WO2015154614A1 - Procédé anti-desserrage à double boulon - Google Patents

Procédé anti-desserrage à double boulon Download PDF

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Publication number
WO2015154614A1
WO2015154614A1 PCT/CN2015/074549 CN2015074549W WO2015154614A1 WO 2015154614 A1 WO2015154614 A1 WO 2015154614A1 CN 2015074549 W CN2015074549 W CN 2015074549W WO 2015154614 A1 WO2015154614 A1 WO 2015154614A1
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Prior art keywords
bolt
nut
fastening
tightening
tightening force
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PCT/CN2015/074549
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English (en)
Chinese (zh)
Inventor
刘兴邦
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刘兴邦
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Application filed by 刘兴邦 filed Critical 刘兴邦
Priority to CN201580000686.7A priority Critical patent/CN105452686B/zh
Publication of WO2015154614A1 publication Critical patent/WO2015154614A1/fr

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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16BDEVICES FOR FASTENING OR SECURING CONSTRUCTIONAL ELEMENTS OR MACHINE PARTS TOGETHER, e.g. NAILS, BOLTS, CIRCLIPS, CLAMPS, CLIPS OR WEDGES; JOINTS OR JOINTING
    • F16B39/00Locking of screws, bolts or nuts
    • F16B39/02Locking of screws, bolts or nuts in which the locking takes place after screwing down
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16BDEVICES FOR FASTENING OR SECURING CONSTRUCTIONAL ELEMENTS OR MACHINE PARTS TOGETHER, e.g. NAILS, BOLTS, CIRCLIPS, CLAMPS, CLIPS OR WEDGES; JOINTS OR JOINTING
    • F16B39/00Locking of screws, bolts or nuts
    • F16B39/02Locking of screws, bolts or nuts in which the locking takes place after screwing down
    • F16B39/12Locking of screws, bolts or nuts in which the locking takes place after screwing down by means of locknuts
    • F16B39/16Locking of screws, bolts or nuts in which the locking takes place after screwing down by means of locknuts in which the screw-thread of the locknut differs from that of the nut

Definitions

  • the patent relates to a double bolt anti-loose method, the screw hole or the hole is machined on the coupling member, the external thread diameters of the locking bolt and the fastening bolt are different and the rotation direction is opposite, the center hole of the bolt body is fastened, and the bolt is locked Through the center hole of the fastening bolt body, the locking bolt and the fastening bolt and the screw hole or nut, and the "reverse rotation nut" are connected to achieve the bolt loosening effect.
  • Radial force is the main reason for loose bolting. Some scholars (especially the former West German G. Junker) have done a lot of tests on the bolting joints to apply the radial exciting force and the axial exciting force. The result is that the bolting by the axial force may be loose or not. Loose, but bolted by radial forces will definitely loosen when the radial excitation force reaches a certain level. After the bolting is pre-tightened, the nut will be in a radially expanded state under the radial expansion force of the nut generated by the pre-tightening force. When the external radial force is transmitted to a certain extent, the radial expansion force of the nut will be broken.
  • the influence of the gap between the internal thread and the external thread is usually a clearance fit.
  • the thread angle (1°40′ ⁇ 3°30′) is smaller than the equivalent friction angle of the screw pair (6.5° ⁇ 10.5°), so the joint thread can satisfy the self-locking condition, at a certain Under the pre-tightening force, it is generally not loose.
  • the thread pair is usually a clearance fit.
  • the thread diameter of the bolt is 28.701mm
  • the thread diameter of the nut is 28.701mm
  • the average gap value of the thread connection is 0.1315mm
  • the maximum gap value is 0.244mm.
  • Gap fit facilitates thread manufacturing and installation, but affects the anti-loose effect.
  • the microscopic debris and particles on the surface of the thread are interspersed between the inner and outer nips, similar to the action of solid lubricants.
  • the threaded coupling pair Under the action of vibration, shock and alternating load, the threaded coupling pair inevitably has axial and radial turbulence.
  • the frictional resistance between the inner and outer threads will instantaneously decrease or even disappear. This phenomenon is repeated many times, interacting, and eventually leads to loose coupling.
  • Anti-loose of the top nut double nut anti-loose structure: After the two nuts are tightened to the top, an additional opposing force is generated between them, and the top force and the pre-tightening force together generate a larger radial expansion of the nut. The force is far from the external radial force, so the nut is not easy to rotate, but it must be noted that this additional top force must be generated between the two nuts to achieve the anti-loose effect.
  • P1 is the pulling force of the screw to the lock nut (the nut on the non-bearing surface is called the lock nut)
  • P2 is the pulling force of the screw to the fastening nut (the nut on the working support surface is called the tightening nut)
  • P is the screw Given the pre-tightening force, the tightening nut should be thicker and the lock nut should be thinner.
  • the bolt is composed of two kinds of spirals, left-handed and right-handed, in the same section On the segment, there are both left-handed and right-handed threads.
  • the tightening nut and the lock nut are two differently turned nuts. When using, tighten the tightening nut first, and then tighten the lock nut. In the case of vibration and impact, the tightening nut has a tendency to loosen, but since the loosening direction of the tightening nut is the tightening direction of the lock nut, the tightening of the lock nut prevents the tightening nut from loosening, resulting in tightness. The solid nut cannot be loosened.
  • the elastic modulus of the carbon steel material from which the bolt is made is generally 200 to 210 ⁇ 10 3 Mpa.
  • High-strength bolts refer to bolts with higher strength to reduce or simplify the size and structure of machinery or components.
  • the tensile strength is generally above 700Mpa, and the quality is stable.
  • high-strength bolts with a diameter of 30mm or more are not hard to be hardened during quenching. The quality is unstable and the working stress should be reduced during use. When using high-strength bolts, they have the following characteristics:
  • the coupling member is subjected to alternating load to generate vibration.
  • the contact surface should be made of high-strength and small-sized bolts, such as 10.9 and 8.8 (10.9 means tensile strength 1000 MPa, The yield strength ⁇ s is 90% of the tensile strength).
  • the reason for the excessive alternating stress is that the pre-tightening force is too small and the residual pre-tightening force is large, so the axial pre-tightening force always loads the bolt to the elastic limit of 90%. Or the pre-tightening force of the bolt is less than 80% of the material's yield limit of the bolt, and try to take a higher value.
  • the yield limit is the yield strength ⁇ s, which has the same meaning.
  • the bolt is made of a material with large deformation, and the material to be connected is made of a relatively rigid material, so that the deformation line of the bolt is relatively flat, and the deformation line of the joint is steep, and the magnitude of the stress is Become smaller.
  • the strength of the bolt is constant, the magnitude of the force in the bolt can be reduced, which helps to improve the life of the bolt.
  • the high-strength bolt connection must adopt a large pre-tightening force, and the general pre-tightening force is 70%-81.2% of the yield strength ⁇ s of the bolt material.
  • the control methods for bolt preload are:
  • the angle of rotation when the nut (or bolt) is tightened is approximately proportional to the sum of the bolt elongation and the looseness of the tightened member, and thus a method of achieving a predetermined preload force at a predetermined rotation angle can be employed.
  • the easiest way to measure the nut angle is to engrave a zero line and measure the nut angle by the rotation of the nut.
  • the measurement accuracy of the nut angle can be controlled within 10 ° ⁇ 15 °. In general, the preload force error is approximately ⁇ 15%.
  • the pre-tightening force can be controlled by the elongation of the bolt to obtain high control precision, and is widely used as a pre-tightening force control method for bolt flange connection in important occasions. If the measurement is correct, the preload force error is about ⁇ 5%.
  • Control the pre-tightening force according to the tightening torque and the nut angle First apply a certain torque to the fastener, then turn the nut through a certain angle to check whether the final torque and the rotation angle are satisfied, so as to avoid insufficient pre-tightening or pre-tightening.
  • the advantage of this control method is that the information given by the tightening torque and the nut angle can precisely control the bolt pre-tightening process and the pre-tightening force, and can find the tightening or over-tightening that may occur during the installation process. This is used alone. Torque control or corner control cannot be achieved.
  • the method of measuring stress by using a resistance strain gauge mainly includes two measuring methods: a force measuring bolt and a ring gasket.
  • the force-measuring bolt is a sensor that directly replaces the existing bolt and can measure the bolt pre-tightening force, which can be accurate to kilograms.
  • the annular gasket is measured by indirectly measuring the pressure at the nut by an annular washer sensor (load cell) added to the head of the bolt to obtain the preload of the bolt.
  • the strain gauge can be placed on the unthreaded part of the bolt, and the tensile strain can be measured and controlled by the resistance strain gauge.
  • the preload force error can be controlled within ⁇ 1%.
  • Ordinary bolts refer to bolts with low tensile strength, such as 3.6 and 5.6.
  • the preload is affected by the actual conditions. For example, find the higher value of the preload as a reference:
  • the pre-tightening force of the 3.6-class M16 bolt is generally 20400N, and the stress ⁇ is:
  • the preload of the 3.6-class M30 bolt is generally 73500N, and the stress ⁇ is:
  • the pre-tightening force of the 5.6-class M16 bolt is generally 34000N, and the stress ⁇ is:
  • the preload of the 5.6-class M30 bolt is generally 122000N, and the stress ⁇ is:
  • the normal pre-tightening force or pre-tightening stress of ordinary bolts generally does not exceed 0.58 ⁇ s (for the calculation of this specification).
  • the stress response of the bolt changes with the preload force.
  • the pre-tightening stress of the shear bolt is about 40% of the yield limit of the material, the strength is maximum; the strength of the tension bolt will follow The pre-tightening force is weakened; at the same time, the bolts subjected to shearing and stretching have the highest strength when the pre-tightening stress is about 40% of the yield limit of the material.
  • China Patent No. CN1087848 "Method for Manufacturing High-strength Nuts" (promulgated on June 15, 1994), announced a method for manufacturing high-strength nuts.
  • the main technical solution is: the pre-order equipment of the cold heading machine is medium frequency induction. Heating furnace, the production process is: (1) heating; (2) ⁇ shape; (3) tapping screw; (4) heat treatment.
  • the metric thread is divided into coarse teeth (60°) and fine teeth (60°).
  • the pitch of the external thread of the coarse teeth M30 bolt is 3.50mm
  • the depth of the thread is 1.75mm
  • the diameter of the bottom of the thread ie the diameter of the bottom of the thread, referred to as the bottom diameter) ) is 26.50mm.
  • the coupling member is machined with two screw holes of different diameters and oppositely rotating threads on the axial center line of the same center, which are called fastening screw holes and locking screw holes, fastening the center hole of the bolt body, fastening bolts And the fastening screw hole is coupled, the locking bolt is coupled through the central hole of the fastening bolt body and the locking screw hole to jointly fasten the coupling member;
  • the hole is made in the coupling member.
  • the diameter of the internal thread of the lock nut and the fastening nut is different and the rotation direction is opposite.
  • the fastening bolt and the fastening nut are coupled, and the locking bolt passes through the center hole of the fastening bolt body and the lock nut. Coupling to jointly fasten the coupling member;
  • the gasket and the lock nut and the fastening nut are welded or integrated into a “reverse rotation nut”.
  • the “reverse rotation nut” is provided with two sets of internal threads with different diameters and opposite directions, fastening bolts and “ The reverse rotation nut is coupled, and the locking bolt is connected through the center hole of the fastening bolt body and the "reverse rotation nut” to jointly fasten the coupling member;
  • the technical point of the double bolt anti-loose method is that the fastening bolt and the locking bolt are two independent bolts, fastening bolts and locking
  • the diameter of the external thread of the bolt and the direction of rotation are different.
  • the diameter of the internal thread of the lock nut and the fastening nut and the direction of rotation are different.
  • the center hole of the fastening bolt body is used to assemble the locking bolt, and the "reverse rotation nut" appears.
  • the integration of the lock nut and the fastening nut is made possible. In the background art, there are three cases in which the lock nut and the fastening nut are integrated:
  • Locking bolts and fastening bolts can be selected according to the material, processing technology and appropriate pre-tightening force. Since the two sets of reverse-rotating threads have an "interlocking" effect, the nut or bolt cannot be rotated to achieve the anti-loose effect. It is also suitable for occasions where the coupling member is required to be pivoted around the fastening bolt.
  • the beneficial effect of the patent is that the reliability of the bolt connection can be improved, and the utility model can be used under the condition of lower pre-tightening force to extend the life of the bolt, and some parts can adopt standard parts, which can be applied to various occasions, especially the more important joints. .
  • Figure 1 is a cross-sectional view showing the structure of a bolt and a coupling.
  • the axial centerline of the same center of the left coupling member is machined with two screw holes of different diameters and opposite directions of rotation.
  • the large diameter screw hole is called a fastening screw hole
  • the small diameter screw hole is called a locking screw hole.
  • Holes drilled or reamed
  • the center of the rod body of the bolt through hole structure.
  • the shape of the head of the fastening bolt is different from the hexagon.
  • the shape of the head of the locking bolt is exemplified by a hexagon.
  • the fastening bolts are fastened to the fastening bolts, and the fastening bolts are fastened through the central hole of the fastening bolt body and the locking screw holes, and the locking bolt heads are pressed against the fastening bolt heads.
  • the effective tensile length of the locking bolt screw is B
  • the effective tensile length of the fastening bolt is the thickness of the right coupling. If the thickness of the left coupling member becomes small, it becomes a through-hole structure.
  • Figure 2 is a right side view of Figure 1 (with the coupling omitted).
  • Figure 3 is a cross-sectional view showing the first structure of the bolt, the nut and the coupling. Both couplings are drilled, using fastening bolts, locking bolts, fastening nuts, lock nuts and flat washers (one type of gasket) for coupling, fastening bolts and fastening nuts to press the coupling, locking The nut is pressed against the fastening nut by a flat washer.
  • This structure is similar to the "reverse rotation double nut" with a flat pad.
  • the shape of the fastening nut and the lock nut is an example of a hexagon. The rest is the same as in Figure 1.
  • Figure 4 is a left side view of Figure 3 (with the coupling omitted).
  • the circumscribed circle of the outer nut of the lock nut is equal to the inscribed circle of the outer hexagon of the fastening nut, and the outer diameter of the flat washer is equal to the inscribed circle of the outer hexagon of the fastening nut.
  • Figure 5 is a cross-sectional view showing the second structure of the bolt, the nut and the coupling.
  • the flat pad and the lock nut and the fastening nut are welded together (to prevent excessive deformation, spot welding along the circumference).
  • the rest is the same as in Figure 3.
  • Figure 6 is a cross-sectional view showing the third structure of the bolt, the nut and the coupling. After the lock nut and the flat pad are integrated, they are welded with the fastening nut. The tightening nut and the flat washer can also be integrated and welded with the lock nut. The rest is the same as in Figure 3.
  • Fig. 6 The left side view of Fig. 6 is the same as Fig. 4 (the solder joint is removed).
  • Figure 7 is a cross-sectional view of the "National Cap Nut" of the Chinese National Standard (GB/T 923-2009).
  • G1 is the length of the undercut, and the M24 ⁇ 2 hex cap nut G1max is 10.7 mm in the first series and 7.3 mm in the second series.
  • the inner circle of the outer hexagon can also be changed to other outer polygon angles, so it can be divided into a round cap nut and an outer polygon cover nut (including a hexagonal cap nut). In this specification, they are collectively referred to as "cap nuts.”
  • Figure 8 is a left side view of Figure 7.
  • Figure 9 is a cross-sectional view showing the structure of the lock nut, the flat washer and the fastening nut, which is referred to as a "reverse rotation nut”.
  • the thread at the lock nut in the "reverse nut” is called the locking thread (left small diameter thread) and the thread at the fastening nut is called the fastening thread (large diameter thread on the right).
  • Figure 10 is a cross-sectional view showing the fourth structure of the bolt, the nut and the coupling.
  • the "reverse rotation nut” is coupled with the coupling member and the bolt, and the left side of the “reverse rotation nut” is a through hole structure. The rest is the same as in Figure 3.
  • Figure 11 is a left side view of Figure 10 (the coupling is omitted).
  • the shape of the lock nut becomes circular (for example, the circumcircle or inscribed circle of the outer nut of the lock nut, but the diameter should be at least not less than the inscribed circle of the outer hexagon), and the diameter is equal to the outer diameter of the lock nut.
  • the outer circle of the outer ring and the shape of the outer hexagon at the fastening nut are called a single outer hexagon "reverse rotation nut”.
  • the shape of the fastening nut becomes circular, the shape of the outer hexagon at the lock nut does not change, which is also called the single-hexagon "reverse rotation nut", so the single-hexagon "reverse rotation nut” is divided into large Hexagon "reverse rotation nut” and small hexagon “reverse rotation nut”.
  • the shape of the outer hexagon at the nut is unchanged.
  • Figure 12 is a cross-sectional view showing the fifth structure of the bolt, the nut and the coupling.
  • the left side of the "reverse rotation nut” is a hemispherical sealing structure called a "reverse rotation nut”. Any such that the nut does not expose the screw hole is collectively referred to as a sealing structure.
  • Figure 13 is a cross-sectional view showing the sixth structure of the bolt, the nut and the coupling.
  • the lock nut presses the tightening nut through a "bowl-type” gasket (another type of gasket) that is similar in construction to a "reverse-rotating double nut” with a “bowl-type” gasket.
  • the locking bolt head, the lock nut and the fastening nut are hexagonal. The rest is the same as in Figure 3.
  • Gaskets and flat pads have the same purpose and are collectively referred to as gaskets.
  • Figure 14 is a cross-sectional view showing the seventh structure of the bolt, the nut and the coupling.
  • Figure 15 is a left side view of Figure 14 (without the coupling).
  • the shape of the "reverse rotation nut” lock nut becomes circular and becomes a large hexagonal "reverse rotation nut”. If the shape of the fastening nut becomes circular, the shape of the outer hexagon at the lock nut does not change, and it becomes a small hexagonal "reverse rotation nut”.
  • Figure 16 is a cross-sectional view showing the eighth structure of the bolt, the nut and the coupling.
  • the locking bolts and the fastening bolts are stud bolts, and a rigid sleeve is used between the two couplings for limiting. The rest is the same as in FIG.
  • the fastening bolts (3) pass through the drilling and left coupling of the right coupling (2).
  • the fastening screw holes of the piece (1) are connected, and the fastening bolts (3) are tightened to achieve the required pre-tightening force.
  • the locking bolt (4) penetrates into the central hole of the fastening bolt (3), and is coupled with the locking screw hole of the left coupling member (1), and tightens the locking bolt (4) to achieve the required pre-tightening force, and the locking bolt ( 4)
  • the head of the head is pressed against the head of the fastening bolt (3).
  • the length of the rod of the fastening bolt (3) and the locking bolt (4) must be strictly controlled to prevent screwing into the bottom of the screw hole. Since the locking screw hole and the fastening screw hole adopt the reverse rotation thread, the left coupling member (1) cannot be rotated due to the "interlocking" effect, and becomes a double-group thread force compared with the single bolt, and can also be improved. The joint strength of the thread. Description of the principle of anti-loose: The left coupling (1) cannot be rotated due to the "interlocking" action of the reverse rotation thread.
  • the fastening bolt (3) tends to loosen, but due to the fastening bolt
  • the retracting direction of (3) is the tightening direction of the locking bolt (4), and the tightening of the locking bolt (4) prevents the fastening bolt (3) from loosening, and the fastening bolt (3) cannot be loosened.
  • the thread of the component meets the requirements, it can be repeatedly disassembled without affecting the coupling performance. If the thickness of the left coupling member (1) becomes small and the round hole or the internal thread is exposed, it becomes a through-hole structure and does not affect the coupling performance.
  • the right coupling member (2) is required to be pivoted around the fastening bolt (3), a gap must be provided between the two coupling members or between the right coupling member (2) and the head of the fastening bolt (3).
  • the fixing bolt (3) needs to grasp the depth of screwing into the fastening screw hole, leaving a proper clearance, and then screwing in the locking bolt (4) and pre-tightening, the anti-loose effect is better than using a single bolt.
  • the fastening bolt (3) is coupled through the drilled hole and the fastening nut (7) and pre-tensioned to the coupling.
  • tighten the locking bolt (4) into the center hole of the fastening bolt (3) attach the flat washer (6), and connect with the lock nut (5).
  • the lock nut (5) is tightly fastened.
  • the nut (7), the lock nut (5) and the tightening nut (7) can be considered to achieve "interlocking", and the anti-loose principle is the same as the "reverse rotation double nut" in the background art.
  • the length of the rod body should be strictly controlled to prevent the left end of the rod body from pressing against the lock nut (5), so that the lock nut (5) cannot press the tightening nut (7).
  • the outer dimensions of the lock nut (5) should match the tightening nut (7) and the flat washer (6).
  • the outer diameter of the lock nut (5) can be slightly smaller than the tightening nut (7), preferably the lock nut.
  • the circumcircle of the outer hexagon is equal to the inscribed circle of the outer hexagon of the fastening nut (7).
  • the inner diameter of the flat washer (6) should be slightly larger than the diameter of the fastening bolt (3).
  • the outer diameter can be equal to the inner cut circle of the outer hexagon of the fastening nut (7).
  • the thickness should be larger than the exposed length of the fastening bolt (3) and leave appropriate.
  • the gap, the exposed length is the sum of the length of the fastening bolt (3) and the thickness of the two couplings and the fastening nut (7).
  • the lock nut (5) can be replaced with a nut with a sealing structure, such as a cap nut. The rest are the same as the embodiment of Fig. 1.
  • the structure of the right end of the fastening bolt and the lock bolt is the same as that of the left end nut, and the bolt is used to fasten the joint.
  • the lock nut (5), the flat washer (6) and the fastening nut (7) are welded together (can be welded along the periphery), and the nut cannot be rotated, which is advantageous for preventing looseness and not affecting. Disassembly. The rest are the same as the embodiment of Fig. 3.
  • the fastening nut (7) is welded, or the fastening nut (7) and the flat washer (6) are integrally formed, and the lock is completed.
  • Tight nut (5) is welded.
  • the flat pad (6) is made in one piece, welded to the fastening nut (7), or the fastening nut (7) and the flat pad (6) are integrated. After that, welding with the cap nut is beneficial to prevent the nut from loosening and does not affect the disassembly. The rest are the same as the embodiment of Fig. 5.
  • the reverse rotation nut (9) is a double outer hexagon structure, and the fastening bolt (3) and the locking bolt (4) are screwed into the reverse rotation nut (9) to fasten the coupling member. As long as it is not manually disassembled, the reverse rotation nut (9) cannot be loosened. The rest are the same as the embodiment of Fig. 3.
  • the coupling is required to be able to rotate about the fastening bolt (3), between the two couplings or between the right coupling (2) and the head of the fastening bolt (3), the left coupling (1) and the opposite A clearance shall be provided between the turning nut (9).
  • the tightening bolt (3) shall have a depth to be screwed into the counter-rotating nut (9), leaving a proper clearance, and the locking bolt (4) is screwed into the counter-rotating nut ( 9) and pre-tightening, the anti-loose effect is better than using a single bolt and a counter-nut.
  • the counter-rotating nut (9) of the hemispherical sealing structure can prevent rain, snow, dust and the like from entering the internal thread, thereby protecting the thread and increasing the service life under more severe natural conditions.
  • the rest are the same as the embodiment of Fig. 10.
  • the lock nut (5) is pressed against the fastening nut (7) by the "bowl type” gasket (10), and the main function of the "bowl type” gasket (10) is to ensure a small outer shape.
  • the lock nut (5) can press the fastening nut (7) with a relatively large outer dimension, and the "bowl type” gasket (10) should have sufficient rigidity, otherwise the joint performance will be affected.
  • a proper clearance should be left between the “bowl” gasket (10) and the left end of the fastening bolt (3) rod to prevent the left end of the fastening bolt (3) against the “bowl” gasket (10).
  • the head and tail of the locking bolt (4) can be used interchangeably, and the head of the fastening bolt (3) can be pressed using the lock nut (5).
  • the rest are the same as the embodiment of Fig. 3.
  • the lock nut (5), the "bowl type” gasket (10) and the fastening nut (7) can be welded for use in one piece, as in the embodiment of Figure 5; the lock nut (5) and the "bowl type” gasket ( 10) In one piece, welded with the fastening nut (7), or the fastening nut (7) and the "bowl type” gasket (10) are integrated, and the lock nut (5) is welded, and the embodiment of Fig. 6 the same.
  • the lock nut (5), the "bowl type” spacer (10) and the fastening nut (7) are integrally formed as a counter-rotating nut (9), and the rest are the same as in the embodiment of Fig. 13.
  • the rigid couplings (11) are used for limiting between the two coupling members, and the fastening bolts (3) and the locking bolts (4) use stud bolts, the bolt length is increased, and more elastic deformation is stored. Yes, the anti-loose effect will be better.
  • the rest are the same as the embodiment of Fig. 13.
  • the fastening bolt (3) is subjected to compressive stress after the coupling
  • the locking bolt (4) is subjected to tensile stress
  • the locking bolt (4) should be pre-tightened. Do not withstand excessive stress.
  • the reverse rotation nut (9) After the reverse rotation nut (9) is made into a double hex or a small hexagonal shape, it can be locked by using a shallow hexagon socket. Remove the lock bolt (4) and the fastening bolt (3) against the nut (9). In fact, the flat washer (6) or the "bowl type” washer (10) and the lock nut (5) and the fastening nut (7) have become the double-hexagon reverse-rotating nut (9) of the welded structure.
  • the welding nut (7) is welded, or the nut (7) and the flat washer are fastened ( 6)
  • the "bowl type” gasket (10) is made in one piece, welded with the lock nut (5), and also becomes the double-hexagon reverse-rotating nut (9) of the welded structure. If the lock nut (5) and the flat washer (6) or the "bowl type” washer (10) are made in a circular shape and welded with the fastening nut (7), it becomes a large hexagonal reverse nut of the welded structure.
  • the fastening nut (7) and the flat washer (6) or the "bowl type” washer (10) are all made circular and integrated with the lock nut (5) to become a small hexagonal reverse of the welded structure. Screw the nut (9). If the shape of the fastening nut (7) and the lock nut (5) are round, and the flat pad (6) or the "bowl type” gasket (10) is welded, it becomes a circular reverse nut of the welded structure. (9); If the cap nut is used instead of the lock nut (5), it becomes the plugged reverse nut (9) of the welded structure. Therefore, the reverse rotation nut (9) can be divided into the following types:
  • Each of the counter-rotating nuts (9) can be divided into different shapes and structures:
  • Welded anti-rotation nut (9) can be divided into through-hole type, sealed type, large hexagon, small hexagon and round shape, in addition to lock nut (5), flat pad (6) or "bowl type” pad
  • the "3 in 1" structure of the piece (10) and the fastening nut (7) is welded; the lock nut (5) and the pad (6) or the "bowl type” spacer (10) are integrally formed, and the fastening nut is (7)
  • the "2 in 1" structure of the welding, the "2 in 1” structure also includes a fastening nut (7) and a flat pad (6) or a "bowl type” gasket (10), and a lock nut ( 5) The form of welding.
  • the integral reverse rotation nut (9) can be divided into a through hole type, a sealing type, a large hexagon, a small hexagon and a circular shape.
  • the single hex reverse rotation nut (9) can be divided into a through hole type, a sealing type, a welded type, an integral type, a large hex and a small hex.
  • the double hex reverse rotation nut (9) can be divided into a through hole type, a sealing type, a welded type and a unitary type.
  • the circular counter-rotating nut (9) can be divided into a through-hole type, a sealing type, a welded type and a monolithic type.
  • Through-hole reverse-rotating nut (9) can be divided into welded, integral, large hexagon, small hexagon and round.
  • the sealed reverse rotation nut (9) can be divided into welded type, integral type, large hexagon, small hexagon and round shape.
  • the single hex reverse rotation nut (9) can also be other outer polyhedral angles, collectively referred to as “single outer polyhedral angle” reverse rotation nut (9).
  • the double hex reverse rotation nut (9) can also be other outer polyhedral angles, collectively referred to as "double outer polygon angle” reverse rotation nut (9).
  • the tightening bolt (4) and the fastening bolt (3) can no longer require too much pre-tightening force; in addition, according to the background art, "the anti-loose effect is increased by 13.2 times when the axial pre-tightening force of the bolt is increased from 0.25 ⁇ s to 0.45 ⁇ s.
  • the pre-tightening force of the fastening bolt (3) or the locking bolt (4) will be lower than 0.4 ⁇ s, since the total pre-tightening force of the fastening bolt (3) and the locking bolt (4) is equal to the pre-tightening force of the two. And, the total pre-tightening force is equivalent to the pre-tightening force acting on the solid bolt. If the pre-tightening force of the solid bolt is not less than 0.4 ⁇ s, the pre-tightening and anti-loose requirements can also be met.
  • the coupling member is fastened together with the reverse rotation nut (9).
  • the diameter (outer diameter), material, and processing of the fastening bolt (3) The process, modulus of elasticity, thread and effective stretch length are the same as for solid bolts.
  • the material, processing technique, elastic modulus, stress, etc. of the locking bolt (4) are the same as the solid bolt, only the effective tensile length L1 of the locking bolt (4) is increased to 120 mm compared with the solid bolt, so its elastic elongation
  • the diameter d of the locking bolt (4) is:
  • the cross-sectional area S of the solid bolt is:
  • the tightening bolt (3) and the locking bolt (4) under the preload force, the elastic elongation is generally not the same, but in the bear
  • the elastic elongation is the same at the working load.
  • the fastening bolt (3) and the locking bolt (4) jointly approach or reach the yield strength under the action of the preload force and the maximum working load to reach the maximum load carrying capacity (stretch resistance) against the load, ie "The tightening bolts (3) and the locking bolts (4) are required to have the same amount of elastic elongation when they are loaded from the preload force to the yield strength", which is simply referred to as "the same requirement for the elastic elongation.”
  • the high-strength bolt connection must adopt a large pre-tightening force, and the general pre-tightening force should be 70% to 81.2% of the yield strength of the bolt material
  • the high-strength bolt pre-tightening force can take 0.8 ⁇ s.
  • the error of the pre-tightening force of the reference nut (bolt) rotation angle is about ⁇ 15%.
  • the elastic elongation When the locking bolt (4) is loaded from zero to the yield strength, the elastic elongation is ⁇ L1q, and when it is loaded from zero to the pre-tightening force F1, the elastic elongation is ⁇ L1, and the elastic elongation is from the preload force F1 to the yield strength.
  • the preload force F1 of the locking bolt (4) is:
  • the elastic elongation ⁇ L2 when the fastening bolt (3) is loaded from zero to the preload force F2 is:
  • the stress ⁇ 2 (ie, the pre-tightening stress) of the fastening bolt (3) when the pre-tightening force is F2 is:
  • the pre-tightening force F1 of the locking bolt (4) is 0.68 ⁇ s
  • the pre-tightening force F2 of the fastening bolt (3) is 0.41 ⁇ s, which is equivalent to the pre-tightening force of the 8.8-class M30 ⁇ 2 solid bolt being 0.47 ⁇ s, which is higher than 0.4 ⁇ s, can meet the requirements of pre-tightening and anti-loosening.
  • the maximum load carrying capacity of the locking bolt (4) and the fastening bolt (3) is:
  • the pre-tightening force of the locking bolt (4) is 0.68 ⁇ s
  • the pre-tightening force of the fastening bolt (3) is 0.41 ⁇ s
  • only the theoretical calculation proves that the locking bolt (4) and the fastening bolt (3) are Under the action of the working load, the elastic elongation when the proof reaches the yield strength is 0.117 mm.
  • the yield strength is generally not reached, and the bolts are not overloaded.
  • the locking bolt (4) is pre-
  • the preload force F1 of the locking bolt (4) is:
  • the preload force F2 of the fastening bolt (3) is:
  • the pre-tightening force of the locking bolt (4) is 0.78 ⁇ s and the pre-tightening force of the fastening bolt (3) is 0.47 ⁇ s
  • the pre-tightening force of the 8.8-class M30 ⁇ 2 solid bolt is 0.54 ⁇ s, which is higher than 0.4 ⁇ s. Meet the anti-loose requirements.
  • the locking bolt (4) reaches the maximum load carrying capacity together with the fastening bolt (3) when it reaches the yield strength, and its value is:
  • the locking bolt (4) is pre-determined according to the relevant calculation result of 1.1.
  • the preload force F1 of the locking bolt (4) is:
  • the preload force F2 of the fastening bolt (3) is:
  • the pre-tightening force of the locking bolt (4) is 0.58 ⁇ s and the pre-tightening force of the fastening bolt (3) is 0.35 ⁇ s
  • the pre-tightening force of the 8.8-class M30 ⁇ 2 solid bolt is 0.4 ⁇ s, which can be used for some requirements to be appropriately reduced. In the case of pre-tightening, the requirements for anti-loosening can be met.
  • the fastening bolt (3) reaches the maximum load carrying capacity together with the locking bolt (4) when it reaches the yield strength, and its value is:
  • the "residual preload force" calculation method is used to calculate the maximum load capacity of the bolts described above in the example of the joint using the 8.8 grade M30 ⁇ 2 threaded joint in Fig. 10 (related to the first calculation method).
  • the pre-tightening force F2 and the stress ⁇ 2 of the fastening bolt (3) are:
  • the fastening bolt (3) reaches the maximum load carrying capacity together with the locking bolt (4) when it reaches the yield strength, and its value is:
  • the calculation method provides reference when needed, so when the physical bolt pre-tightening force is determined, 1.4 can be used.
  • the calculation method calculates the preload of the fastening bolt (3) and the locking bolt (4).
  • the difference between the 1.2 and 1.3 calculation methods is that the locking bolts (4) and the fastening bolts (3) have different order of yield strength.
  • the high-strength bolt connection must adopt a large pre-tightening force, and the general pre-tightening force should be 70%-81.2% of the yield strength of the bolt material
  • the yield strength ⁇ s of the 8.8 grade bolt is 640 MPa
  • the stress ⁇ 1 of the lock bolt (4) is:
  • the diameter d of the locking bolt (4) is:
  • the ratio of the diameter d of the locking bolt (4) to the diameter D of the solid bolt is:
  • a 8.8-stage M12 bolt can be selected as the locking bolt (4).
  • the diameter of the locking bolt (4) is selected by calculating the cross-sectional area of the fastening bolt (3) and the locking bolt (4).
  • the cross-sectional area S of the solid bolt is:
  • the cross-sectional area S2 of the fastening bolt (3) is:
  • the ratio of the diameter d of the locking bolt (4) to the diameter D of the solid bolt is:
  • the maximum diameter of the locking bolt (4) is 0.707D
  • the diameter of the locking bolt (4) can be slightly less than 0.707D.
  • the locking bolt (4) The cross-sectional area cannot be larger than the cross-sectional area of the fastening bolt (3), otherwise the strength of the fastening bolt (3) will be affected.
  • the fastening bolt (3) and the locking bolt (4) use different materials or processing techniques, the tightening bolt (3) has a relatively high yield strength, and the locking bolt (4) has a larger cross-sectional area than the fastening bolt (3).
  • the cross-sectional area the bearing capacity of the fastening bolt (3) is still relatively large, the diameter of the locking bolt (4) can be further increased.
  • the fourth calculation method "the high-strength bolt connection must adopt a large pre-tightening force, and the general pre-tightening force should be 70% to 81.2% of the yield strength of the bolt material" to fasten the bolt (3).
  • the maximum pre-tightening force Fmax is equal to the physical bolt pre-tightening force P to select the diameter of the locking bolt (4), and the fastening bolt (3) pre-tightening force F2 is required to be no more than 0.8 ⁇ s.
  • the physical bolt pre-tightening force P is equal to the sum of the pre-tightening forces of the fastening bolt (3) and the locking bolt (4), that is, the total pre-tightening force F, but the fastening bolts are tightened after tightening the locking bolts (4) (3)
  • the pre-tightening force F2 will be reduced, and the reduced amplitude is equal to the pre-tightening force F1 of the locking bolt (4).
  • the fastening bolt (3) is required to tighten the locking bolt (4), it can also achieve the required Pre-tightening force, so the maximum pre-tightening force Fmax should be equal to the physical bolt pre-tightening force P when assembling the fastening bolts (3). The same applies to the first, second and third calculation methods.
  • the cross-sectional area S of the solid bolt is:
  • the cross-sectional area S1 of the locking bolt (4) is:
  • the cross-sectional area S2 of the fastening bolt (3) is:
  • the pulling force when the solid bolt reaches the ⁇ times yield strength, that is, the pre-tightening force P is:
  • the selection of the 8.8 grade M14 bolt as the locking bolt (4) meets the requirements.
  • the fastening bolt (3) has a larger cross-sectional area, and ⁇ 2/ ⁇ s is also less than 0.8, so it also meets the requirements.
  • the pre-tightening force P is:
  • the cross-sectional area S of the 8.8-class solid bolt is:
  • the cross-sectional area S2 of the fastening bolt (3) is:
  • the cross-sectional area S1 of the 8.8-stage locking bolt (4) is:
  • the diameter d of the locking bolt (4) is:
  • the diameter d of the 8.8-stage locking bolt (4) can be taken as 16 mm.
  • the solid bolt, the fastening bolt (3) and the locking bolt (4) are high-strength bolts, the following characteristics are obtained when the yield strength is the same:
  • the physical bolt pre-tightening force requires 0.4 ⁇ s ⁇ P ⁇ 0.8 ⁇ s;
  • the tightening bolt (4) pre-tightening force requires 0.4 ⁇ s ⁇ F1 ⁇ 0.8 ⁇ s;
  • the maximum pre-tightening force or maximum pre-tightening stress of the solid bolt in the ordinary threaded joint is 0.78 ⁇ s. If the influence of the pre-tightening operation error is ⁇ 15%, it becomes the locking bolt (4) and the tightening bolt (3).
  • the sixth calculation method Select the diameter of the locking bolt (4) according to the maximum pre-tightening force and the maximum pre-tightening stress of the fastening bolt (3), and consider the influence of the pre-tightening operation error ⁇ 15% to calculate the maximum bearing capacity of the bolt and Fastening bolt (3) pre-tightening force.
  • the solid bolt diameter D 30 mm
  • the effective tensile length of the screw L 65 mm
  • the requirement ⁇ / ⁇ s 0.58.
  • the fastening bolt (3) has the same diameter (outer diameter), thread, effective tensile length, material and machining process as the solid bolt.
  • the material of the locking bolt (4) and the machining process are the same as the physical bolt.
  • the length of the anti-rotation nut (9) fastening thread is 25.6mm
  • the inner distance between the locking thread and the fastening thread is 10.7mm
  • the height of the head of the fastening bolt (3) is 18.7mm, so the locking
  • the bolt (4) has an effective tensile length L1 of 120 mm (refer to the first calculation method).
  • the pre-tightening force P of the 5.6-class M30 ⁇ 2 solid bolt is:
  • the cross-sectional area S of the 5.6-class M30 ⁇ 2 solid bolt is:
  • the cross-sectional area S1 of the locking bolt (4) is:
  • the diameter d of the locking bolt (4) is:
  • the diameter d of the locking bolt (4) may be a value not greater than 15.2 mm, and if it is larger than 15.2 mm, the sectional area S2 of the fastening bolt (3) may be insufficient.
  • a 5.6-stage M14 bolt can be selected as the locking bolt (4).
  • the preload force F1 of the locking bolt (4) is:
  • the pre-tightening force F2 and the stress ⁇ 2 of the fastening bolt (3) are:
  • the elastic modulus E is 200 ⁇ 10 3 Mpa.
  • the upper limit Fmax1 and the lower limit Fmax2 of the maximum pre-tightening force of the fastening bolt (3) are:
  • the upper limit F11 and the lower limit F12 of the pre-tightening force of the locking bolt (4) are:
  • the maximum pre-tightening force Fmax and the stress ⁇ 2 of the fastening bolt (3) are:
  • the pre-tightening force of the fastening bolt (3) is 0.7 ⁇ s ⁇ F2 ⁇ 0.42 ⁇ s.
  • the pre-tightening force of the fastening bolt (3) is always between 0.42 ⁇ s and 0.7 ⁇ s. In the meantime, it can meet the requirements of pre-tightening and anti-loose.
  • the maximum bearing capacity of the bolt shall be calculated according to the following four conditions (refer to 1.2 or 1.3 in the first calculation method) , using the minimum value to check the safety factor:
  • the pre-tightening force of the locking bolt (4) is the upper limit of 0.76 ⁇ s, and the pre-tightening force of the fastening bolt (3) is the upper limit of 0.7 ⁇ s;
  • the pre-tightening force of the locking bolt (4) is the lower limit of 0.56 ⁇ s, and the pre-tightening force of the fastening bolt (3) is the lower limit of 0.42 ⁇ s;
  • the pre-tightening force of the locking bolt (4) is the upper limit of 0.76 ⁇ s, and the pre-tightening force of the fastening bolt (3) is the lower limit of 0.42 ⁇ s:
  • the pre-tightening force of the locking bolt (4) is the lower limit of 0.56 ⁇ s, and the pre-tightening force of the fastening bolt (3) is the upper limit of 0.7 ⁇ s.
  • the tightening bolt (3) stress ⁇ 2 is 0.85 ⁇ s, which belongs to “temporary over-standard”. Because the pre-tightening force of the locking bolt (4) is lower than 0.56 ⁇ s, ⁇ 2 is only 0.7 ⁇ s, which meets the requirements.
  • the maximum pre-tightening force Fmax1 of the fastening bolt (3) is 141.3KN, which is less than Pmax (165.3KN), indicating that the external thread of the fastening bolt (3) should be no problem.
  • the pre-tightening force should meet the following requirements when the yield strength is the same:
  • the physical bolt pre-tightening force generally requires 0.4 ⁇ s ⁇ P ⁇ 0.58 ⁇ s;
  • the tightening bolt (4) pre-tightening force requires 0.4 ⁇ s ⁇ F1 ⁇ 0.78 ⁇ s;
  • the upper limit Fmax1 and the lower limit Fmax2 of the maximum pre-tightening force of the fastening bolt (3) are:
  • the upper limit F11 and the lower limit F12 of the pre-tightening force of the locking bolt (4) are:
  • the maximum pre-tightening force Fmax and the stress ⁇ 2 of the fastening bolt (3) are:
  • the pre-tightening force of the fastening bolt (3) is 0.71 ⁇ s ⁇ F2 ⁇ 0.43 ⁇ s.
  • the pre-tightening force of the fastening bolt (3) is always between 0.43 ⁇ s and 0.71 ⁇ s. In the meantime, it can meet the requirements of pre-tightening and anti-loose.
  • the maximum bearing capacity of the bolt shall be calculated according to the following four conditions (refer to 1.2 or 1.3 in the first calculation method) , using the minimum value to check the safety factor:
  • the pre-tightening force of the locking bolt (4) is the upper limit of 0.78 ⁇ s, and the pre-tightening force of the fastening bolt (3) is the upper limit of 0.71 ⁇ s;
  • the pre-tightening force of the locking bolt (4) is the lower limit of 0.58 ⁇ s, and the pre-tightening force of the fastening bolt (3) is the lower limit of 0.43 ⁇ s;
  • the pre-tightening force of the locking bolt (4) is the upper limit of 0.78 ⁇ s, and the pre-tightening force of the fastening bolt (3) is the lower limit of 0.43 ⁇ s;
  • the pre-tightening force of the locking bolt (4) is the lower limit of 0.58 ⁇ s, and the pre-tightening force of the fastening bolt (3) is the upper limit of 0.71 ⁇ s.
  • the stress ⁇ 2 of the fastening bolt (3) is 0.87 ⁇ s, which belongs to “temporary over-standard”. Because the pre-tightening force of the locking bolt (4) is 0.58 ⁇ s at the lower limit, ⁇ 2 is only 0.71 ⁇ s, which meets the requirements.
  • the preload of the locking bolt (4) and the fastening bolt (3) can be taken as 0.4 ⁇ s.
  • the diameter d of the locking bolt (4) is selected by the first, second, third, fourth, fifth or sixth calculation method
  • the maximum pre-tightening force Fmax of the fastening bolt (3) is equal to the physical bolt pre-tightening force P to check the stress ⁇ 2 of the fastening bolt (3), and the requirement ⁇ 2 is not more than 0.8 ⁇ s (high-strength bolt) or 0.78 ⁇ s (ordinary bolt) );
  • the phenomenon does not meet the requirements in the calculation process, it can be treated by reducing the diameter of the locking bolt (4) or using the high yield strength fastening bolt (3).
  • the effective tensile length of the locking bolt (4) is the height of the head of the fastening bolt (3) and the sum of the thickness of the fastening nut (7), the flat washer (6) and the two coupling members, and the fastening bolt (3)
  • the effective tensile length is the sum of the thicknesses of the two coupling members.
  • the effective tensile length of the bolts of the embodiment of Figures 5 and 6 is the same as that of the embodiment of Figure 3.
  • the effective tensile length of the bolt of the embodiment of Figure 12 is the same as that of the embodiment of Figure 10.
  • the effective tensile length of the locking bolt (4) is the sum of the head height of the fastening bolt (3) and the thickness of the fastening nut (7), the "bowl type” gasket (10) and the two coupling members.
  • the fastening bolt (3) has an effective tensile length which is the sum of the thicknesses of the two coupling members.
  • the bolt effective length of the embodiment of Figure 14 is the same as that of the embodiment of Figure 10.
  • the effective tension length of the locking bolt (4) is the length of the rigid sleeve (11) plus the fastening nut (7), the "bowl type” gasket (10) and the thickness of the two coupling members
  • the effective tensile length of the fastening bolt (3) is the length of the rigid sleeve (11) and the sum of the thicknesses of the two coupling members.
  • the effective tensile length of the locking bolt (4) is the height of the head of the fastening bolt (3) and the sum of the thickness of the flat pad (6) and the two coupling members, and the effective tensile length of the fastening bolt (3) For the right coupling (2) thickness.
  • the above calculation method is applicable to the embodiments of FIGS. 1, 3, 5, 6, 10, 12, 13, 14, and 16, if the yielding of the locking bolt (4) or the fastening bolt (3)
  • the strength or effective tensile length changes, and the diameter of the locking bolt (4) or the maximum load capacity of the bolt may also change.
  • the diameter of the fastening bolt (3) or the solid bolt is calculated by the bottom diameter of the thread. More reasonable. Because the diameter of the locking bolt (4) is relatively small, the depth of the thread is small, and the center of the bolt body is not made of holes, the cross-sectional area does not change, and the nominal diameter can be generally calculated.
  • the pre-tightening force is controlled by the tightening torque, the error is about ⁇ 25%; the pre-tightening force is controlled by the nut (or bolt) angle, and the error is about It is ⁇ 15%; the pre-tightening force is controlled according to the tightening torque and the nut rotation angle, which is higher than the method of controlling the pre-tightening force by the tightening torque alone or by the nut (or bolt) rotation angle, and the pre-tightening force error should be less than ⁇ 15%.
  • the resistance strain gauge is used to measure and control the tension of the bolt, that is, the preload force, to reach the desired After the preload, remove the strain gauge and screw into the lock bolt (4).
  • the tightening force of the tightening bolt (3) is less than ⁇ 1%.
  • the pre-tightening force error is about ⁇ 5%. If the force-measuring bolt is used directly, the pre-tightening force can be accurate to kilogram.
  • the preload force error should be less than ⁇ 15%. If the pre-tightening force error is selected ⁇ 15% for calculation and the calculated value meets the requirements, the actual error value of the bolt pre-tightening force can be controlled within ⁇ 15%, indicating that the actual pre-tightening force of the bolt definitely meets the requirements.
  • the tightening bolt (4) with a small cross-sectional area and a long length has a lower pre-tightening force F1
  • the tightening bolt with a larger cross-sectional area and a shorter length (3) takes a higher value of the pre-tightening force F2.
  • the maximum preload force Fmax of the fixing bolt (3) is equal to the pretensioning total pulling force P.
  • the problem of poor permeability of the large-diameter high-strength bolt during heat treatment is solved.
  • the bolt is easily hardened during quenching treatment, which improves the heat treatment effect of the bolt and stabilizes the quality. Suitable for mass production, and does not need to reduce working stress when in use.
  • the locking bolt (4) is made of high-strength bolt with a diameter of 30mm, the wall thickness of the fastening bolt (3) is 30mm, and the inner diameter of the center hole of the fastening bolt (3) is 31mm, then the maximum of the fastening bolt (3)
  • the quality is stable. It can be used as a high-strength bolt and used with the locking bolt (4). After that, it can meet the high strength requirements and anti-loose requirements of the larger diameter bolts for special occasions. Compared with the use of ordinary bolts, the diameter, volume and weight are relatively small, and the size and structure of the mechanical or component can be reduced or simplified. Have a stronger market competitiveness.
  • the head bolt size of the fastening bolt (3) is the same as that of the solid bolt, the material of the fastening bolt (3), the locking bolt (4), and the machining process are the same as those of the solid bolt, and the bolt (3) rod and head are tightened.
  • the shear strength of the joint should meet the requirements. If the material or processing technique of the locking bolt (4) is changed compared with the fastening bolt (3), the yield strength of the locking bolt (4) is increased or the fastening bolt (3) is made of a high-strength bolt of a larger diameter.
  • the thickness and outer diameter of the head of the fastening bolt (3) should be appropriately increased to ensure that the shear strength of the joint between the rod and the head of the fastening bolt (3) is not less than that when the fastening bolt (3) reaches the tensile strength.
  • the shear stress generated, the increase in the outer diameter of the head of the fastening bolt (3) is to control the contact surface contact stress of the head of the fastening bolt (3) and prevent plastic annular indentation on the surface of the coupling.
  • the shear strength of the anti-rotation nut (9) locking thread and the fastening thread connection shall not be less than the shear stress generated by the fastening bolt (3) reaching the maximum pre-tension upper limit, locking the thread and fastening
  • the compressive strength of the threaded joint shall not be less than the stress generated when the locking bolt (4) reaches the tensile strength.
  • the thread of the fastening bolt (3) and the locking bolt (4) can be made according to relevant standards. No matter whether it is left-handed or right-handed, the thread has no breaking point and does not damage the strength of the thread, which is beneficial to improve the pre-tightening force and the joint strength.
  • the "double bolt anti-loose method" described in the present invention is a new method for preventing loose bolts, and has a simple structure and convenience. Practical, the manufacturing process of the reverse rotation nut (9) and the active nut is basically the same.
  • the fastening bolt (3) only has one more hole in the center of the rod than the current bolt, and the manufacturing cost is relatively low, and the high-strength bolt is enlarged.
  • Application range mainly refers to the large-diameter high-strength bolt with stable quality, higher strength than the existing high-strength bolts, can meet the needs of some special occasions), and has application repeatability, so the prospect of industrial applicability is relatively broad.

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  • Engineering & Computer Science (AREA)
  • General Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Connection Of Plates (AREA)
  • Mutual Connection Of Rods And Tubes (AREA)

Abstract

La présente invention concerne un procédé anti-desserrage à double boulon, consistant à : usiner un trou de vis ou un trou de perçage dans une articulation, utiliser un boulon de verrouillage et un boulon de fixation de diamètres différents et de sens de vissage opposés ; usiner un trou central dans la tige du boulon de fixation, faire passer le boulon de verrouillage à travers le trou central du boulon de fixation et raccorder le boulon de verrouillage et le boulon de fixation au moyen du trou de vis et d'un écrou (comprenant un écrou de vissage inverse) de manière à obtenir l'effet anti-desserrage du boulon.
PCT/CN2015/074549 2014-04-11 2015-03-19 Procédé anti-desserrage à double boulon WO2015154614A1 (fr)

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CN201410152929.6 2014-04-11
CN201410152929.6A CN104976210A (zh) 2014-04-11 2014-04-11 双螺栓防松方法

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CN107725566A (zh) * 2017-11-30 2018-02-23 张小龙 防松螺栓螺母结构总成
CN107939804A (zh) * 2018-01-02 2018-04-20 福建泉州市金正机械有限公司 一种双杆螺栓
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CN108644215A (zh) * 2018-07-24 2018-10-12 合肥仨力机械制造有限公司 一种多功能螺栓
CN108644212A (zh) * 2018-07-24 2018-10-12 合肥仨力机械制造有限公司 一种带有止退结构的螺杆紧固件
CN108869502A (zh) * 2018-08-24 2018-11-23 上海纳特汽车标准件有限公司 点焊接地螺母柱
CN108895080A (zh) * 2018-09-14 2018-11-27 管铭 一种自扭力防松螺母及加工、使用方法
CN110107575A (zh) * 2019-05-30 2019-08-09 河北鑫泰轴承锻造有限公司 一种子母膨胀螺丝组件
CN111536131A (zh) * 2020-05-12 2020-08-14 三一重机有限公司 一种螺栓锁紧结构
CN113297711B (zh) * 2021-07-28 2022-01-07 广东电网有限责任公司中山供电局 一种无源松动预警螺栓的结构优化方法及装置
CN114321137B (zh) * 2021-11-20 2023-07-28 杨富云 提升螺纹副防松性能的方法及其辅弹垫

Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US904956A (en) * 1907-08-30 1908-11-24 Don J Higginbotham Nut-lock.
US2066402A (en) * 1935-06-01 1937-01-05 Daniel W Hinkel Electrical system
CN2893281Y (zh) * 2005-12-15 2007-04-25 董金 双丝自锁螺栓和螺母
WO2012070272A1 (fr) * 2010-11-25 2012-05-31 株式会社ハマ・システム Boulon
CN102506048A (zh) * 2011-08-05 2012-06-20 王大俊 防松固紧螺栓套件
US20120251263A1 (en) * 2011-03-31 2012-10-04 Hon Hai Precision Industry Co., Ltd. Connection assembly

Family Cites Families (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3772503A (en) * 1972-11-22 1973-11-13 Laitram Corp Course difference logic for use with digital magnetic compass
JPS501769U (fr) * 1973-05-04 1975-01-09
JP2767683B2 (ja) * 1994-02-16 1998-06-18 吉之助 長塩 耐振性ネジ
CN202338550U (zh) * 2011-11-17 2012-07-18 中铁十五局集团有限公司 一种拉式自锁螺栓

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US904956A (en) * 1907-08-30 1908-11-24 Don J Higginbotham Nut-lock.
US2066402A (en) * 1935-06-01 1937-01-05 Daniel W Hinkel Electrical system
CN2893281Y (zh) * 2005-12-15 2007-04-25 董金 双丝自锁螺栓和螺母
WO2012070272A1 (fr) * 2010-11-25 2012-05-31 株式会社ハマ・システム Boulon
US20120251263A1 (en) * 2011-03-31 2012-10-04 Hon Hai Precision Industry Co., Ltd. Connection assembly
CN102506048A (zh) * 2011-08-05 2012-06-20 王大俊 防松固紧螺栓套件

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN107356179A (zh) * 2017-08-21 2017-11-17 贵州航太精密制造有限公司 一种三针测量固定装置
CN107356179B (zh) * 2017-08-21 2023-07-11 贵州航太精密制造有限公司 一种三针测量固定装置
CN112528394A (zh) * 2020-11-09 2021-03-19 东风汽车集团有限公司 一种汽车发动机连杆螺栓选型及校核方法
CN112699499A (zh) * 2020-11-09 2021-04-23 东风汽车集团有限公司 一种汽油发动机飞轮螺栓选型和校核方法
CN112528394B (zh) * 2020-11-09 2022-04-15 东风汽车集团有限公司 一种汽车发动机连杆螺栓选型及校核方法
CN112699499B (zh) * 2020-11-09 2022-09-20 东风汽车集团有限公司 一种汽油发动机飞轮螺栓选型和校核方法
CN113021260A (zh) * 2021-03-18 2021-06-25 上汽大众汽车有限公司 一种车车拉刀块拆除螺栓的装置
CN114909382A (zh) * 2022-04-27 2022-08-16 江苏联储能源科技有限公司 一种高温熔盐泵用螺母防松结构及其安装方法
CN114909382B (zh) * 2022-04-27 2024-04-12 江苏联储能源科技有限公司 一种高温熔盐泵用螺母防松结构及其安装方法
CN115076205A (zh) * 2022-06-22 2022-09-20 东方电气风电股份有限公司 一种应用于风力发电机组油浸环境的新型螺栓防松方法

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