US3845564A - Micrometer with movable anvil - Google Patents

Micrometer with movable anvil Download PDF

Info

Publication number
US3845564A
US3845564A US00295225A US29522572A US3845564A US 3845564 A US3845564 A US 3845564A US 00295225 A US00295225 A US 00295225A US 29522572 A US29522572 A US 29522572A US 3845564 A US3845564 A US 3845564A
Authority
US
United States
Prior art keywords
spindle
anvil
mounting section
micrometer
section
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US00295225A
Other languages
English (en)
Inventor
P Morgan
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
CENTURY WHEELS Inc
Original Assignee
CENTURY WHEELS Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from US00238340A external-priority patent/US3810310A/en
Application filed by CENTURY WHEELS Inc filed Critical CENTURY WHEELS Inc
Priority to US00295225A priority Critical patent/US3845564A/en
Priority to AU53421/73A priority patent/AU477173B2/en
Priority to CA166,422A priority patent/CA985495A/en
Priority to CH433373A priority patent/CH563006A5/xx
Priority to NL7304271A priority patent/NL7304271A/xx
Priority to GB1462173A priority patent/GB1412073A/en
Priority to FR7310976A priority patent/FR2178069B1/fr
Priority to JP48034219A priority patent/JPS51108857A/ja
Priority to IT22213/73A priority patent/IT986628B/it
Priority to US398461A priority patent/US3871596A/en
Priority to BE135959A priority patent/BE805218A/fr
Priority to BR754773A priority patent/BR7307547D0/pt
Priority to AR25617274A priority patent/AR208894A1/es
Publication of US3845564A publication Critical patent/US3845564A/en
Application granted granted Critical
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • GPHYSICS
    • G01MEASURING; TESTING
    • G01BMEASURING LENGTH, THICKNESS OR SIMILAR LINEAR DIMENSIONS; MEASURING ANGLES; MEASURING AREAS; MEASURING IRREGULARITIES OF SURFACES OR CONTOURS
    • G01B3/00Measuring instruments characterised by the use of mechanical techniques
    • G01B3/18Micrometers

Definitions

  • Patent 191 Morgan 1 1 Nov. 5, 1974 MICROMETER WITH MOVABLE ANVIL [75] Inventor: Paul A. Morgan, Chicago, Ill.
  • ABSTRACT A micrometer comprises a frame having an anvil mounting section and a spindle mounting section.
  • a spindle is mounted in the spindle mounting section and an anvil means is mounted to the anvil mounting section.
  • the anvil mounting means is biased for movement relative to the spindle mounting section upon creation of gauging pressure by a workpiece that is being measured between the anvil means and the spindle.
  • Indicating means responsive to the relative movement of the anvil means indicates the application of a predetermined gauging pressure on the anvil means and the moving of the anvil means from a nonmeasuring position to a measuring position.
  • This invention relates to improvements in micrometers, and more particularly relates to improvements for insuring accurate readings of micrometers throughout their life.
  • micrometers In the past, there have been many different types of inicrometersbased on the use of a threaded spindle or micrometer screw to obtain measurements of linear distances. These micrometers, for the most part, have been limited to one inch micrometers, that is, micrometers having a measuring range of at most one inch, as distinguished from the largest measurement that the micrometer can make.
  • a conventional micrometer includes a threaded spindle or micrometer screw which is longitudinally movable under the control of a nut. Attempts to provide micrometers with a greater than one inch range have met with difficulty because of the inaccuracies inherent in producing a thread of this length by ordinary methods. Further, the threads of the micrometer-screw and nut are subject to wear during use of the micrometer. This wear results in play or a sloppy fit between the micrometer screw and the nut and causes inaccurate micrometer readings.
  • the prior art has recognized that error is introduced into the micrometer reading by the wear of the threads of the micrometer screw and nut, and has employed various means tocompensate for this wear. Although the prior art has compensated for wear, this compensation has not always achieved a compensation of the error introduced by the wear, and in some cases where the sloppiness is continually compensated for, the error wear usually involves periodic adjustment of the nut on the micrometer screw after a certain amount of wear hasoccurred. Until this periodic adjustment is made, however, the sloppiness caused by the wear produces inaccurate micrometer readings.
  • An automobile disc braking system usually comprises a rotor attached to the wheel of the automobile and a plurality of brake pads which are normally positioned in an inactive position closely adjacent theopposed braking surfaces of the rotor.
  • a brake operating mechanism When it is desired to slow or stop a rotation of the wheel of an automobile, a brake operating mechanism is actuated to force the brake pads into frictional contact with the rotor. The frictional contact of the brake pads with the rotor results in a decrease in the rotation of the wheel.
  • the thickness of the rotor is decreased to a point where it is subject to failure due to the stresses caused by the frictional forces that are applied to it during the braking action.
  • the minimum thickness that the rotor can have and still be safe for use is known as the discard thickness/and thus it is important to be able to accurately measure the thickness of the rotor to determine whether it has reached the discard thickness. If the thickness of the rotor is less than the discard thickness it must be discarded and replaced with a new rotor.
  • disc brakes for use as the braking mechanism of motor vehicles has resulted in the need for a device which can accurately measure the rotors when they are new and which can determine when the disc brakes have been worn to an unsafe point.
  • the original size of the rotors for disc brakes vary from a fraction of an inch to about two inches in thickness and the discard thickness for each type of rotor also varies.
  • any instrument that is designed for determining whether a disc brake is still safe must be capable of measuring disc brake rotors at varying thickness from as small as three eighths of an inch to as large as two inches.
  • the braking surfaces of the rotors often have grooves and score marks worn into them, and the rotor thickness at these points must also be measured when considering whether any particular disc brake is safe for continued use.
  • a micrometer is provided with a novel means for controlling the-movement of the spindle including a control nut extending partially around a longitudinal portion of the threaded section of the spindle and resilient force applying means acting transverse to the axis of the spindle to continuously urge the threads of the spindle and control nut into tight engagement with each other to maintain the roots and crests of the threads of spindle in continuous alignment with the roots and crests of the control nut to provide for accurate readings of the micrometer.
  • the device described in the above pending application is extremely accurate and provides for accurate measurement when the anvil and spindle are properly aligned on the workpiece that is being measured.
  • the canting of the micrometer causes severe stresses to be developed on the anvil and the structure supporting the anvil. These stresses distort the support structure and result in inaccurate micrometer readings. In fact, the stresses caused can be so severe that the support structure can be permanently distorted to destroy the reproducability of readings obtainable by the micrometer. Further, the canting of the micrometer can cause damage to the workpiece being measured.
  • a micrometer is a contact instrument which means that there must be positive contact between the workpiece being measured and the micrometer. ln conventional micrometers the amount of contact or gauging pressure applied to the workpiece is a function of the operator of the micrometer. Each operatorobviously will have a different feel ofthe gauging pressure. Also, the feel of the same operator will vary from one measurement to another. The gauging pressure applied to a workpiece, however, must be the same for each measurement to obtain the same true reading time after time, because almost imperceptible differences in the amount of contact can result in different measurements for the same size workpiece.
  • ratchet controls for the micrometer.
  • a ratchet control is an overriding clutch that kicks out at a predetermined torque to hold the gauging pressure applied to the workpiece to the same amount for each instrument regardless of human factors.
  • the spindle has a radially extending pin on the back end of its threaded section.
  • a hollow sleeve having a pair of diametrically opposed longitudinally extending slots is mounted about the threaded section of the spindle and the pin rides in the opposed longitudinally extending slots.
  • the hollow sleeve is rotatable and its rotation produces a corresponding rotation of the spindle.
  • the hollow sleeve is a difficult and expensive part to manufacture, and the assembling of the pin on the end of the spindle and in th longitudinally extending slots of the sleeve is a time consuming procedure.
  • a further object of this invention is to provide a micrometer that produces the same amount of gauging pressure for each measurement that it makes.
  • the micrometer of this invention comprises: a frame having an anvil mounting section and a spindle mounting section; a spindle mounted in said spindle mounting section for axial movement; an anvil means mounted to the anvil mounting section and movable relative to the spindle mounting section from a non-measuring position to a measuring position upon the creation of a gauging pressure by a workpiece that is being measured between the anvil means and spindle; and indicating means responsive to the relative movement of the anvil means for indicating movement of the anvil means to the measuring position.
  • first biasing means are provided for biasing the anvil means for movement relative to the spindle mounting section and for maintaining the same amount of gauging pressure at the measuring position for each measurement that the micrometer makes.
  • the anvil means includes a measuring arm and that the first biasing means be a spring engaged with the measuring arm.
  • the measuring arm preferably is pivotally mounted to the anvil mounting section and the spring urges the measuring arm toward the non-measuring position.
  • the anvil mounting section is connected to the spindle mounting section for movement relative thereto and that a second biasing means controls the relative movement of the anvil mounting section to the spindle mounting section and absorbs excess gauging pressure.
  • the indicating means comprises a sensing means and an indicator responsive to the sensing means for indicating movement of the anvil means to the measuring position.
  • the sensing means comprises a pair of contacts actuated by movement of the anvil means and the indicator is a light in circuit with the contacts.
  • a micrometer which comprises: a frame having an anvil mounting section and a spindle mounting section; anvil means mounted to the anvil mounting section; a
  • spindle threadably mounted in the spindle mounting section for axial movement; a gear mounted on the spindle and having gear teeth; and a rotatable drive sleeve having internal gear teeth engaged with the gear teeth of the gear for rotating the spindle and causing it to move axially, the drive sleeve having a control knob mounted externally of the spindle mounting section to enable rotation of the drive sleeve.
  • the internal gear teeth of the drive sleeve have the same shape asthe gear teeth of the gear on the spindle. It is also preferred that the internal gear teeth of the drive sleeve are larger than the gear teeth of the gear to produce a sloppy fit of the drive sleeve with the gear.
  • the internal gear teeth of the drive sleeve preferably extend exteriorly of the spindle mounting section into the control knob to permit the spindle to be withdrawn from the anvil means and to extend exteriorly of the spindle mounting section.
  • FIG. 1 is a perspective view of a micrometer constructed in accordance with the teachings of the present invention showing its use for measuring a disc brake rotor.
  • FIG. 2 is a longitudinal sectional view of the micrometer of FIG. lwith a front plate of its spindle mounting section and a counter mask for a counter mechanism removed for clarity, and shows the internal mechanisms of the micrometer.
  • FIG. 3 is a vertical sectional view taken along lines 3+3 of FIG. 2 showing the keying of the spindle to a drive gear.
  • FIG. 4 is an end view of the micrometer as viewed from the left end of the micrometer of FIG. 1.
  • FIG. 5 is a partial perspective view of the micrometer of FIG. l and shows the anvil mounting section of the micrometer in greater detail.
  • FIG. 6 is a vertical sectional view taken along lines 66 of FIG. 2.
  • FIG. 7 is a perspective view in open position of a front plate and a back plate that form the spindle mounting section of the micrometer of FIG. 1 when the plates are brought together in mating position.
  • Flg. 8 is an exploded perspective view, partially in section, of a drive mechanism for rotating the spindle of the micrometer.
  • FIG. 9 is a partial perspective view of a pivotal mounting of the anvil mounting section to the spindle mounting section with the front plate of the spindle mounting section removed for clarity, and shows in phantom line the normal position of the anvil mounting section relative to the spindle mounting section and in full line a pivoted position of the anvil mounting sectron.
  • FIG. 10 is a perspective view of a plastic support for housing electrical elements in the anvil mountng section of the micrometer.
  • FIG. 11 is a perspective view of a choker plate used for positioning a counter mechanism in the micrometer.
  • FIG. 12 is a partial perspective view of an adjusting means for adjusting the resilient pressure of a coil spring used to control the movement of the spindle.
  • the present invention is embodied in a micrometer, generally 10, for measuring the thickness of a rotor, generally 12, of a disc braking system.
  • Rotor 12 comprises two spaced apart annular rotor plates 14 and 16.
  • Rotor plate 14 has an outside frictional surface 18
  • rotor plate 16 has an outside frictional surface 20.
  • Frictional brake pads (not shown) are mounted closely adjacent each rotor plate 14 and 16 and are brought into contact with frictional surfaces 18 and 20 when a braking force is required.
  • the thickness d" between the outside frictional surfaces 18 and 20 of rotor plates 14 and 16 is also important in determining the safety of the disc brake'rotor, and the micrometer of the present invention is designed to individually measure the thickness of each of the plates 14 and 16.
  • the micrometer includes a frame having an anvil mounting section and a spindle mounting section.
  • the frame generally 21, comprises a spindle mounting section, generally 22, in the form of a housing, and an anvil mounting section, generally 26, connected to the spindle mounting section.
  • spindle mounting section 22 is preferably comprised of a front plate 28 and a back plate 30 which are secured to each other by conventional means, such as by screws 32. (FIG. 1).
  • Front plate 28 and back plate 30 have a number of corresponding elements which are identically shaped, but which are the reverse of each other so that when the plates are brought together, the corresponding elements in each plate are aligned and cooperate to form a final element of spindle mounting section 22.
  • a single reference numeral will be used to identify the corresponding elements in each plate and the final element, with an unprimed numeral identifying the final element, a single primed numeral identifying an element of front plate 28 and a double primed numeral identifying the corresponding element of back plate 30.
  • front plate 28 has a semi-circular opening 34 at the top ofa side wall 36
  • back plate 30 has a corresponding semi-circular opening 34" at the top of corresponding side wall 36".
  • semicircular openings 34' and 34" cooperate to form full a full opening 34 (FIG. 2) in side wall 36 of spindle mounting section 22.
  • the primed and double primed numbers are found with reference to FIG. 7 and the unprimed numbers are found in the remaining figures.
  • Front plate 28 comprises a first side wall 36', an opposing second side wall 38', a top wall 40, and a front wall 44.
  • back plate 30 comprises a first side wall 36", an opposing second side wall 38", a top wall 40", and a back wall 42.
  • Top walls 40' and 40 are each curved and thus form a curved top wall 40 of spindle mounting section 22.
  • the bottoms of front and back plates 28 and 30 are open to form an opening at the bottom of spindle mounting section 22.
  • Spindle mounting section 22 as described in greater detail hereafter, has a number of cavities for receiving the various mechanisms and parts of the present micrometer which are described in detail hereafter.
  • anvil mounting section 26 comprises an L-shaped housing having a base, generally 46 and a perpendicularly extending support arm, generally 48, and is defined by an L-shaped front plate 50, an L-shaped back plate 52, a vertical side wall 54 joining the inner ends of the support arms of plates 50 and 52, and a horizontially extending top wall 56 at the bottom of side wall 54 closing the top of base 46.
  • front plate 50 and back plate 52 are spaced apart to define an interior opening having a narrow top section 58 which expands into a wider bottom section 60 that begins immediately above top wall 56. Shoulders 62 are formed at the point where the interior opening expands from top section 58 to bottom section 60.
  • Vertical side wall 54 of anvil mounting section 26 opposes side wall 36 of spindle mounting section 22, and these walls together with top wall 56 of anvil mounting section 26 and an anvil measuring arm, generally 64, secured to the top of front and back plates 50 and 52, form the conventional U-shaped measuring end of the micrometer where the workpiece to be measured is placed.
  • the distance between side wall 36 of spindle mounting section 22 and vertical wall 54 of anvil mounting section is slightly greater than two inches to permit workpieces ranging in length from zero to two inches to be measured by the micrometer of the present invention.
  • a spindle having a threaded section is mounted in the spindle mounting section for axial movement.
  • the spindle generally 66, comprises a smooth cylindrical front measuring section 68 that passes through side wall 36 of spindle mounting section 22 and a back threaded section 70.
  • the front end of measuring section 66 has a spherical measuring tip 72 which can be made from a carbide material or any other suitably hardened material.
  • a bearing 74 is secured in opening 34 at the top of side wall 36 and measuring section 68 passes through this bearing.
  • a drive gear 76 is mounted within spindle mounting section 22 on measuring section 68 adjacent opening 34 by means of a key 78, best seen in FIG. 3, which rides in a longitudinally extending keyway on the outer surface of measuring section 68 and internal keyway 82 in gear 76.
  • Key 78 is square and made of key stock. As viewed in FIG. 2, key 78 is inserted into keyway 82 of drive gear 76 and keyway 80 of measuring section 68 from the right. Bearing 74 prevents key 78 from further moving to the left into keyway 80 of measuring section 68 and out of keyway 82 of drive gear 76.
  • a choker and calibrating plate is pivotally mounted about spindle 66 adjacent spindle drive gear 76 to prevent key 78 from leaving keyway 82 of drive gear 76 to the right. Rotation of spindle 66 thus produced a corresponding rotation of drive gear 76.
  • Threaded section 70 is slightly greater than two inches to permit spindle 66 to move through a two inch measuring range.
  • Threaded section 70 has a pitch diameter of 0.4050 inches and is provided with 20 threads to the inch of the inclined plane type of thread form.
  • thread form refers to the profile on cross-section of the thread.
  • V-type thread forms are used and the right handed American National Unified thread is particularly preferred.
  • a spur gear 86 is mounted on the back end of threaded section 70 of spindle 66.
  • Spur gear 86 is preferably made of brass and has sixteen gear teeth 88, a pitch diameter of 0.500 inches, a pressure angle of 149?, a 32 pitch, and a center hole opening of 3/l6 inches.
  • a spindle drive sleeve generally 90, having internal gear teeth 92 that mate with teeth 88 of spur gear 86 engages spur gear 86 to drive spindle 66.
  • Spindle drive sleeve 90 includes a control knob 94 on one of its ends and a radially outwardly extending flange 96 on its other end.
  • a cylindrical casing 98 (FIG. 2), formed by a semicylindrical casing 98 (FIG.
  • Casing 98 has alternating cylindrical ribs 100 and relief areas 102, and is open at both of its ends. One open end of casing 98 is formed in side wall 38 of spindle mounting section 22 and the other open end terminates in a relief area 102. Flange 96 is positioned in this end relief area and abuts against adjacent rib 100. Control knob 94 is positioned exteriorly of spindle mounting section 22 and abuts against side wall 38 of the spindle mounting section.
  • drive sleeve 90 has a longitudinally extending bore 91 having a plurality of longitudinally extending internal teeth 92 equal in number to and mating with teeth 88 on spur gear 86.
  • Rotation of drive sleeve 90 through control knob 94 thus produces a corresponding rotation of spindle 66, and since spindle 66, as described in greater detail hereafter, rotates under the control of a thread, its rotation causes it to move longitudinally toward or away from anvil measuring arm 64 depending on its direction of rotation.
  • the length of internal teeth 92 is such that threaded section 70 of spindle 66 can extend into drive sleeve 90 sufficiently far to withdraw.
  • the length of internal teeth 92 is slightly larger than 2 inches to permit spindle 66 to be withdrawn 2 inches from measuring arm 64 and enable measurement of 2 inch workpieces.
  • bore 91 and internal teeth 92 extend exteriorly of spindle mounting section 22 into control knob 94 for a substantial portion of their length, and as here embodied, extend approximately half their length into control knob 94.
  • bore 91 and internal teeth 92 extending into control knob 94, when spindle 66 is fully withdrawn, a portion of its back threaded section 70 is actually outside of spindle mounting section 22.
  • the use of a drive sleeve having a positive drive portion outside of spindle mounting section 22 enables a reduction in the size of the spindle mounting section needed to house spindle 66.
  • Internal gear teeth 92 of spindle drive sleeve 91 differ from the teeth on a conventional internal gear which have a different shape than and a close tolerance fit with their mating external gear teeth in that the roots of internal teeth 92 of the present invention have the same shape as the crests of teeth 88 on spur gear 86,
  • an anvil means is mounted on the anvil mounting section and is movable relative to the spindle mounting section from a nonmeasuring position to a measuring position upon the creation of a gauging pressure by a workpiece that is being measured between the anvil means and the spindle.
  • an anvil means generally 104, comprises anvil measuring arm 64 pivotally secured to the top of anvil mounting section 26 and a spherical anvil head 1106 secured to the top of measuring arm 64 by conventional means.
  • Anvil head 106 serves as the reference point from which all measurements are taken.
  • Anvil head 106 is made of a suitably hardened material that resists wear, such as a carbide material, and lies along the line of measurement A" of the workpiece being measured.
  • measuring arm 64 comprises a top section 108, a center section 110 having a hole 112 through which a pivot pin 114 extends, and a bottom vertically extending section 116 which is offset from top section 1118.
  • vertical side wall 54 of anvil mounting section 26 has a U-shaped cutout 118 at its top.
  • Center section 110 of measuring arm 64 is pivotally mounted in cutout 118 between front wall 50 and back wall 52 about pivot pin 114.
  • Pivot pin 114 has its opposite ends secured in walls 50 and 52.
  • Top section 108 of measuring arm 64 thus extends upwardly out of anvil mounting section 26 and bottom section 116 is substantially enclosed by the anvil mounting section.
  • offset bottom section 116 of measuring arm 64 is spaced from the inside surface of vertical wall 54.
  • Measuring arm 64 normally is in a non-measuring vertical position as shown in full line in FIG. 2, and is movable to a measuring position about pivot pin 114 as shown in phantom line in FIG. 2.
  • a first biasing means in the form of a spring 120 biases measuring arm 64 for movement relative to spindle mounting section 22 and absorbs normal gauging pressure.
  • Bottom section 116 of measuring arm 64 has a cylindrical recess 122 and spring 120 is mounted within this recess with one of its ends abutting against the inside surface of vertical wall 54 of anvil mountings section 26 and its other end seated in recess 122.
  • Measuring arm 64 is thus biased to continuously urge measuring arm 64 to its vertical non-measuring position and anvil head 106 toward spindle 66.
  • anvil mounting section 26 is pivotally connected to spindle mounting section 22 for relative movement thereto and a second biasing means, generally 124, controls the relative movement of anvil mounting section 26 to spindle mounting section 22 and absorbs excess gauging pressure.
  • a solid cross block 126 is integrally formed with front wall 50 and back wall 52 of anvil mounting section 26 to joint these walls at the bottom portion of base 46 immediately adjacent spindle mounting section 22.
  • front plate 50 and back plate 52 of base 46 adjacent spindle mounting section 22 are inclined from their bottom upwardly toward the interior of spindle mounting section 22, and as best seen in FIG. 2 back plate 52 has an inclined end 128 and as best seen in FIG. 9 front plate 50'has an inclined end 130.
  • Cross block 126 has a curved outer end 132 with extends past inclined ends 128 and toward the interior of spindle mounting section 22 and an inner end 134 which extends into the interior of base 46 of anvil mounting section 26.
  • Side wall 36 of spindle mounting section 22 has a curved cutout 136 at its bottom shaped to conform with and receive curved outer end 132 of cross block 126. As best seen in FIG. 7, cutout 136 is formed by a cutout 136' in side wall 36" and a corresponding cutout 136" in side wall 36".
  • Front wall 44 of spindle mounting section 22 has an opening 138 aligned with the center of cutout 136 and back wall 42 has a similar opening 140.
  • a pivot pin 142 extends through openings 138 and 140, and through cross block 126 to pivotally mount the cross block, and hence anvil mounting section 26 to spindle mounting section 22.
  • An inclined surface 144 extends upwardly from the top edge of curved cutout 136 toward the interior of spindle mounting section 22 and in normal position this surface mates with the inclined ends 130 and 128 of front and back plates 50 and 52 of anvil mounting section 26.
  • the ends of front wall 44 and back wall 42 of spindle mounting section 22 ad-.
  • jacent base 46 of anvil mounting section 26 overlie and cover inclinded ends 128 and 130 and curved outer end 132 of cross block 126.
  • inclined surface 144 of anvil mounting section 26 separates from inclined ends 128 and 130, but the greatest amount of movement permitted is such that front wall 44 and back wall 42 still overlie inclined ends 128 and 130 and curved outer end 132 of cross block 126 so that these parts are not exposed during movement of anvil mounting section 26.
  • second biasing means 124 comprises a bolt 146, a die spring 148 mounted about the bolt, and an abutment 150 for compressing die spring 148 to absorb excess gauging pressure.
  • bolt 146 is mounted immediately below horizontal wall 56 of anvil mounting section 26 between front and back walls 50 and 52.
  • bolt 146 has a smooth shaft 147 which terminates in a first end 152 that passes through an opening 154 in inclined surface 144 of side wall 36 of spindle mounting section 22. The terminal portion of end 152 is threaded. Opening 152 expands into a second larger opening 156 in side wall 36 and a nut 158 is threaded into end 152 in opening 156.
  • Nut 158 has a curved end surface which abuts against a shoulder 160 formed at the point where opening 152 expands into opening 156. End 152 is thus captured within opening 156 of spindle mounting section 22.
  • the opposite end of bolt 146 has a slotted head 162 which serves as a stop for die spring 148.
  • Die spring 148 is mounted about bolt 146 adjacent slotted head 162 and is characterized by two flat ends which prevent cocking or canting of the spring. Two spring caps, 164 and 166, are positioned between bolt 146 and die spring 148 at each end of the die spring to center the die spring on the bolt. One end of die spring 148 seats against slotted head 152 of bolt 146 while its other end seats against abutment 150. Shaft 147 of bolt 146 passes through an opening in abutment 150. Abutment 150 is fixed to front plate 50 and back plate 52 of anvil mounting section 26 and moves with the anvil mounting section while it pivots about pin 142. Die spring 148 continuously biases anvil mounting section 26 and measuring arm 64 toward spindle mounting section 22.
  • indicating means responsive to the relative movement of the anvil means is provided for indicating the movement of the anvil means from the non-measuring position to the measuring position.
  • the indicating means comprises a sensing means, generally 168, for sensing movement of the anvil means, and an indicator in the form of a light 170, responsive to the sensing means for indicating movement of the anvil means to a measuring position.
  • Sensing means 168 includes a first contact 172 connected to measuring arm 64 and a second contact 174 mounted to vertical wall 54.
  • Measuring arm 64 has a threaded hole 176 transversely extending completely through bottom section 116 below recess 122.
  • a screw 178 having a slotted head on one end is received in this hole and contact 172 is mounted on the opposite end of the screw.
  • An L-shaped metal bracket 180 is secured to the inside surface of vertical side wall 54 of anvil mounting section 26, but is electrically insulated therefrom by conventional means, such as by a plastic insulating sheet 182 positioned between the wall and bracket. Insulating sheet 182 is secured to wall 54 by a suitable adhesive such as an epoxy adhesive, and bracket 180 is similarly secured to the opposite side of the sheet.
  • Second contact 174 is mounted at the top of bracket 180 and is normally spaced from and aligned with first contact 172.
  • Support 186 is removably insertable into the base 46 of anvil mounting section 26 between front plate 50 and back plate 52 and has an outer peripheral shape which conforms to the outer shape of base 46. As best seen in FIGS. 2 and 10, support 186 has a cavity 188 for receiving a power source in the form of two batteries 190 and 192 which are connected in series one above the other by a metal strip 194.
  • Support 186 has a horizontally extending overhang 196 at one end which fits over inner end 134 of cross block 126 when the support is property located in anvil mounting section 26.
  • Support 186 has an upwardly extending projection 198 at its other end which abuts against shoulders 62 of front plate 50 and back plate 52 of anvil mounting section 26.
  • support 186 has two aligned projecting semicircular locking spheres 200, one on each side of the support. Spheres 200 are engageable in aligned detent openings 201 in front plate 50 and back plate 52 to firmly position support 186 in mounting section 26.
  • Support 186 can be partially removed from anvil mounting section 26 by applying pressure to projection 198 to overcome the detent force and pivot the support about cross block 126 to expose cavity 188 and socket 184 and enable replacement of batteries 190 and 192 and light 170.
  • Light 170 is connected to bracket by an electric lead 202 and is connected to battery by a second lead 204.
  • a third lead 206 connects battery 192 to screw 178.
  • front plate 50 and back 52 of anvil mounting section 26 each have a plastic dome 208 adjacent light 170 so that when light 170 is actuated, it is visible from either side of the micrometer.
  • a direct reading counter mechanism is connected to the spindle.
  • a conventional counter mechanism generally 210, is mounted within spindle mounting section 22 adjacent side wall 36.
  • Counter mechanism 210 includes a U-shaped counter frame 212 having parallel ends 214 and 216 and four counting wheels 218, 220, 222, and 224 which are all mounted on a rotatable common drive shaft 226 extending through ends 214 and 216 of frame 212.
  • Drive shaft 226 is operatively connected to counting wheel 224 which indicates the lowest unit of measurement of the micrometer. Rotation of drive shaft 226 thus produces a corresponding rotation of counting wheel 224.
  • Front wall 44 of front plate 28 has a window 228 (FIGS. 1 and 7) which contains a clear plastic. Window 228 is positioned over the counting wheels to permit the indicia on them to be easily viewed.
  • a counter mask 229 (FIG. 1) covers counter mechanism 210, but has openings to permit the indicia on the counting wheels to be viewed through window 228 of front plate 28.
  • a counter drive gear 230 is fixed to the end of drive shaft 226 adjacent end 216 of frame 212 so that rotation of drive gear 230 produces a rotation of drive shaft 226 and actuation of the counting wheels.
  • Counter drive gear 230 is connected to drive gear 76 mounted on measuring section 68 of spindle 66 by an intermediate transmission gear 232 which has a two gear cluster, one of which is engaged with drive gear 76 and one of which is engaged with countEr drive gear 230.
  • back wall 42 of back plate 30 has two spaced apart end support blocks 234 and 236, and parallel ends 214 and 216 of counter mechanism 116 are mounted on these blocks.
  • Back wall 42 also contains a drive shaft support block 238 having a central opening 240 (FIG. 7).
  • Front wall 44 of front plate 28 has first and second shaft positioning blocks 242 and 244 which mate with the ends of drive shaft support block 238.
  • Drive shaft 226 of counter mechanism 210 has one of its ends mounted in opening 240 of drive shaft support block 238 and its other end held by choker plate 84 so that the counter mechanism is maintained in proper position in spindle mounting section 22.
  • Choker plate 84 positions counter mechanism 210 in spindle mounting section 22 by means of an arcuate slot 246 (FIG.
  • Choker plate 84 can be easily disengaged from drive shaft 226 by pivoting it around spindle 66 when front plate 28 is removed from back plate 30.
  • Counter mechanism 210 can then be easily lifted out of drive shaft support block 238 and disengaged with intermediate gear 232 to permit the counter mechanism to be calibrated.
  • Choker plate 84 also functions to keep gears 76 and 232 from binding when spindle 66 is withdrawn from the measuring end of the micrometer.
  • spindle 66 is rotated so as to withdraw measuring section 68 from anvil head 106 a back pressure is created on drive gear 76 which tends to force it against the side of gear 232, and thereby bind gears 76 and 232 against each other and prevent further withdrawal of spindle.
  • Choker plate 84 opposes this binding force and permits spindle 66 to be easily withdrawn without binding.
  • a straight keeper wire 248 is positioned between a block 252, described in greater detail hereafter, and choker plate 84 to apply pressure to the choker plate to enable it to overcome the binding back pressure of the gears.
  • a control nut for controlling movement of the spindle.
  • the control nut extends partially around a longitudinal portion of the threaded section of the spindle and has threads mating with those of the threaded section of the spindle.
  • the control nut comprises a first half nut 250 which extends around a top longitudinal portion of threaded section 70 of spindle 66.
  • Half nut 250 has V-type American National Unified Thread forms which mate with the thread forms of spindle 66.
  • Half nut 250 as best seen in FIG. 8, has a curved top and this top fits within the curvature of top wall 40 of spindle mounting section 22.
  • a locating and retaining block 252 (FIG. 2) formed by a block 252' in front plate 28 and a block 252" in back plate 30 is spaced from the inner end of casing 98 and half nut 250 is mounted in the space between casing 98 and block 252.
  • Block 252 has an opening 254 and spindle 66 passes through this opening.
  • the threaded length of the control nut is about twice the pitch diameter of threaded section 70 of spindle 66.
  • the provision of a threaded length which is twice the pitch diameter of spindle'66 spreads and distributes the wear between the spindle and control nut over a greater length and reduces the wear on any one threaded portion. It has been found that a threaded length for the control nut of at least twice the pitch diameter of spindle 66 is the minimum length which will be effective in markedly reducing wear on the threads, and thus it is highly desirable to provide such a relationship in the micrometer of the present invention.
  • resilient force applying means acts transverse to the axis of the spindle to continuously urge the mating threads of the spindle and control nut into tight engagement with each other to maintain the roots and crests of the threads of the spindle in continuous alignment with the roots and crests of the control nut and provide for accurate readings of the micrometer.
  • this force applying means acts perpendicularly to the axis of spindle 66 and comprises a second nut means in the form of a second half nut 256 which is aligned with and opposes first nut 250, and a biasing means in the form of a resilient coil spring 258 engaged with second nut 256.
  • First nut 250 and second nut 256 are spaced from each other about the circumference of threaded section 70 of spindle 66 and are continuously urged toward each other by coil spring 258, but are sized so that they do not engage each other.
  • half nut 256 has a centrally located circular recess 260 on its bottom surface 262.
  • Coil spring 258 has its top end seated in recess 260 and its bottom end seated in a slotted end 264 of a screw 266.
  • Screw 266 is threadably mounted in a pair of nuts 268 and 270 that are separated by a washer.
  • a pair of opposing U-shaped members 274 and 275 (FIG.
  • a straight cross-leg 277 extends from and diameterically intersects the bottom coil of coil spring 258, and this cross-leg is seated in screw 266.
  • Screw 266 is identically slotted at both of its ends to permit either end of the screw to be inserted into nuts 268 and 270 when the micrometer is assemmoving from the housing a magazine, generally 276, described in greater detail hereafter. Because cross-leg 277 is diametrically positioned on coil spring 258 and recess 260 is at the center of half nut 256, the resilient pressure of the coil spring is evenly distributed to bottom half nut 256 to enable it to respond evenly to changes in the thread of spindle 66. Second nut 256 is a freely floating nut and its longitudinal axis is free to rock radially with respect to the axis of spindle 66.
  • the length of the threads of second nut 256 is greater than twice the pitch diameter of spindle 66 to more evenly distribute the wear on the threads of second nut 256 and spindle as discussed above.
  • nuts 250 and 256 are both movable and free to move in a longitudinal direction during movement of spindle 66. To obtain accurate and reproducible measurements, at least one of these nuts must be at a set distance from anvil head 106 when the anvil head and measuring arm 64 are in their measuring position as shown in phantom line in FIG. 2.
  • means are provided for positioning control nut 250 at a set longitudinal distance from anvil head 106 when measuring arm 64 is in its measuring position. As here embodied, this means is the inner end of casing 98.
  • Casing 98 aids in positioning both nuts 250 and 256 at a set distance from anvil head 106 because when spindle 66 engages a workpiece, a back pressure is created which is transmitted to nuts 250 and 256.
  • nuts 250 and 256 move longitudinally until they contact the end of casing 98 which is longitudinally fixed and thereby positions the nuts in the same longitudinal alignment whenever a measurement is made.
  • Magazine 276 is mounted below counter mechanism 210 between side walls 36 and 38 of spindle mounting section 22.
  • Magazine 276 includes a frame, generally 278 having two opposed outside walls 280 and 282, a bottom wall 284, a top wall 286, a back wall 288, and a front wall 290.
  • a floor plate 292 provides a hand grip for grasping magazine 276 so that it can be inserted into or removed from the open bottom of spindle mounting section 22.
  • Front wall 290 is made of transparent plastic to enable an information tape 294 to be viewed from the front of the magazine.
  • Tape 294 is wound on two spaced apart spools 293 and 295 that are journaled for rotation in magazine 276.
  • An inner side wall 296 is spaced from outside wall 280 of magazine 276 and spools 293 and 295 are journaled in this inner wall and outside wall 282 through drive pins 298 and 300.
  • a slot 297 is formed in side wall 36. Slot 297 serves as a guide for drive pins 298 and 300 adjacent outside wall 282 of magazine 276.
  • Spools 293 and 295 are connected to each other by a positive drive means so that rotation of one of the spools produces an equal and corresponding rotation of the other.
  • a rotatable member in the form of a drive gear 302 is secured to drive pin 298 between inner wall 296 and outside wall 280 of magazine 276.
  • a second rotatable member in the form of a drive gear 304 is secured to drive pin 300 between inner wall 296 and outside wall 280.
  • a series of intermediate gears connect drive gears 302 and 304 so that rotation of drive gear 302 produces a rotation of drive gear 304 and of spools 293 and 295.
  • the provision of a positive drive for both spools aids in obtaining an even drive to tape 294.
  • other means can be used to provide a positive drive, such as, for example, a bead chain, sprocket chain or ladder chain and appropriate rotatable members for these chains.
  • a connecting means in the form of a straight pin 312 is attached off center to drive gear 302, but parallel to the axis of drive pin 298, for inserting magazine 276 in spindle mounting section 22 and connecting it to a magazine drive means.
  • the magazine drive means includes a magazine drive plate, generally 314, which opposes drive gear 302 of magazine 276.
  • a rotatable control knob 316 is mounted externally of spindle mounting section 22 in alignment with drive gear 302.
  • Control knob 316 has a shaft (not shown) which extends through wall 38 of spindle mounting section 22 and magazine drive plate 314 is fixed to this shaft internally of the housing.
  • Drive plate 314 has at least one radially extending slot 318 which begins at its outer edge and when magazine 276 is in operative position in spindle mounting section 22, pin 312 is engaged in one of these slots.
  • Rotation of control knob 316 causes drive plate 314 to rotate and because pin 312 is engaged in a slot 318 of the drive plate, drive gear 302 will also rotate. This rotation of drive gear 302 produces a corresponding rotation of spools 293 and 295 thereby moving tape 294.
  • Magazine 276 can be inserted into spindle mounting section 22 and connected to magazine drive plate 314 by having pin 312 engage slot 318. If magazine drive plate 314 is not in a position where its slot 318 is aligned with pin 312, it can be rotated by control knob 316, to bring its slot into aligned position with pin 312.
  • Outside wall 280 has a circular opening (not shown) at its top to permit pin 312 to rotate with drive gear 302 and be connected to magazine drive plate 314.
  • Tape 294 is divided longitudinally into sections, with each section listing a car model, car year, and discard thickness for the disc brake rotor for that car.
  • Each section of tape 294 is in alphabetical order so that the discard thickness for a particular car can easily be determined by rotating the tape until the desired section appears in a window 320 (FIGS. 1 and 7) of front plate 28 of spindle mounting section 22. Window 320 contains a clear plastic.
  • the disc brake rotor size is then determined by miking the rotor, and this size is compared to the discard thickness indicated on the magazine. If the actual micrometer size is larger than the discard thickness, the rotor can still be used, but if it is smaller, the rotor is unsafe and should be discarded and 17 replaced.
  • magazine 276 can be removed, and replaced with a new magazine having a new tape with the revised information for the new model year.
  • tape 294 needed for storing all of the information necessary in readily viewable size to determine the thicknesses of rotors for all of the various years, makes and models of cars is approximately six feet and preferably feet. This length of tape cannot be easily wound on spaced apart spools and be freely rotated from one end to another on these spools in a magazine without having the tape sag, bunch up, or jam.
  • tape 294 is made of a plastic film having elastic recovery so that a spring-like action is provided on the magazine spools which together with the direct drive of both spools enable six to ten feet of tape to evenly move from one spool to another without any winding problems.
  • Suitable tapes for this purpose can be made of any plastic film which is resilient and exhibits elastic recovery.
  • differentially stressed spring-like plastic films of, for example, polyethylene terephthalate (sold under the trademark Mylar by du Pont Company) polyamides (e.g. nylon), polyacrylonitrile, and copolymers of acrylonitrile with other vinyl compounds, copolymers of vinyl chloride and vinylidene chloride, and polyhydrocabrons (e.g. polyethylene and polypropylene can be used in making tapes 294.
  • the resilient nature of tape 294 tends to force it against front wall 290 of magazine 276 so that the plane of the tape is parallel to the plane of front wall 44 of front plate 28. Tape 294 thus tends to ride against front wall 290.
  • the resilient nature of tape 294 also permits the rotating force of drive gear 302 to be transmitted to the tape without any lost motion so that the tape immediately responds to rotation of drive 302 in an even manner.
  • the micrometer of the present invention can be used to measure workpieces other than disc brake rotors without departing from the scope of this invention. Accordingly, the information on tape 294 can be tailored for use with other systems where it is important to have a readily available source of indicating measurements.
  • the micrometer of the present invention is extremely accurate, and its counting wheel 224 is provided with ten equally spaced digits for reading in thousandths of an inch.
  • the present invention thus provides a micrometer of two inch capacity reading to thousandths of an inch on one line, in a single final group of numbers in which no verniers need be scrutinized.
  • the micrometer can be made to read in dimensions other than inches, such as for example millimeters.
  • locking means are provided on the magazine to lock it into position in spindle mounting section 22.
  • this means comprises a flat leaf spring 322 that is secured to outside wall 280 of magazine 276.
  • Leaf spring 322 comprises an anchor leg 324 attached to outside wall 280, and a downwardly extending locking leg 326 that is angled away from outside wall 280 and toward side wall 38 of spindle mounting section 22.
  • Side wall 38 has an inner lip 328 and when magazine 276 is inserted far enough into spindle mounting section 22, locking leg 326 of leaf spring 322 engages this lip and prevents the magazine from being removed from the spindle mounting section.
  • Top wall 286 of magazine 276 abuts against U-shaped member 274 and 275 when locking leg 326 engages lip 328 to prevent movement of the magazine within spindle mounting section 22.
  • a keyway 330 is provided in side wall 38 adjacent the locked position of leaf spring 322.
  • a key 332 such as a house key or car key, is inserted into keyway 330 to depress locking leg 326 clear from lip 328. While locking leg 326 is depressed, magazine 276 can be grasped by floor plate 292 and removed from spindle mounting section 22. When inserting magazine 276 into spindle mounting section 22 locking leg 326 cannot lock into lip 328 until connecting pin 312 engages in magazine drive plate 314.
  • a workpiece is positioned between measuring arm 64 and spindle 66 and control knob 94 is rotated to advance the spindle toward the measuring arm.
  • spindle 66 advances to the point where its tip 72 and anvil head 106 of measuring arm 64 both contact the workpiece, a gauging pressure develops.
  • measuring arm 64 of the present invention moves about pivot 114 to their measuring position illustrated in phantom line in FIG. 2, under the control of spring which absorbs energy and thus lessens the amount of gauging pressure that is developed on the anvil.
  • Spring 120 is under an initial slight predetermined compression when measuring arm 64 is in its vertical non-measuring position, illustrated in full line in FIG.
  • measuring arm 64 As measuring arm 64 moves about its pivot 114, spring 1220 comes under greater compression and the gauging pressure on the workpiece increases. The gauging pressure for any given position of measuring arm 64, however, is constant due to the action of spring 1120. Thus, when measuring arm 64 reaches its measuring position, the gauging pressure at this position is always the same. When measuring arm 64 reaches its measuring position, contact 172 at the bottom of the measuring arm engages contact 174 on bracket 180 to close the electrical circuit to light and actuate the light.
  • the gauging pressure of the micrometer of the present invention when measuring arm 64 is in its measuring position can be set and maintained at a relatively low level by the selection of a spring having appropriate spring characteristics and can be as low as 6-10 p.s.i.
  • gauging pressures developed by conventional micrometers on the anvil can be in the range of 20,000 p.s.i. to 30,000 p.s.i., especially when the micrometer is misaligned. ln the present invention, excessive gauging pressures caused by misalignment or canting of the micrometer on the workpiece are prevented from developing by die spring 148 of second biasing means 124.
  • measuring arm 64 can move past its measuring position a slight distance, but this movement is due to the inherent elastic properties of contacts 172 and 174 and their supporting structure so that only a small movement is possible before a nonresilient coupling of measuring arm and bracket 180 is produced whereupon the gauging pressure would begin to increase rapidly and cause a high stress concentration on anvil head 106 and measuring arm 64.
  • Spring 120 cannot absorb this pressure because the further compression of the spring necessary to absorb it is prevented by the non-resilient coupling of measuring arm 64 and bracket 180.
  • Anvil mounting section 26 is pivotable about pivot 142, and moves about pivot 142 from its normal position (FIG. 9 phantom line position) where ends 128 and 130 of back plate 52 and front plate 50 abut against inclined surface 144 of side wall 36 of spindle mounting section 22, away from spindle mounting section 22 to a position where ends 128 and 130 do not abut against inclined surface 144 (HO. 9 full line position), when measuring arm 64 couples to bracket 180.
  • Abutment 150 moves with anvil mounting section 22 and compresses die spring 148 against slotted head 162 of bolt 146 to enable the die spring to absorb energy and prevent excessive gauging pressures from developing even though the micrometer in misaligned or canted on the workpiece.
  • Die spring 148 is a spring which can absorb large amounts of energy. As soon as the force that causes die spring 148 to compress is lessened, the die spring begins returning anvil mounting section 26 to its normal position where ends 128 and 130 of back plate 52 and front plate 50 abut against inclined surface 144 of side 36 of spindle mounting section 22. When anvil mounting section 26 returns to its normal position the micrometer is ready to be used in its normal manner.
  • Second biasing means 124 thus prevents excess concentrations of stress from developing on anvil head 106 which can cause permanent distortion of the parts of the micrometer.
  • Second biasing means 124 together with spring 120 provide a biasing means which acts to insure that the same gauging pressure is obtained for each measurement the micrometer makes and which prevents the development of excess gauging pressures which can destroy the reliability of the micrometer.
  • the present invention thus provides a micrometer which insures that the same gauging pressure is applied to a workpiece for each measurement that the micrometer makes, provides a visual indication of when the micrometer reading should be taken, insures that excess gauging pressure does not develop on the anvil of the micrometer as a result of misalignment or other causes, and provides a positive, easily assembled, means for driving the spindle.
  • the various features of the present invention are especially useful with micrometers having a two inch measuring range, such as the micrometers described in the above referred to application Scr. No. 238,340, because these micrometers can more easily generate large stresses on the anvil.
  • the present invention also provides a micrometer which is particularly useful in measuring disc brake rotors and because of the spring biasing of measuring arm 64 can withdraw the spherical measuring tip 72 on spindle 66 and the spherical anvil head 106 from the depth of grooves worn into disc brake rotors up to the smooth surfaces of the rotors without damage to the micrometer.
  • the use of spherical ball contact ends comprising anvil head 106 and measuring tip 72 enables the micrometer of the present invention to measure scored or deeply worn sections of the rotor regardless of the relative positions of the deep scores on each side of the rotor.
  • a micrometer for measuring a workpiece comprismg:
  • an anvil means mounted to said anvil mounting section and movable relative to said spindle and anvil mounting sections from a non-measuring position to a measuring position upon the creation of a gauging pressure by a workpiece that is being measured between the anvil means and the spindle;
  • indicating means responsive to the relative movement of the anvil means for indicating movement of said anvil means to the measuring position
  • a first biasing means for biasing said anvil means for movement relative to said mounting sections and for maintaining the same amount of gauging pressure at said measuring position for each measurement that the micrometer makes; and a second biasing means connecting said mounting section and spindle mounting section for controlling the relative movement of the anvil mounting section to the spindle mounting section and absorbing gauging pressure in excess of that which can be absorbed by said first biasing means.
  • micrometer of claim 1 wherein said anvil means includes a measuring arm and said biasing means is a spring engaged with said measuring arm.
  • said second biasing means comprises a bolt mounted in said anvil mounting section and having one end captured in said spindle mounting section, a spring mounted about said bolt in said spindle mounting section, and an abutment fixed to and movable with said anvil mounting section for compressing said spring to absorb excess gauging pressure.
  • said indicating means comprises a sensing means for sensing movement of said anvil means and an indicator responsive to said sensing means for indicating movement of the anvil means to the measuring position.
  • said sensing means comprises a pair of contacts actuated'by movement of said anvil means, and said indicator is a light in circuit with said contacts.
  • said indicating means comprises an electric circuit including a light operated upon movement of said anvil means to the measuring position.
  • micrometer of claim 1 including a gear mounted on said spindle and having gear teeth, and a drive sleeve having internal gear teeth engaged with the gear teeth of said gear for rotating the spindle and causing it to move axially, said drive sleeve having a control knob extending exteriorly of said spindle mounting section to enable rotation of the drive sleeve.
  • the micrometer of claim 13 wherein the spindle has a threaded section, a control nut extends partially around a longitudinal portion of the threaded section and has threads mating with those of the threaded sec tion of the spindle, and resilient force applying means acts transverse to the axis of the spindle to continuously urge the mating threads of the spindle and control nut into engagement with each other to maintain the roots and crests of the threads of the spindle in continuous longitudinal alignment with the roots and crests of the control nut and provide for accurate readings of the micrometer.
  • the resilient force applying means comprises a floating nut means spaced from, non-engaging with, and opposing said control nut and having threads mating with those of said threaded section, and a biasing means engaged with said nut means for urging said nut means against said spindle.
  • micrometer of claim 14 including means for positioning said control nut at a set longitudinal distance from said anvil means when said anvil means is in its measuring position.
  • a micrometer for measuring a workpiece comprising:
  • a rotatable drive sleeve having internal gear teeth engaged with the gear teeth of said gear for rotating said spindle and causing it to move axially, said drive sleeve having a control knob mounted externally of said spindle mounting section to enable rotation of the drive sleeve.
  • micrometer of claim 17 wherein the spindle has a threaded section a control nut extends partially around a longitudinal portion of the threaded section and has threads mating with those of the threaded section of the spindle, and resilient force applying means acts transverse to the axis of the spindle to continuously urge the mating threads of the spindle and control nut into tight engagement with each other to maintain the roots and crests of the threads of the spindle in continuous longitudinal alignment with the roots and crests of the control nut and provide for accurate readings of the micrometer.
  • the resilient force applying means comprises a floating nut means spaced from, non-engaging with, and opposing said control nut and having threads mating with those of said threaded section, and a biasing means engaged with said nut means for urging said nut means against said spindle.
  • a micrometer for measuring a workpiece comprising:
  • anvil means mounted to said anvil mounting section and movable relative to said spindle mounting section from a non-measuring position to a measuring position upon the creation of gauging pressure by a workpiece that is being measured between the anvil means and the spindle, said anvil means including a measuring arm comprising a top section extending above the anvil mounting section and having an anvil head mounted thereon, said measuring arm further including a center section, means pivotally mounting said center section to the anvil mounting section and a bottom section offset from the top section and substantially enclosed by said anvil mounting section;
  • indicating means responsive to the relative movement of the anvil means for indicating movement of said anvil means to the measuring position
  • the resilient force applying means comprises a floating nut means spaced from, non-engaging with, and opposing said control nut and having threads mating with those of said threaded section. and a biasing means engaged with said nut means for urging said nut means against said spindle.
  • micrometer of claim 1 wherein said micrometer is a direct reading micrometer for measuring workpieces of O to 2 inches.

Landscapes

  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Length-Measuring Instruments Using Mechanical Means (AREA)
  • Braking Arrangements (AREA)
US00295225A 1972-03-27 1972-10-05 Micrometer with movable anvil Expired - Lifetime US3845564A (en)

Priority Applications (13)

Application Number Priority Date Filing Date Title
US00295225A US3845564A (en) 1972-03-27 1972-10-05 Micrometer with movable anvil
AU53421/73A AU477173B2 (en) 1972-03-27 1973-03-19 Micrometer with movable anvil
CA166,422A CA985495A (en) 1972-03-27 1973-03-19 Micrometer with movable anvil
CH433373A CH563006A5 (it) 1972-03-27 1973-03-26
FR7310976A FR2178069B1 (it) 1972-03-27 1973-03-27
GB1462173A GB1412073A (en) 1972-03-27 1973-03-27 Micrometer with movable anvil
NL7304271A NL7304271A (it) 1972-03-27 1973-03-27
JP48034219A JPS51108857A (en) 1972-03-27 1973-03-27 Kadoanbirutsuki maikuromeeta
IT22213/73A IT986628B (it) 1972-03-27 1973-03-27 Micrometro ad incudine mobile
US398461A US3871596A (en) 1972-10-05 1973-09-18 Magazine for storing an information tape
BE135959A BE805218A (fr) 1972-10-05 1973-09-24 Micrometre a butee mobile
BR754773A BR7307547D0 (pt) 1972-10-05 1973-09-27 Micrometro para medir uma peca e cartucho para usar num dispositivo micrometrica
AR25617274A AR208894A1 (es) 1972-10-05 1974-10-21 Micrometro

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
US00238340A US3810310A (en) 1972-03-27 1972-03-27 Micrometer measuring devices
US00295225A US3845564A (en) 1972-03-27 1972-10-05 Micrometer with movable anvil

Publications (1)

Publication Number Publication Date
US3845564A true US3845564A (en) 1974-11-05

Family

ID=26931585

Family Applications (1)

Application Number Title Priority Date Filing Date
US00295225A Expired - Lifetime US3845564A (en) 1972-03-27 1972-10-05 Micrometer with movable anvil

Country Status (9)

Country Link
US (1) US3845564A (it)
JP (1) JPS51108857A (it)
AU (1) AU477173B2 (it)
CA (1) CA985495A (it)
CH (1) CH563006A5 (it)
FR (1) FR2178069B1 (it)
GB (1) GB1412073A (it)
IT (1) IT986628B (it)
NL (1) NL7304271A (it)

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20090223074A1 (en) * 2008-03-07 2009-09-10 Lin Wo Gage for measuring disc brake thickness
US20160280200A1 (en) * 2013-11-21 2016-09-29 Philip Stuart Esnouf A device for measuring the thickness of automotive disc brake rotors
US20170108323A1 (en) * 2015-10-15 2017-04-20 Pi-Liang Wu Measuring tool for disc brake device brake pad
CN113375624A (zh) * 2021-07-07 2021-09-10 中国汽车工程研究院股份有限公司 一种商用车制动盘dtv的测量及数据处理方法
US20220268563A1 (en) * 2021-02-25 2022-08-25 Intelligrated Headquarters, Llc Sprocket wear gauge

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
FR2812938A1 (fr) * 2000-08-09 2002-02-15 Cedric Desbouiges Outil de mesure de l'epaisseur des disques de frein

Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
FR332769A (fr) * 1903-06-04 1903-11-06 Antonin Claude Pierre Joseph A Système de palmer perfectionné
US868813A (en) * 1906-10-17 1907-10-22 Charles Scheibenstock Measuring instrument.
US1444565A (en) * 1920-09-01 1923-02-06 Smith John Ciceri Gauge
US2217509A (en) * 1937-11-18 1940-10-08 William J Bryant Gauge
US2294831A (en) * 1941-01-21 1942-09-01 Robert W Carson Apparatus for making very fine measurements
US2463263A (en) * 1945-02-15 1949-03-01 Gordon William Quick-acting screw actuated clamping device
US2493000A (en) * 1945-04-27 1950-01-03 Douglas F Linsley Backlash take-up
US2567483A (en) * 1947-12-03 1951-09-11 Hotine William Screw-thread and nut assembly
US2674806A (en) * 1953-05-07 1954-04-13 Sagona Charles Dial micrometer
US2741848A (en) * 1952-10-21 1956-04-17 Livingston Leo Combination micrometer caliper

Family Cites Families (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2502038A (en) * 1944-11-03 1950-03-28 Norman R Fletcher Micrometer caliper
DE840602C (de) * 1949-07-24 1952-06-03 Wilhelm Dipl-Ing Wilk Spindelverstellung fuer Feinmessgeraete
US2691224A (en) * 1953-08-20 1954-10-12 Thielieke Ernst Direct reading micrometer

Patent Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
FR332769A (fr) * 1903-06-04 1903-11-06 Antonin Claude Pierre Joseph A Système de palmer perfectionné
US868813A (en) * 1906-10-17 1907-10-22 Charles Scheibenstock Measuring instrument.
US1444565A (en) * 1920-09-01 1923-02-06 Smith John Ciceri Gauge
US2217509A (en) * 1937-11-18 1940-10-08 William J Bryant Gauge
US2294831A (en) * 1941-01-21 1942-09-01 Robert W Carson Apparatus for making very fine measurements
US2463263A (en) * 1945-02-15 1949-03-01 Gordon William Quick-acting screw actuated clamping device
US2493000A (en) * 1945-04-27 1950-01-03 Douglas F Linsley Backlash take-up
US2567483A (en) * 1947-12-03 1951-09-11 Hotine William Screw-thread and nut assembly
US2741848A (en) * 1952-10-21 1956-04-17 Livingston Leo Combination micrometer caliper
US2674806A (en) * 1953-05-07 1954-04-13 Sagona Charles Dial micrometer

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
D. A. Bourne, Digital Micrometer, IBM Technical Disclosure Bulletin, Vol. 3, No. 11, April, 1961, page 54. *

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20090223074A1 (en) * 2008-03-07 2009-09-10 Lin Wo Gage for measuring disc brake thickness
US20160280200A1 (en) * 2013-11-21 2016-09-29 Philip Stuart Esnouf A device for measuring the thickness of automotive disc brake rotors
US10493973B2 (en) * 2013-11-21 2019-12-03 Philip Stuart Esnouf Device for measuring the thickness of automotive disc brake rotors
US20170108323A1 (en) * 2015-10-15 2017-04-20 Pi-Liang Wu Measuring tool for disc brake device brake pad
US9897426B2 (en) * 2015-10-15 2018-02-20 Pi-Liang Wu Measuring tool for disc brake device brake pad
US20220268563A1 (en) * 2021-02-25 2022-08-25 Intelligrated Headquarters, Llc Sprocket wear gauge
US11892284B2 (en) * 2021-02-25 2024-02-06 Intelligrated Headquarters, Llc Sprocket wear gauge
CN113375624A (zh) * 2021-07-07 2021-09-10 中国汽车工程研究院股份有限公司 一种商用车制动盘dtv的测量及数据处理方法

Also Published As

Publication number Publication date
NL7304271A (it) 1973-10-01
JPS51108857A (en) 1976-09-27
CA985495A (en) 1976-03-16
FR2178069B1 (it) 1979-06-22
GB1412073A (en) 1975-10-29
AU5342173A (en) 1974-09-19
AU477173B2 (en) 1976-10-14
CH563006A5 (it) 1975-06-13
IT986628B (it) 1975-01-30
FR2178069A1 (it) 1973-11-09

Similar Documents

Publication Publication Date Title
EP0646764B1 (en) Digital display micrometer gauge
US3845564A (en) Micrometer with movable anvil
JPH0239721B2 (it)
US2770050A (en) Gage for rotating test part for peripheral and concentricity gaging
EP0801730A1 (en) Apparatus for inspecting a gear
US4535415A (en) Measurement conversion and visual display instrument
US3810310A (en) Micrometer measuring devices
US1018582A (en) Pressure-gage.
US1145852A (en) Calipers.
US1390432A (en) Gage
US2388582A (en) Method of and apparatus for measuring center spacing
US1204292A (en) Torsion-dynamometer.
US2540961A (en) Pivot arm gear rolling fixture
US4733564A (en) Pressure gauge with a capsule closed by a resilient membrane
US3507049A (en) Spline wear gauge
US3936943A (en) Measuring system
CN109421016A (zh) 锁紧工具
US4213247A (en) Thread compliance gauge
JP2759756B2 (ja) 照明付きタイヤゲ−ジ
US3691640A (en) Disc brake rotor thickness wear and score depth gauge and method of using same
US2616185A (en) Spacing gauge assembly for mill rollers
US3321839A (en) Linear measurement device
US3793733A (en) Zero adjusting device for digital micrometer
US2873535A (en) Drafting apparatus
US3557746A (en) Turns-counting rotary instrument dial indicator