Thread Pitch Research Articles

Computer-Aided Thread Grinding without Form Dressing with Monitoring System to Prevent Wheel Interference.

A previous report proposed a computer-aided thread grinding method for generating helicoid without form dressing, using a standard-shaped grinding wheel independent of the final helicoid. The method uses a simple conical or plain wheel, without limitations of the diameter and base angle. The wheel axis is set three-dimensionally at the optimum computed angle of inclination. When the wheelthickness is large or the thread pitch is small, there is a risk of interference between the back of the wheel and helical surface opposing the helical surface being ground. When the grinding wheel is fed radially to the thread with a small thread pressure angle, there is also a risk of deformation of the helical surface generated. This report introduces a monitoring system to the original computer-aided thread grinding method, for protection against undesirable wheel interference, considering an axial displacement of the wheel and the maximum allowable displacement. The investigation shows that the monitoring system is effective to determine limits of thread dimensions without undesirable wheelinterference.

Effect of nut geometries on screw thread stress distribution: Photoelastic results

The structural merits of lip-type nuts engaging with ordinary bolts are assessed experimentally by means of frozen-stress photoelasticity. Thread pitch, lip radial thickness, and lip length are selected as design variables and scanned for possible effect on the maximum stress within the connection. In this respect, the length of lip is shown to play a major role while the other parameters have no decided effect. It is found that a nut with a lip covering 60 percent of total height reduces the stress concentration in the screw by nearly 40 percent with respect to a standard nut of equal height and outside diameter. This improvement is achieved without producing higher stresses in the nut than in the screw.

Recognition of threaded objects by spatial spectrum analysis

An optical processing system for the recognition and sorting of machine screws is presented. A theoretical analysis of the diffraction problem is detailed which provides a basis for selecting a set of features used in the sorting algorithm. These features are used to discriminate between screws based on their diameter and thread pitch.

Thermal-hydraulics of helical-type helium/helium intermediate heat exchangers (IHX) for nuclear process heat applications of high-temperature gas-cooled reactors (HTR) — fundamental research and large-scale tests

The influence of the yaw angle on heat transfer and pressure drop was studied by testing tube banks of straight tubes at different angles between the flow direction and the tube axis in the range 15° ⩽ ϕ ⩽ 90° (cross advantages caused by an opposite inclination of neighbouring tube layers are shown. Results from the fundamental work on straight tube banks were checked at a semiexperimental helical-type heat exchanger for a nuclear process heat application, which is characterized by a large thread pitch and opposite-sense coiling of the tubes.

Casing and Tubing Connection Stresses

Schneider, Warren P., SPE, Lone Star Steel Co. Summary By use of a simple theoretical analysis, the transverse stresses in couplings and pipe ends of API eight-round and buttress threaded connections caused by makeup and pressures have been calculated and tabulated. Stresses for 680 specified combinations of casing and tubing size, grade, and thread type are examined. Introduction More now than at any other time in the search for petroleum energy reserves, operators are using drilling and production equipment nearer the limits of performance capabilities and, at the same time, facing more costly consequences of failure. The rapid advances in abilities to reach greater depths are challenging designers of equipment that must safely contain the high pressures attendant with today's greater drilling depths. The recent surge in drilling activity has resulted in more frequent encounters with high pressure. Casing and tubing play an important role in both drilling for and extracting oil and gas. Their contribution to the success or failure of the effort and their cost warrant thoughtful design and selection. When unexpectedly high pressures are encountered downhole, these tubulars can be the last defense against loss of equipment, the well, and even lives. It has been established that the use of steel pipe is the most practical means to make a pressure vessel suitable for the drilling and production environment. Many practical considerations require that the pipe be used in separate lengths, each length being joined in sequence as it is lowered into the wellbore. The connection between lengths must sustain high tensile loads and at the same time provide pressure containment from both net internal and external pressures. This connection is made through the joining of threaded pipe ends, most commonly with the aid of a threaded coupling. With the exception of a growing number of proprietary connections, the configuration and specifications of these connections have been standardized through the efforts of the API. To understand the performance of these important connections more thoroughly, the stresses in API round and buttress threaded connections were examined. The results of the application of a previously introduced analysis method to couplings and pipe ends of the full range of sizes, weights, and grades of API casing and tubing are presented. Connection Description API casing thread types include short round thread, long round thread, buttress, and extreme-line. Except for extreme-line, the connections all include use of a coupling. Tubing thread types include nonupset (NUE), external-upset (EUE), and integral joint. NUE and EUE connections use a coupling. This discussion is restricted to short, long, and buttress threaded casing connections and NUE and EUE tubing connections because of predominant use of those connection types. predominant use of those connection types. For each of these types, the union is made by screwing a threaded pipe end into a similarly threaded coupling (Fig. 1). Both pipe and coupling threads are cut on a taper such that at a certain point of engagement the threads of the coupling and pipe come into full intimate contact. This is called the hand-tight position. The thread taper for both pipe end and coupling is specified at 3/4 in./ft on the diameter, except for taper on buttress threads on pipe 16-in. OD and larger, which is 1 in./ft. Two thread profiles are used with these connections: rounded "V", more commonly known as round thread, and buttress (Fig. 2). Thread pitch on casing and tubing round threads is 8 threads per inch, or 10 threads per inch in the smaller tubing sizes. Buttress pitch is 5 threads per inch. As the pipe end advances farther into the coupling through rotation, or makeup, past the hand-tight position, an increasing amount of interference between the pipe and the coupling occurs because of the taper. Expansion of the coupling and compression of the pipe end caused by the wedging action is a major source of tangential, or hoop, stress in both members. The amount of makeup to be applied to a given connection is prescribed. prescribed. JPT p. 1851

Checking slack in a discontinuous internal thread with respect to its outside diameter

Fig. i Any variation :in the threaded surface relative to the outside diameter in the nut of a ball--screw system can be considered as change in the dimension h or H (Fig. i). The system has oval windows in the ball channels, and therefore the tip of the measuring device must be directed strictly along the spiral line in accordance with the pitch of the thread, and there must be no motion of the tip along the pitch when it or the associated supporting element falls in the gaps in the thread. For design reasons it is more convenient to measure the change in dimension H.

The Split Nut: An Easy to Fit Nut with a Higher Inherent Strength

The split nut, invented by Commander P. Y. Williams, is easier to fit than the conventional nut and has a higher inherent strength. The two halves of the nut, which is coned at both ends, fit into a conical washer that forces them tightly onto the bolt. The positive clamping action increases the radial load on the threads, which reduces the tensile bending stress at the root of the thread. The load distribution in the threads is also improved, because the change in thread pitch caused by the axial deformation of the nut and bolt is partly compensated by a rotation of the nut halves about an axis normal to that of the bolt. These two effects reduce the maximum tensile stress at the root of the thread to about half of that in the conventional nut.

高強度ボルトの疲れ強さ向上について

It has been said that the fatigue strength of high strength bolts does not increase in proportion to the statical tensile strength. In order to establish the stable method for the improvement of fatigue strength of high strength bolts, the large scale experiments are done, referring to the published papers. The six factors including the pitch modification and the sequence of thread finishing are taken, and the design of experiment is based on the orthogonal array L32 (231). As the method of fatigue testing, the staircase method with small samples is used. The obtained conclusions are as follows : (1) In the range of the present experiments, the effects of nominal diameter and pitch of screw threads are not significant, and the effects of pitch modification, strength grade (D), sequence of thread finishing and mean stress in fatigue testing (G) as well as the interaction between D and G are significant. (2) The slight reducing (-0.3%) of the pitch of bolt threads comparing with that of nut threads and the thread rolling after heat treatment are effective to improve the fatigue strength of high strength bolts, and especially, the use of both actions has an excellent effect.

ねじの締付管理方法の比較

In this paper, the torque and the angle control methods, which are most usually used in screw tightening, and the newly developed gradient control method are compared and a policy for the selection of them is discussed. For this purpose a tightening test machine which can test the above three methods is designed and manufactured. Firstly, using the machine, fundamental experiments are carried out taking account of the following factors : pitch of screw threads (A), surface treatment (B), lubrication (C) and tightening speed (D), and it is pointed out that the effect of the lubrication condition is especially significant. Secondly, in the case where the factors (A), (B) and (D) are fixed and the factor (C) is with or without lubrication, the three control methods are compared, and it is found that the dispersions of clamping force become greater in order of the angle, the gradient and the torque control methods. Finally, a new tightening method is presented, in which bolted joints are tightened with the torque or the angle control methods using the value of the torque or the angle found in the case of tightening them with the gradient control method, and this method is confirmed to be efficient.

A study on tapping wrought aluminum (1st Report)

The tapping (tapping for screwing) test for wrought aluminum alloys is reported in th paper. Three sorts of alloys, or 17S and 24S as typical alloys of high tensile strength and 56S as an anticorrosion alloy, were examined for tapping machinability such as tapping resistance, state of rough surface, accuracy of finished surface, etc.The results obtained were summarized as follows.The tapping torque was not affected by cutting speed of 5-10m/min in this experiment, but the torque at a constant rake angle slightly increased with the increase in tapping load. The torques varied according to the sorts of materials. Their values were arranged in ascending order of 24 S-F, 17 S-F, and 56 S-F, among which 24 S-F gave the most stable value, while the latter two gave unstable ones, having large deviation. It seemed that the state of finished surface was dependent upon rake angle and tapping load, but was independent of cutting speed; and there would be found out optimum tapping conditions for obtaining the best surface state. It was observed that the pitch of thread agreed with the tap within the limit of ever in measurement regardless of tapping conditions, and the angle of thread was larger by 30-60' than that of tap. The value of microhardness tended to increase up to about Hv=10-20 in the neighborgood of tapped surface.

Application of Interferometry to the Measurement of the Pitch of Threads on a Lead Screw

A rapid, interferometric method for measuring the pitch of a nonrotating lead screw that involves no mechanical contact with the thread is described. The moving plane mirror of a Michelson interferometer is set on the axis of the lead screw. The lead screw is mounted on the carriage of a machine which moves it parallel to its axis. The Michelson fringes are counted continuously as the screw threads are moved across a light beam. The Michelson interferometer uses the green line of a (198)Hg isotope electrodeless lamp. The passage of a pitch point, to punctuate the fringe count, is sensed by photoelectric microscopes, and associated electronic circuitry, as described herein. The performance of the apparatus is presented.

めねじの測定

It is very difficult to measure the thread pitch and angle in the nut. In this report, the plastic material such as Cu amalgam and dental wax is casted in the nut to obtain a casting for the nut. Its pitch and angle are easily measured, because the casting has external thread. The coefficient of thermal expansion of the dental wax is measured and the aging effect of Cu. amalgam is researched in order to research the source of the error for this measurement. As the result, Cu amalgam is preferable to the dental wax for the measurement of the nut.

Strength of Screw Threads of Whitworth Form

SummaryA Stress analysis of screw threads of Whitworth form has been performed.The critical stress in the threads is a shear stress, and this may be expressed simply in the form:–whereSmax=shear stress.f=distribution factor.= 1.0 when screw and nut are both in tension or compression.= 2.0 when screw and nut are in tension and compression respectively, unless specially designed for an improved distribution of load.k = coefficient, depending mainly on fit, but also on pitch of threads, L and D.<0.8 for close fit.<0.9 for medium fit.<1.0 for free fit.P=axial load.L=length of engagement.D=nominal diameter.