JP5822165B2 - Master ring gauge - Google Patents

Description

  The present invention relates to a mastering gauge used for zero adjustment and calibration of various measuring instruments such as a cylinder gauge, an inner micrometer, and an inner dial comparator.

  Conventionally, a ring gauge having a structure shown in Japan Precision Measuring Instruments Industry Association Standard JMAS 4008-1988 has been known.

  In addition, there is a known structure in which a protective ring is arranged on the outer periphery of the ring gauge. By arranging the protective ring, dirt on the hand does not adhere to the ring gauge even if it is grasped with bare hands. The protective ring protects the ring gauge from external forces due to unexpected drop collisions, prevents the ring gauge from being broken or damaged, or damages the reference gauge hole, or by hand during zero adjustment or calibration, This will prevent body temperature from being transmitted directly to the ring gauge.

Utility model registration No. 3125109 Japanese Utility Model Sho 60-11501

  However, in the case of the conventional structure, an annular non-slip uneven portion is formed on the outer peripheral surface of the protective ring, and the outer peripheral surface of the protective ring is gripped so as to be sandwiched between two fingers, the thumb and the index finger that are opposed from above. When it is lifted up, it is structured to prevent the protective ring from slipping and falling due to the non-slip uneven strip, but with the protective ring placed on the surface plate, the protective ring is placed on the surface plate with the thumb and index finger facing from the side. When gripped so as to be pinched with a finger, a horizontal slipping out of the protective ring may occur due to the presence of an annular non-slip uneven portion formed on the outer peripheral surface of the protective ring. There is a disadvantage that the protective ring may strongly collide with a measuring instrument on the surface plate and damage the outer peripheral surface of the protective ring and the reference gauge hole.

The present invention aims to solve these disadvantages. Among the present inventions, the invention according to claim 1 is provided on the outer peripheral portion of a ring gauge having a reference gauge hole serving as a reference for various measuring instruments. A protective ring is arranged, and on the upper surface of the protective ring, a nominal dimension as an inner diameter value of the reference gauge hole, an error value between the nominal dimension and the actual dimension, and a measurement index indicating the direction and position of the measurement axis of the actual dimension. The ring ring is arranged so that the upper surface of the ring gauge is immersed from the upper surface of the protective ring, and the protective ring is prevented from sliding and falling when the outer peripheral surface of the protective ring is gripped and lifted to the outer peripheral surface of the protective ring. When the outer peripheral surface of the protective ring placed on the surface plate is gripped on the outer peripheral surface of the protective ring, the non-slip concave / convex strip portion is formed. Prevents the guard ring from sliding out horizontally Stop gripping portion and a plurality formation, top and bottom of the anti-slip concave-convex portions are formed on the arc surface, the anti-slip gripping portion is formed in the concave arc surface which is notched to the anti-slip concave-convex portions in the concave arc shape The master ring gauge is characterized by

According to the second aspect of the present invention, a protective ring is disposed on the outer periphery of a ring gauge having a reference gauge hole that serves as a reference for various measuring instruments, and the inner diameter value of the reference gauge hole is formed on the upper surface of the protective ring. The nominal dimension, the error value between the nominal dimension and the actual dimension, and the measurement index indicating the direction and position of the measurement axis of the actual dimension are displayed, and the upper surface of the ring gauge is immersed from the upper surface of the protective ring, and the protection is performed. An annular non-slip ridge is formed on the outer peripheral surface of the protective ring to prevent the protective ring from slipping and falling when the outer peripheral surface of the protective ring is gripped and lifted. when gripping the outer circumferential surface of the protective ring placed on the surface plate, to form a plurality of anti-slip gripping portion to prevent the jumping out horizontal sliding of the protective ring due to the presence of the annular anti-slip concave-convex portions, the sliding The top and bottom of the staggered ridge are formed on the arc surface Is, the anti-slip grip portion is in the master ring gauge, characterized in that it is formed as a flat surface which is notched to the anti-slip concave-convex portions in a planar shape.

The invention according to claim 3 is characterized in that the protective ring is made of an aluminum alloy, and the invention according to claim 4 is characterized in that the ring gauge is made of alloy tool steel, cemented carbide. Or made of ceramics.

As described above, according to the present invention, in the first aspect of the invention , the nominal size as the inner diameter value of the reference gauge hole, the error value between the nominal size and the actual size, and the actual size are measured on the upper surface of the protective ring. Since the measurement index indicating the direction and position of the axis is displayed, it is possible to easily recognize the imprinted position of the actual size of the reference gauge hole in the zero point adjustment of various measuring instruments. The calibration accuracy can be improved, and the upper surface of the ring gauge is immersed from the upper surface of the protective ring. Therefore, even if the ring gauge is inverted on the surface plate, the upper surface of the ring gauge and reference gauge hole without touching the surface plate, it is possible to prevent damage to the top surface and the reference gauge hole of the ring gauge, it is possible to improve handling, cyclic non-slip irregularities on the outer peripheral surface of the protective ring And a plurality of non-slip gripping portions are formed on the outer peripheral surface of the protective ring, so that when the protective ring is gripped and lifted, the protective ring prevents the protective ring from sliding down. By holding multiple anti-slip grips, it is possible to prevent horizontal slipping of the protective ring due to the presence of the anti-slip irregularities, and protective rings and ring gauges caused by external forces such as collisions. Since the top and bottom portions of the non-slip uneven portion are formed on the arc surface, the non-slip uneven portion can be safely gripped by hand, Since the non-slip gripping part is formed by a concave arc surface with a non-slip uneven strip cut into a concave arc shape, the concave arc surface is easy to grip on the finger and when the protective ring is gripped, Can prevent horizontal slipping out due to the presence of strips. It is possible to prevent damage to the reference gauge hole of the protective ring and the ring gauge due to an external force such as collision.

In the invention described in claim 2 , the nominal dimension as the inner diameter value of the reference gauge hole on the upper surface of the protective ring, the error value between the nominal dimension and the actual dimension, and the direction and position of the measurement axis of the actual dimension. Since the measurement index is displayed, it is possible to easily recognize the imprint position of the actual size of the reference gauge hole in the zero point adjustment of various measuring instruments, and to improve the zero point adjustment accuracy and calibration accuracy accordingly. Since the upper surface of the ring gauge is immersed from the upper surface of the protective ring, the upper surface of the ring gauge and the reference gauge hole are fixed even if the ring gauge is inverted in a reverse state on the surface plate. Without touching the panel, it is possible to prevent damage to the upper surface of the ring gauge and the reference gauge hole, to improve the handleability, and to form an annular non-slip unevenness on the outer peripheral surface of the protective ring, Or Since there are a plurality of non-slip gripping portions formed on the outer peripheral surface of the protection ring, when the protection ring is gripped and lifted, the slippage of the protection ring can be prevented by the anti-slip irregularities, and By gripping multiple anti-slip gripping parts, it is possible to prevent horizontal slipping of the protective ring due to the presence of anti-slip uneven parts, and damage to the protective ring and reference gauge hole of the ring gauge due to external forces such as collisions. Since the top and bottom of the non-slip uneven portion are formed on an arc surface, the non-slip uneven portion can be safely gripped by hand, and the non-slip grip portion is Since the non-slip uneven portion is formed by a flat surface which is cut out in a planar shape, a plurality of anti-slip grips can be easily formed.

In the invention according to claim 3 , since the protective ring is made of an aluminum alloy, the weight can be reduced and the corrosion resistance can be improved, and the corrosion resistance can be improved by alumite finishing. In addition, it is possible to add wear resistance and decorativeness.

In the invention according to claim 4 , the ring gauge is made of alloy tool steel, cemented carbide, or ceramics. In the ring gauge made of alloy tool steel, it is excellent in impact resistance and the like. In the ring gauge made of cemented carbide, wear resistance and long life can be achieved, and since the coefficient of thermal expansion is small, there is little change due to temperature, and because of high hardness, the surface is hardly scratched, Gauge management is easy, and ceramic ring gauges have superior wear resistance compared to steel and are resistant to aging, so there is no dimensional change, no worry about corrosion, etc. Therefore, it is not magnetized, there is little plastic change due to scratches and dents, and it is lightweight and easy to measure and maintain.

1 is a perspective view of a first embodiment of the present invention. 1 is an exploded perspective view of a first embodiment of the present invention. It is a top view of the 1st example of an embodiment of the invention. It is a side view of the first embodiment of the present invention. 1 is a cross-sectional view of a first embodiment of the present invention. It is a perspective view of the second embodiment of the present invention. It is a top view of the 2nd example of an embodiment of the invention. It is sectional drawing of the 2nd example of implementation of this invention.

  1 to 8 show an embodiment of the present invention, FIGS. 1 to 5 show a first embodiment, and FIGS. 6 to 8 show a second embodiment.

  In the first embodiment shown in FIGS. 1 to 5, reference numeral 1 denotes a ring gauge, which is formed in a ring shape having a reference gauge hole 2 that serves as a reference for various measuring instruments, and is made of alloy tool steel (JIS symbol: SKS or SKT). Etc.) is manufactured from a steel material such as steel, cemented carbide or ceramics such as zirconia, and a protective ring 3 is arranged on the outer periphery of the ring gauge 1, and in this case, the protective ring 3 is manufactured from an aluminum alloy and colored anodized. Then, the fitting recess 3c is formed in the protective ring 3, and the outer peripheral surface of the ring gauge 1 is bonded and fixed to the inner peripheral surface of the fitting recess 3c with, for example, an adhesive.

  In this case, as shown in FIGS. 1, 2, and 3, on the outer peripheral surface of the protective ring 3, a two-ring annular shape that prevents the protective ring 3 from sliding and falling when the protective ring 3 is grasped and lifted by two fingers. Of the anti-slip uneven portion 4, the top 4 a and the bottom 4 b of the anti-slip uneven portion 4 are formed on the arc surface, and the protective ring placed on the surface plate J on the outer peripheral surface of the protective ring When the outer peripheral surface of 3 is gripped so as to be sandwiched between the thumb and forefinger, the horizontal slip-out in the horizontal direction S perpendicular to the axial direction of the reference gauge hole 2 of the protective ring 3 due to the presence of the annular non-slip uneven portion 4 is prevented. A plurality of non-slip gripping portions 5 are formed, in this case, six on a 60 degree equidistant arrangement.

  4 and 5, the bottom surface 3a of the protective ring 3 is made to contact the bottom surface 1a of the ring gauge 1 so that only the bottom surface 1a of the ring gauge 1 is in direct contact with the surface of the temperature-controlled surface plate J. Further, for example, a minute protrusion amount H of 0.1 mm to 0.5 mm is protruded and configured.

Further, in this case, as shown in FIG. 1, the upper surface 1 b of the ring gauge 1 is arranged so as to be immersed from the upper surface 3 b of the protective ring 3.

In this case, as shown in FIG. 1, the nominal dimension M as the inner diameter value D of the reference gauge hole 2 is displayed on the upper surface 3b of the protective ring 3. In this case, since the inner diameter value D is 10 mm, the nominal dimension M is “ No. 10 ”is displayed, and an error value N between the nominal dimension M and the actual dimension is displayed. In this case, since the actual dimension is 9.9991 mm, the error value N is displayed as“ Actual -0.0009 ”. ing.

F is a measurement index. In this case, as shown in FIG. 1, it is formed into a black triangular mark, formed by laser printing or the like, and the measurement axis X of the actual dimension is formed on the upper surface 3b of the protective ring 3. The direction and position are displayed.

  Since the first embodiment of the present embodiment has the above configuration, when the protective ring 3 is gripped and lifted on the outer peripheral surface of the protective ring 3 with a finger as shown in FIGS. Two annular anti-slip irregularities 4 are formed, and the outer peripheral surface of the protective ring 3 placed on the surface plate J is attached to the outer peripheral surface of the protective ring with two fingers, the thumb and the index finger. A plurality of non-slip gripping portions 5 are formed to prevent horizontal slipping out in the horizontal direction perpendicular to the axial direction of the reference gauge hole 2 of the protective ring 3 due to the presence of the annular non-slip uneven portion 4 when gripped so as to be sandwiched. Therefore, when the protective ring 3 is gripped and lifted, the anti-slip uneven portion 4 can prevent the protective ring 3 from slipping down, and the plurality of anti-slip grips 5 can be gripped. Due to the presence of the non-slip uneven portion 4, the protective ring 3 is horizontally slipped out. Can be prevented, it is possible to prevent damage to the reference gauge hole 2 of the protective ring 3 and ring gauge 1 according to an external force such as collision.

  In this case, as shown in FIGS. 1 and 2, since the top 4a and the bottom 4b of the non-slip uneven portion 4 are formed on the arc surface, the anti-slip uneven portion 4 can be safely held by hand. In this case, the non-slip gripping portion 5 is formed by six concave arc surfaces 6 in which the anti-slip uneven portion 4 is notched in a concave arc shape. It is easy to hold, and when the protective ring 3 is gripped, horizontal slipping out due to the presence of the non-slip uneven portion 4 can be reliably prevented.

  In this case, as shown in FIGS. 4 and 5, the bottom surface 1a of the ring gauge 1 is disposed so as to protrude from the bottom surface 3a of the protective ring 3. Therefore, only the bottom surface 1a of the ring gauge 1 is temperature-controlled. The temperature of the surface of the temperature controlled surface plate J in the measurement / inspection room is quickly transmitted to the ring gauge 1, and accordingly, the temperature break-in time as preparation work is shortened. Therefore, it is possible to suppress variations in the temperature of the ring gauge 1, and consequently, it is possible to speed up the zero adjustment and calibration of various measuring instruments.

In this case, as shown in FIG. 1, the upper surface 1b of the ring gauge 1 is arranged so as to be immersed from the upper surface 3b of the protective ring 3. Therefore, even if the ring gauge 1 is inverted on the surface plate J in a reversely inverted state, The upper surface 1b and the reference gauge hole 2 of the ring gauge 1 do not touch the surface plate J, the damage of the upper surface 1b of the ring gauge 1 and the reference gauge hole 2 can be prevented, and the handleability can be improved.

In this case, the nominal dimension M as the inner diameter value D of the reference gauge hole 2, the error value N between the nominal dimension M and the actual dimension, and the direction and position of the measurement axis X of the actual dimension are provided on the upper surface 3b of the protective ring 3. Since the measurement index F is displayed, it is possible to easily recognize the imprint position of the actual dimension of the reference gauge hole 2 in the zero point adjustment of various measuring instruments. Improvements can be made.

  The second embodiment shown in FIGS. 6 to 8 shows another structure. In this case, the anti-slip grip portion 5 of the first embodiment is formed on an arc surface composed of a top portion 5a and a bottom portion 5b. On the other hand, in this case, as shown in FIGS. 6, 7, and 8, the non-slip gripping portion 5 is formed on eight flat surfaces 7 in which the anti-slip uneven portion 4 is cut out in a planar shape.

  In this second embodiment, the same operational effects as in the first embodiment can be obtained, and the non-slip grip portion 5 is formed by eight flat surfaces 7 cut out in a planar shape. Therefore, the plurality of non-slip grip portions 5 can be easily formed.

  The present invention is not limited to the above embodiment, but the material and size of the ring gauge 1, the size of the reference gauge hole 2, the material and size of the protective ring 3, the non-slip uneven portion 4, The shape of the non-slip gripping part 5, the measurement index F, the nominal dimension M, the form of the error value N, and the like are designed as appropriate.

  As described above, the intended purpose can be sufficiently achieved.

J Surface plate
D inside diameter
M nominal size
N error value
X measurement axis
F measurement index 1 Ring gauge
1b Upper surface 2 Reference gauge hole 3 Protective ring
3b upper surface 4 non-slip uneven portion 4a top 4b bottom 5 anti-slip grip 6 concave arc surface 7 flat surface

Claims (4)

A protective ring is arranged on the outer periphery of a ring gauge having a reference gauge hole that serves as a reference for various measuring instruments, and the nominal size, nominal size, and actual size as the inner diameter value of the reference gauge hole on the top surface of the protective ring. And the measurement index indicating the direction and the position of the measurement axis of the actual dimension, and the upper surface of the ring gauge is immersed from the upper surface of the protective ring, and the outer surface of the protective ring is placed on the outer peripheral surface of the protective ring. An annular non-slip uneven portion that prevents the protective ring from slipping and falling when the outer peripheral surface is gripped and lifted is formed, and the protective ring mounted on the surface plate is formed on the outer peripheral surface of the protective ring. When the outer peripheral surface is gripped, a plurality of non-slip grips are formed to prevent horizontal slipping out of the protective ring due to the presence of the annular non-slip ridges, and the top and bottom of the non-slip ridges are arcs. Formed on the surface, the non-slip gripping portion is Master ring gauge, characterized in that it is formed in the concave arc surface which is notched to stop concave-convex portions in the concave arc shape. A protective ring is arranged on the outer periphery of a ring gauge having a reference gauge hole that serves as a reference for various measuring instruments, and the nominal size, nominal size, and actual size as the inner diameter value of the reference gauge hole on the top surface of the protective ring. And the measurement index indicating the direction and the position of the measurement axis of the actual dimension, and the upper surface of the ring gauge is immersed from the upper surface of the protective ring, and the outer surface of the protective ring is placed on the outer peripheral surface of the protective ring. An annular non-slip uneven portion that prevents the protective ring from slipping and falling when the outer peripheral surface is gripped and lifted is formed, and the protective ring mounted on the surface plate is formed on the outer peripheral surface of the protective ring. When the outer peripheral surface is gripped, a plurality of non-slip grips are formed to prevent horizontal slipping out of the protective ring due to the presence of the annular non-slip ridges, and the top and bottom of the non-slip ridges are arcs. Formed on the surface, the non-slip gripping portion is Master ring gauge, characterized in that the stop concave-convex portions are formed on the flat surface which is notched in a plane. The master ring gauge according to claim 1 or 2 , wherein the protective ring is made of an aluminum alloy. The master ring gauge according to claim 1 or 2 , wherein the ring gauge is made of alloy tool steel, cemented carbide, or ceramics.