support 1 The strain body according to Item. The length of each of the first arm portions in the direction perpendicular to the symmetry axis of the strain body is 1.3 times or more of the length of the strain region in the direction across the symmetry axis of the strain body. The strain generating body according to any one of claims 1 to 4 , wherein: The length of the first connecting portion in the direction parallel to the symmetry axis of the strain body is 1.4 times or more of the length of the strain region in the direction crossing the symmetry axis of the strain body. The strain body according to any one of claims 1 to 5 , wherein the strain body is characterized by the following. The strain body according to any one of claims 1 to 6 , wherein a first through hole is formed in each of the first arm portions. The strain body according to any one of claims 1 to 7 , wherein a second through hole is formed in each of the second arm portions. The strain body according to any one of claims 1 to 8 ,
A weight measuring apparatus comprising a load cell attached to the strain body and including a plurality of strain gauges that generate signals according to deformation of the strain body.

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