Patent Application
20070178043
The present invention relates to a sliding material, a manufacturing method therefor and a device employing the slide material.
Lubricants (sliding materials) that reduce friction between bodies have transitioned from solid lubricants to fluid lubricants. However, since the use of fluid lubricants is restricted in environments where fluids cannot be used such as vacuums and high temperature environments, problems arise such as insufficient reduction in frictional force and low durability. Also, with the appearance of tiny machinery such as micromachines and nanomachines, the development of a lubricant and lubrication system that can be used even in tiny machinery is eagerly awaited.
As a lubrication system applicable to tiny machinery, a lubrication system has been proposed that sandwiches carbon ball molecules or carbon tube molecules between graphite substrates (Patent Document 1). In this lubrication system, C60 molecules are vapor-deposited on a graphite substrate surface to form a monolayer C60 molecular film. By utilizing the rolling of the C60 molecules, a separate graphite substrate that is placed on the C60 molecular film can be made to slide.
However, in the case of forming a C60 molecular film by vapor-deposition, regulating the C60 molecular film formed on the graphite substrate surface to a monolayer is difficult, and it is easy in practice for the C60 molecules to overlap over two layers. When a bi-layer C60 molecular film is formed, rolling of the C60 molecules is hindered, which increases the friction between the two graphite substrates. Fabrication by the vapor-deposition method of a lubrication system that can minimize friction between graphite substrates has involved such difficulties. Also, the durability of the lubrication system that sandwiches carbon ball molecules or carbon tube molecules between graphite substrates is not sufficiently satisfactory.
[Patent Document 1] Japanese Unexamined Patent Application, First Publication No. 2003-62799.
Problem to be Solved by the Invention
The object of the present invention is to provide a sliding material that can be used in machines/devices of various sizes ranging from heavy machinery such as automobiles to nanomachines without restrictions on the environment it can be used, can minimize friction compared to conventional types, and has superior durability; a method of manufacture that can readily manufacture the sliding material; and a device that uses the sliding material.
Expedient for Solving the Problem
The sliding material of a present invention is characterized by having hexagonal crystals that form a layer structure and ball-shaped molecules inserted in interlayers of the hexagonal crystals.
The structure in which ball-shaped molecules are inserted in interlayers of the hexagonal crystals preferably exists in plurality repetition in the thickness direction.
The ball-shaped molecules preferably form a monolayer in each interlayer of the hexagonal crystals.
The ball-shaped molecules preferably have five-member rings or six-member rings of carbon.
The distance between ball-shaped molecules in the thickness direction is preferably 1.4 nanometers or less.
Also, the sliding material of the present invention may be a mixture of the sliding material and a solid or fluid, and may be one provided on a solid surface.
The method of manufacturing the sliding material of the present invention is characterized by having a step that widens the interlayer of hexagonal crystals forming a layer structure and a step that inserts ball-shaped molecules in the interlayer of the hexagonal crystals.
In the manufacturing method, it is preferable to insert the ball-shaped molecules in the interlayer of the hexagonal crystals by sublimating the ball-shaped molecules.
The device of the present invention is characterized by having a sliding portion in which at least one member slides with respect to another member, and being provided with the sliding material of the present invention on the surface of at least one member of the sliding portion.
A timepiece of the present invention is a timepiece having at least one set of gears that transmits power and a changeover mechanism that corrects the time, characterized by the gears and/or the changeover mechanism having a sliding portion in which at least one member slides with respect to another member and being provided with the sliding material of the present invention on the surface of at least one member of the sliding portion.
The motor of the present invention is characterized by having a sliding portion in which at least one member slides with respect to another member, and being provided with the sliding material of the present invention on the surface of at least one member of the sliding portion.
Effect of the Invention
The sliding material of the present invention can be used in machines/devices of various sizes ranging from heavy machinery such as automobiles to nanomachines without restrictions on the environment it can be used, is highly effective in reducing friction compared to conventional types, and has superior durability.
The sliding material of the present invention can be readily manufactured according to the manufacturing method for the sliding material of the present invention.
The device, timepiece, and motor of the present invention can minimize friction in the sliding portion and can maintain the low friction state for a long period.
(Sliding Material)
The sliding material of the present invention is an intercalation compound having hexagonal crystals that form a layer structure and ball-shaped molecules inserted (intercalated) in the interlayers of the hexagonal crystals. The structure of the ball-shaped molecules inserted in the interlayers of the hexagonal crystals preferably exists in multiple repetition in the thickness direction.
Specific examples of the hexagonal crystal forming a layer structure include graphite and molybdenum disulfide, and the like, with graphite being preferred. The graphite has a layer structure in which a large number of planar layers of connected six-member rings of carbon atoms are overlapped. The graphite shape may be suitably selected in accordance with the use of the sliding material, with examples including a film shape and powder shape.
Since the ball-shaped molecules are required to have a strong interaction with the graphite, those having five-member rings or six-member rings of carbon are preferred. Also, since the ball-shaped molecules are required to easily enter the graphite interlayer and be stable, those having a diameter of 0.7 nanometer or more and 0.8 nanometer or less are preferred.
Fullerenes are particularly preferred as the ball-shaped molecules. Fullerenes are hollow, shell-shaped carbon ball molecules closed by a network of five-member rings or six-member rings of carbon. Examples of fullerenes include C60 molecules, C70 molecules, C76 molecules, C78 molecules, C80 molecules, C82 molecules, C84 molecules, C86 molecules, C88 molecules, C90 molecules, C92 molecules, C94 molecules, C96 molecules, etc. C60 molecules and C70 molecules are preferred as fullerene molecules since they easily roll, and as a result a sliding material is obtained that is effective in reducing friction.
A specific example is described below in which the hexagonal crystals are graphite and the ball-shaped molecules are C60 molecules.
The C60 molecules 4 are aligned to form a monolayer between the graphite layers 3. By having the C60 molecules 4 form a monolayer between the graphite layers 3, the molecules easily roll, and as a result a sliding material is obtained that is effective in reducing friction.
It is preferable that the layer formed by the C60 molecules 4 have a dense structure with small gaps between the C60 molecules so as to further facilitate the rolling of the C60 molecules 4. A dense structure specifically means a structure in which the C60 molecules 4 are aligned so that the center-to-center spacing between adjacent C60 molecules 4 and 4 in the planar direction is 1 nanometer.
The distance between the C60 molecules 4 in the thickness direction is preferably 1.4 nanometers or less to ensure a stable structure. The distance between the C60 molecules 4 in the thickness direction is, as shown in
The sliding material of the present invention may be mixed with a solid or fluid, and this mixture may be used as the sliding material (solid lubricant or fluid lubricant). A solid that is mixed with the sliding material includes a resin in which the base resin is polystyrene, polyethylene terephthalate, polycarbonate, polyacetal (polyoxymethylene), polyamide, denatured polyphenylene ether, polybutylene terephthalate, polyphenylene sulfide, polyether ether ketone, or polyetherimide. A fluid that is mixed with the sliding material includes lubricating oil such as gear oil, machine oil, bearing oil, and precision instrument oil.
Also, the sliding material of the present invention may be provided on a solid surface, with this solid being used as the sliding material. This sliding material may be a layer of a sliding material that is formed by applying the sliding material on a solid surface, with examples including nickel plating, zinc plating, aluminum plating, copper plating, gold plating, and the like. A solid on whose surface the sliding material is applied includes resins such as polycarbonate and polyacetal, brass, steel, aluminum alloy, copper alloy, magnesium alloy, and the like.
(Method of Manufacture of Sliding Material)
The sliding material of the present invention is produced by a step that widens the interlayer of hexagonal crystals forming a layer structure (hereafter referred to as the expansion step) and a step that inserts ball-shaped molecules in the interlayer of the hexagonal crystals (hereafter referred to as the intercalation step).
The interlayer of the hexagonal crystals is widened by immersing the hexagonal crystals in a liquid mixture of sulfuric acid and nitric acid, drying the hexagonal crystal, and then applying heat. The mixture ratio of the sulfuric acid and nitric acid (sulfuric acid:nitric acid) is preferably 4:1 (volumetric ratio). The concentrations of the sulfuric acid and nitric acid are preferably 100%. The immersion time is preferably 16 to 17 hours, and the temperature of the liquid mixture during immersion is preferably 20° C. to 30° C. Also, the immersion is preferably performed while agitating the liquid mixture and the hexagonal crystals. The heating of the hexagonal crystals after drying is preferably performed at 1000 to 1100° C.
The insertion step is a step that specifically inserts the ball-shaped molecules in the interlayer of the hexagonal crystals widened by the expansion step by sublimating the ball-shaped molecules. Sublimation of the ball-shaped molecules is performed by heating to a temperature at which the ball-shaped molecules sublimate. In the case of the ball-shaped molecules being C60 molecules, heating to 550 to 600° C. is performed. The heating time is preferably 2 to 3 weeks. Also, in order to prevent oxidation of the ball-shaped molecules, the sublimation of the ball-shaped molecules is preferably performed in a vacuum or in an atmosphere of an inert gas such as nitrogen gas or the like.
Moreover, the manufacturing method of the sliding material of the present invention preferably has a step in which the ball-shaped molecules inserted in the interlayer of the hexagonal crystals form a monolayer in each interlayer (hereafter referred to as the monolayering step). When inserting the ball-shaped molecules in the interlayer of the hexagonal crystals by sublimating the ball-shaped molecules, normally since the ball-shaped molecules inserted in the interlayer of the hexagonal crystals are inserted so as form a monolayer in each interlayer, the intercalation step and the monolayering step proceed simultaneously.
(Device)
The device of the present invention has a sliding portion in which at least one member slides with respect to another member, and provides the sliding material of the present invention on the surface of at least one member of the sliding portion.
Examples of the device include a timepiece, a motor, an automobile, a generator, an airplane, a marine vessel, a motorcycle, a camera, a video camera, spectacles, measuring equipment, photographic equipment, sound recording equipment, sound recording and video recording equipment, printing machines, machining equipment, processing machinery, assembly equipment, conveyance equipment, haulage equipment, dispensing equipment (dispenser), and machinery having bearings, and the like.
Examples of the sliding portion of a device include the gear tooth flank of a timepiece, the bearing portion of the gearing of a timepiece, a brush of a motor, a stator, a rotor, a car motor piston, the turbine bearing portion of a generator, a camera shutter, spectacle frames, and the like.
(Timepiece)
A timepiece that is an example of a device of the present invention includes one having at least one set of gears for transmitting power and a changeover mechanism that corrects the time.
The gears and the changeover mechanism have a sliding portion in which at least one member slides with respect to another member, with the sliding material of the present invention provided on the surface of at least the one member of the sliding portion.
The sliding material of the present invention as explained above is based on slippage within a solid, unlike conventional material for improving friction characteristics by improvements to the solid surface. That is, when shearing force is applied to a hexagonal crystal in the state of ball-shaped molecules inserted in the interlayers of hexagonal crystals forming a layer structure, the ball-shaped molecules roll in the interlayers of the hexagonal crystals, whereby fluctuations are caused and super lubrication is brought about in which the friction is extremely close to zero. The structure in which ball-shaped molecules are inserted in the interlayers of the hexagonal crystals exists in unlimited repetition in the thickness direction in the sliding material of the present invention. Therefore, in the sliding material of the present invention, super lubrication is brought about in which the friction approximates zero by in-solid slipping that utilizes the slip surface (the interfacial boundary of the hexagonal crystal layer and the layer of ball-shaped molecules) that exists in unlimited repetition in the thickness direction in the sliding material of the present invention.
Since the sliding material of the present invention utilizes in-solid slipping, the effect of water and effects due to surface abrasion, etc. can be disregarded, and the durability is excellent. Also, since there is no anisotropy on the sliding surface, there is no anisotropy in the frictional force as well, leading to free sliding in all directions within the plane.
Also, by using hexagonal crystals with nanometer- or micrometer-size thicknesses, the obtained sliding material can be applied to tiny machinery such as nanomachines and micromachines. By using powdered hexagonal crystals, the obtained sliding material can be used as a lubricant for roller bearings and the like in conventional machinery.
Examples are illustrated below.
First, 100% sulfuric acid and 100% nitric acid were mixed at a ratio of sulfuric acid:nitric acid=4:1 (volume ratio), and Highly Oriented Pyrolytic Graphite (HOPG) (available from Veeco, Grade-ZYH) measuring 2.2 mm×2.2 mm×0.2 mm was put into 50 ml of the liquid mixture, and the mixture was then agitated for 16 hours at 20° C. using a stirrer 11 as shown in
As shown in
Subsequently, 7.54 mg of C60 molecules (made by MTR with a purity of 99.98% or greater) and 3.77 mg of interlayer-widened HOPG was put in a quartz tube, which was sealed after being evacuated.
As shown in
The structure of the obtained sliding material was confirmed using a high-resolution electron microscope (made by JEOL, model JEM-2000EX). A high-resolution electron microscope image is shown in
The friction characteristics of the obtained sliding material were investigated using a frictional force microscope (made by Seiko Instruments Inc., model SPI300). Specifically, a probe was made to travel back and forth over the sliding material surface while applying a fixed load, at which time the frictional force was measured. The result of load 0 nN is shown in
From the result of FIGS. 8 to 13, the state in which the static friction force and the dynamic friction force approach zero is realized at a load of 100 nN. Also, no anisotropy of the frictional force was observed.
An example is now explained that provides the sliding material of the first example in the sliding portion of an analog timepiece.
(Structure of Analog Timepiece)
The movement (machinery) of the analog timepiece used in the second example shall be explained first referring to FIGS. 14 to 17.
A movement (machinery) 100 of an analog timepiece is provided with a support member of the movement 100 constituted from a main plate 102, a train wheel bridge 112, and a second wheel bridge 114; a winding stem 110 that is incorporated so as to be pivotable in a winding stem guide hole of the main plate 102; an insulating plate 160; a switch spring 162; a circuit block 116 that is fixed to the main plate 102 and the train wheel bridge 112 by the switch spring 162 through the insulating plate 160; a battery 120 that constitutes the power source of the analog timepiece; an IC 118 and a crystal oscillator 122 that are attached to the circuit block 116; a changeover spring 166 for determining the position of the axial direction of the winding stem 110 that is integrally formed with the switch spring 162; an hour motor 210 constituted from a coil block A212, a stator A214, and an hour rotor 216; an hour display wheel train constituted from an intermediate minute wheel 222, a minute wheel 224, and an hour wheel 226; a minute motor 240 constituted from a coil block B242, a stator B244, and a minute rotor 246; a minute display wheel train constituted from a second intermediate wheel B252, a second intermediate wheel A254, and a minute wheel 256; a second motor 270 constituted from a coil block C272, a stator C274, and a second rotor 276; and a second display wheel train constituted from a fifth wheel 282 and a second wheel 284.
The movement (machinery) 100 is constituted so as to show the “hour” of the present time with an hour hand 230 by rotation of the hour display wheel train from rotation of the hour motor 210. It is also constituted so as to show the “minute” of the present time with a minute hand 260 by rotation of the minute display wheel train from rotation of the minute motor 240. It is also constituted so as to show the “second” of the present time with a second hand 290 by rotation of the second display wheel train from rotation of the second motor 270.
A rechargeable secondary battery can be used as the battery 120, and a rechargeable capacitor can also be used. The crystal oscillator 122 constitutes the source oscillation of the analog timepiece, and oscillates at, for example, 32, 768 Hertz.
(Placement of Sliding Material)
In the movement (machinery) 100, the sliding material of the first example was provided as follows in the bearing portion of the second motor 270 (the upper bearing portion constituted from the second motor bearing portion 276a and the train wheel bridge 112, and the lower bearing portion constituted from the second motor bearing portion 276b and the main plate 102).
First, a portion of the sliding material obtained in the first example was separated to obtain a sliding material with a thickness of 1 μm.
An epoxy-based adhesive was applied at a thickness of 0.1 μm on the second motor bearing portion 276a and a portion of the train wheel bridge 112 in contact with the second motor bearing portion 276a. Simultaneously, an epoxy-based adhesive was applied to the second motor bearing portion 276b and a portion of the main plate 102 in contact with the second motor bearing portion 276b.
Then, the separated sliding material was attached to the applied epoxy-based adhesive, and the epoxy-based adhesive was sufficiently dried by being left to stand for one hour at 25° C.
Similarly, the sliding material of the first example was also provided in the bearing portions of the hour motor 210, the hour display wheel train, the minute motor 240, the minute display wheel train, and the second display wheel train. As a result, since friction loss of the sliding portion could be reduced, the battery life could be extended.
In the movement (machinery) 100, the sliding material of the first example was provided as follows in the bearing portion of the second motor 270 (the upper bearing portion constituted from the second motor bearing portion 276a and the train wheel bridge 112, and the lower bearing portion constituted from the second motor bearing portion 276b and the main plate 102).
First, the sliding material obtained in the first example was ground to a particle diameter of 0.1 to 1 μm. Then a lubricant for clocks (SYNTHETIC OIL 9010 (made by MOEBIUS)) and the ground-up sliding material were mixed at a ratio of 10 parts sliding material to 100 parts lubricant.
The lubricant mixed with the sliding material was applied on the second motor bearing portion 276a and a portion of the train wheel bridge 112 in contact with the second motor bearing portion 276a. Simultaneously, the lubricant mixed with the sliding material was applied to the second motor bearing portion 276b and a portion of the main plate 102 in contact with the second motor bearing portion 276b.
Similarly, the sliding material of the first example was also provided in the bearing portions of the hour motor 210, the hour display wheel train, the minute motor 240, the minute display wheel train, and the second display wheel train. As a result, since friction loss of the sliding portion could be reduced, the battery life could be extended.
Explained below is an example that provides the sliding material of the first example in the sliding portions of a mechanical timepiece in which a main spring serves as the power source.
(Structure of Mechanical Timepiece)
First, the movement (machinery) of the mechanical timepiece used in the fourth example shall be explained first referring to FIGS. 18 to 21.
The movement (machinery) 300 of the mechanical timepiece has a main plate 302 that constitutes a base plate of the movement. A winding stem 310 is incorporated so as to be pivotable in a winding stem guide hole 302a of the main plate 302. Normally, among the two sides of the main plate, the dial plate-side thereof is referred to as the “back side” of the movement, and the side opposite the dial plate side is referred to as the “front side” of the movement. The wheel train incorporated in the “front side” of the movement is referred to as the “outside wheel train”, and wheel train incorporated in the “back side” of the movement is referred to as the “backside wheel train”. The position in the axial direction of the winding stem 310 is determined by a changeover device that includes a setting lever 390, a yoke 392, a latch spring 394, and a yoke friction spring 396. A winding pinion 312 is rotatably provided in a guide shaft portion of the winding stem 310.
A clutch wheel 398 is disposed so as to be coaxial with the winding stem 310 with respect to the angle portion of the winding stem 310. When the winding stem 310 is rotated to the state of being in a first winding stem position (zeroth step) that is nearest to the inside of the movement along the axis of rotation, the winding pinion 312 is constituted to turn via rotation of the clutch wheel 398. A crown wheel 314 is constituted so as to rotate by rotation of the winding pinion 312. A ratchet wheel 316 rotates by rotation of the crown wheel 314. Rotation of the ratchet wheel 316 winds up the main spring 322 housed in a barrel wheel 320. A center wheel 324 is constituted so as to rotate by rotation of the barrel wheel 320. An escapement wheel 330 rotates through rotation of a fourth wheel 328, a third wheel 326, and the center wheel 324. The barrel wheel 320, the center wheel 324, the third wheel 326, and the fourth wheel 328 constitute the outside wheel train.
A setting wheel 397 is rotatably disposed with respect to the main plate 302. A minute wheel 358 is rotatably disposed with respect to the main plate 302. The gear portion of the setting wheel 397 is constituted to mesh with the gear portion of the minute gearing of the minute wheel 358. The gear portion of the minute gearing of the minute wheel 358 is constituted so as to mesh with the gear portion of a cannon pinion 350. The pinion portion of the minute pinion of the minute wheel 358 is constituted to mesh with the gear portion of a cylinder wheel 354. A minute pusher 384 supports the setting wheel 397 and the minute wheel 358 so as to be rotatable with respect to the main plate 302. When the winding stem 310 is rotated to the state of being in a second winding stem position (first step) on the outside of the movement along the axis of rotation, the setting wheel 397 is constituted to rotate by rotation of the clutch wheel 398. Moreover, when the winding stem 310 is rotated to the state of being in the first step, the minute wheel 358 is constituted to rotate by rotation of the setting wheel 397. In this state, when the minute wheel 358 rotates, the cannon pinion 350 and the cylinder wheel 354 rotate, and accordingly an hour hand 356 and a minute hand 352 rotate, so that time correction of the timepiece can be performed.
An escapement/controller that controls the rotation of the outside wheel train includes a balance 340, an escapement wheel 330, and an pallet fork 342. The balance 340 includes a balance staff 340a, a balance wheel and balance spring 340c. Based on rotation of the center wheel 324, the cannon pinion 350 rotates simultaneously. The minute hand 352 attached to the cannon pinion 350 shows “minutes”. A slip mechanism with respect to the center wheel 324 is provided in the cannon pinion 350. Based on rotation of the cannon pinion 350, the cylinder wheel 354 rotates via rotation of the minute wheel 358. The hour hand 356 attached to the cylinder wheel 354 shows the “hour”. The balance spring 340c is a flat spring with a swirling (spiral) shape having a plurality of windings. The inner end portion of the balance spring 340c is fixed to a collet 340d that is fixed to the balance staff 340a, and the outer end portion of the balance spring 340c is fixed by a screw fastening through a stud 370a that is attached to a stud support 370 that is fixed to a balance bridge 366. A regulator pin 368 is rotatably attached to the balance bridge 366. The balance 340 is supported so as to be rotatable with respect to the main plate 302 and the balance bridge 366.
The barrel wheel 320 is provided with a barrel drum 320d, a barrel arbor 320f, and a main spring 322. The barrel arbor 320f includes an upper shaft 320a and a lower shaft 320b. The barrel arbor 320f is formed with a metal such as carbon steel. The barrel drum 320d is formed with a metal such as brass. The center wheel 324 includes an upper shaft 324a, a lower shaft 324b, a pinion portion 324c, a gearwheel portion 324d, and a bead portion 324h. The pinion portion 324c of the center wheel 324 is constituted so as to mesh with the barrel drum 320d. The upper shaft 324a, the lower shaft 324b, and the bead portion 324b are formed with a metal such as carbon steel. The gearwheel portion 324d is formed with a metal such as brass. The third wheel 326 includes an upper shaft 326a, a lower shaft 326b, a pinion portion 326c, and a gearwheel portion 326d. The pinion portion 326c of the third wheel 326 is constituted so as to mesh with the gearwheel portion 324d. The fourth wheel 328 includes an upper shaft 328a, a lower shaft 328b, a pinion portion 328c, and a gearwheel portion 328d. The upper shaft 328a and the lower shaft 328b are formed with a metal such as carbon steel. The gearwheel portion 328d is formed with a metal such as brass. The escapement wheel 330 includes an upper shaft 330a, a lower shaft 330b, a pinion portion 330c, and a gearwheel portion 330d. The pinion portion 330c of the escapement wheel 330 is constituted so as to mesh with the gearwheel portion 328d. The gearwheel portion 328d of the escapement wheel 330 is constituted so as to mesh with a pallet stone 343 that is bonded to the pallet fork 342. The pallet fork 342 is provided with an pallet fork (incomplete) 342d and an pallet staff 342f. The pallet staff 342f includes an upper shaft 342a and a lower shaft 342b.
The barrel wheel 320 is supported so as to be rotatable with respect to the main plate 302 and a barrel bridge 360. That is, the upper shaft 320a of the barrel arbor 320f is supported so as to be rotatable with respect to the barrel bridge 360. The lower shaft 320b of the barrel arbor 320f is supported so as to be rotatable with respect to the main plate 302. The center wheel 324, the third wheel 326, the fourth wheel 328, and the escapement wheel 330 are supported so as to be rotatable with respect to the main plate 302 and a train wheel bridge 362. That is, the upper shaft 324a of the center wheel 324, the upper shaft 326a of the third wheel 326, the upper shaft 328a of the fourth wheel 328, and the upper shaft 330a of the escapement wheel 330 are supported so as to be rotatable with respect to the train wheel bridge 362. Also, the lower shaft 324b of the center wheel 324, the lower shaft 326b of the third wheel 326, the lower shaft 328b of the fourth wheel 328, and the lower shaft 330b of the escapement wheel 330 are supported so as to be rotatable with respect to the main plate 302. The pallet fork 342 is supported so as to be rotatable with respect to the main plate 302 and an pallet fork bearing 364. That is, the upper shaft 342a of the pallet fork 342 is supported so as to be rotatable with respect to the pallet fork bearing 364. The lower shaft 342b of the pallet fork 342 is rotatably supported with respect to the main plate 302.
(Placement of Sliding Material)
In the movement (machinery) 300, the sliding material of the first example was provided as follows in the sliding portion with the escapement wheel 330 (the gearwheel portion 330d) and the pallet stone 343.
First, a portion of the sliding material obtained in the first example was separated to obtain a sliding material with a thickness of 1 μm.
An epoxy-based adhesive was applied at a thickness of 0.1 μm on the gearwheel portion 330d of the escape wheel 330 and the pallet stone 343.
Then, the separated sliding material was attached to the applied epoxy-based adhesive, and the epoxy-based adhesive was sufficiently dried by being left to stand for one hour at 25° C.
Similarly, the sliding material of the first example was also provided in the bearing portions of the center wheel 324, the third wheel 326, the fourth wheel 328, the balance staff 340a and the changeover wheel. As a result, since friction loss of the sliding portion could be reduced, the duration of the main spring could be extended.
In the movement (machinery) 300, the sliding material of the first example was provided as follows in the sliding portion with escape wheel 330 (the gearwheel portion 330d) and the pallet stone 343.
First, the sliding material obtained in the first example was ground to a particle diameter of 0.1 to 1 μm. Then a lubricant for timepieces (SYNTHETIC OIL 9010 (made by MOEBIUS)) and the ground-up sliding material were mixed at a ratio of 10 parts sliding material to 100 parts lubricant.
The lubricant mixed with the sliding material was applied on the gearwheel portion 330d of the escapement wheel 330 and the pallet stone 343.
Similarly, the sliding material of the first example was also provided in the bearing portions of the center wheel 324, the third wheel 326, the fourth wheel 328, the balance staff 340a and the changeover wheel. As a result, since friction loss of the sliding portion could be reduced, the duration of the main spring could be extended.
The sliding material of the present invention can be used in machines/devices of various sizes ranging from heavy machinery such as automobiles to nanomachines without restrictions on the environment it can be used, can minimize friction compared to conventional types, and has superior durability.
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/JP04/18016 | 12/3/2004 | WO | 12/7/2006 |
