CZ20004875A3 - Motion mechanism for sewing machine - Google Patents

Description

Locomotive organs for sewing machine

Technical field

BACKGROUND OF THE INVENTION The present invention relates to a sewing machine capable of effectless movement of the sliding and rotating parts.

BACKGROUND OF THE INVENTION

The driving part of an industrial sewing machine having a large number of parts, wherein the parts for sliding and rotating movement come at high speed relative to each other and are represented by shaft and contact, causing friction, under high load, is mainly a bearing. The shaft and the bearing are generally formed by a combination of metallic materials. In many cases, lubricating oil is supplied to prevent seizure or normal abrasion of metallic materials, such as friction corrosion.

When lubricating oil is supplied to the contact parts of an industrial sewing machine, it is damaged by the heat generated by friction of the contact parts. It is therefore necessary to provide means for supplying oil and forcibly supplying lubricating oil. The oil supply means comprises, for example, an oil distribution path for supplying lubricating oil to the contact portions, an oil reservoir for storing lubricating oil, and a pump for pumping lubricating oil. With such a construction, the lubricating oil can be withdrawn from the oil tank with the aid of a pump, and can be circulated and fed to each contact portion via an oil distribution path.

The abrasion caused by the sliding or rotating movement and the resistance caused by the sliding, rotating movement or the like largely depend on the PV value determined by the speed of the sliding or rotating movement and the surface pressure (loaded) exerted during the sliding or rotating movement. If the velocity is higher, or if the surface pressure is higher, the coefficient of friction increases so that the abrasion and the resistance caused increase.

For example, in a sewing machine having a structure such that the lubricating oil is fed to the contact portions, in the case of supplying a large amount of lubricating oil, the lubricating oil is dispersed towards the periphery, thereby escaping out of the sewing machine the linear movement of the needle bar at high speed, the rocker rocker movement or the needle bar crankshaft rotary movement.

Conversely, if the amount of lubricating oil supplied is reduced, there is a risk of excessive abrasion or seizure of the contact parts.

Furthermore, if the contact portions are provided with oil supply means for supplying the lubricating oil as described above, the number of sewing machine components increases and, as a result, the manufacturing cost and production costs are increased, and the production cost is increased. weight of the sewing machine. Therefore, it is required to ensure non-lubricating operation of the sewing machine interface parts.

Efforts have been made to achieve a non-lubricating operation in which the surface of the metal material forming the friction surface of the interface has been coated, for example, with a ceramic coating such as TiN or DLC, coated with a M0S2 or Teflon coating, or abrasion-resistant rubber material. or carbon fiber reinforced rubber material (CFRP).

However, there was a possibility that in long-term use, the coating formed on the surface of the metal material may have abraded or peeled off, which would have no effect. In addition, since a conventional abrasion-resistant rubber material generally has a large coefficient of thermal expansion, it can be greatly deformed by the effect of the heat generated during the translational or rotational movement. In many cases, the commonly known abrasion-resistant rubber materials generally had to be processed to obtain sufficient dimensional accuracy.

As a result, it was not possible to ensure sufficient lubrication of the friction sliding parts of the industrial sewing machine.

SUMMARY OF THE INVENTION

Accordingly, it is an object of the present invention to provide a sewing machine capable of achieving lubrication-free operation of the contact parts and providing reduced manufacturing effort and weight of the sewing machine.

The above object has been accomplished in accordance with the present invention by providing a moving device for a sewing machine in which two parts in contact with each other perform relative sliding or rotational movement, wherein at least one of the contact surfaces of the parts is formed from hard porous carbonaceous material.

At least one of the two components has a metal annular portion, the other component having a shaft-shaped portion for receiving in the annular portion, at least one of the contact surfaces being formed of a hard porous carbonaceous material.

The interface formed from the hard porous carbonaceous material has a large number of concave portions based on the pores of the hard porous carbonaceous material.

A first aspect of the present invention is directed to a sewing machine comprising interlocking contact portions causing friction upon movement of portions, such as sliding or rotary motion, wherein the interlock portion of at least one of the components is formed of a hard porous carbonaceous material .

In accordance with its structure, the hard porous carbonaceous material has a low coefficient of friction. As a result, the amount of friction caused by the tactile movement of the components can be reduced, and the generation of heat can also be reduced. Therefore, the abrasion resistance as well as the galling resistance of the contact portions can be increased. In this way, the lubrication of the sewing machine can be achieved.

In addition, it is not necessary to supply lubricating oil to the contact parts. Therefore, it is not necessary to use oil supply means, such as an oil distribution path, oil tank or oil pump, to supply lubricating oil to the sewing machine. The weight of the sewing machine can thus be reduced.

Part of the interface portion is further comprised of a hard porous carbonaceous material having a density less than that of the metallic material. As a result, the weight of the sewing machine can be further reduced.

In addition, lubricant oil supply means are not required. The number of parts of the sewing machine can thus be reduced, which also reduces the manufacturing effort of the sewing machine. In addition, production costs are also reduced.

It is also possible to provide a linear reciprocating operation in the axial direction to perform a linear reciprocating movement, a pivoting movement about the center of the shaft, and a pivoting movement together with the sliding movement.

In addition, a cylindrical shaft for performing a translational or rotational movement in the axial direction or a combination thereof may be supported in a bearing having an inner cylindrical portion for receiving the shaft, or a shaft having a selectable cross-sectional shape for performing linear translation in the longitudinal direction. mounted in a bearing having an inner cylindrical portion having a shape that corresponds to the cross-sectional shape of the shaft.

For example, if the structure according to the first aspect of the present invention is applied to a bearing (upper needle rod bearing 19A 17, lower needle rod bearing 19B) arranged in a pivot plate, a rocker slide bearing or a rod bearing, it can be conveniently achieved lubrication function.

In addition, when the structure is applied to a bearing in accordance with the first aspect of the present invention, the shaft-shaped member of hard porous carbonaceous material may be fixed to the inner surface of the outer frame member.

As a contact part, for example, a square piece is provided, arranged in the driving part of the sewing machine, which moves in frictional contact along a path arranged to guide the movement of the square piece. In this case, if the parts forming the frictional surfaces of the square piece and the respective path are made of a hard porous carbonaceous material, a non-lubricating function can very easily be achieved.

The amount of oil to be fed can be further reduced by using both a structure in which a hard porous carbonaceous material is used for the friction surfaces of the sewing machine interface parts and a structure in which the lubricating oil is fed to the contact parts.

Further, as a part formed of hard porous carbonaceous material, only the friction surface of one of the components formed of hard porous carbonaceous material may be provided, or all the surfaces constituting the friction surfaces may be formed of hard porous carbonaceous material.

In addition, many of the interface components themselves may be formed directly from a hard porous carbonaceous material.

The member formed of a hard porous carbonaceous material may further be attached to the friction surface of the metal portion as a base member. In addition, a member formed of a hard porous carbonaceous material may be attached to the outer frame member using adhesive or mechanical attachment methods such as screwing.

The hard porous carbonaceous material is further produced by a manufacturing process comprising the steps of preparing a mold using a mixed material comprising at least a cellulose-based material and a rubber, followed by firing and charring of the mold.

For example, rice ceramics formed in the process of refining paddy rice to obtain husked rice, more specifically, degreased rice bran, obtained by removing the oil content, are a suitable cellulose-based material. The degreased rice bran is impregnated with rubber and then pressed to form a mold. The mold is then dried. The dried mold is subjected to heat treatment in an inactive gas atmosphere, such as a nitrogen gas atmosphere, after which it is carbonized and fired. Rice ceramics can thus be produced.

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In this case, there is no damage to the natural environment due to waste after use. This allows excellent adaptation to the environment. In addition, the subject material (degreased rice bran) can be stably maintained in large quantities. The use of degreased rice bran can reduce the amount of wood used. This can help to reduce deforestation in the world.

In addition, various rubber materials capable of carbonization and heat treatment are used as rubber material in the manufacture of rice ceramics. In particular, thermosetting resins such as phenolic resin are preferred.

When using the hard porous carbonaceous material obtained by this manufacturing process, the mold can be obtained with the aid of a metal mold, or the mold can be easily obtained through various multi-purpose processing such as extrusion or cutting. Thus, a mold having a complicated shape can be easily prepared while reducing manufacturing costs.

Furthermore, the hard porous carbonaceous material has the property that its hardness can be adjusted depending on the firing temperature in the firing and carbonization step of the mold. Thus, the hardness necessary for the form can be obtained.

In addition, the hard porous carbonaceous material has properties such that its density can be adjusted since its porosity varies depending on the firing temperature. Thus, a density with a corresponding PV value can be obtained depending on the conditions used.

A third aspect of the invention is directed to a sewing machine movement according to the first aspect of the invention, wherein at least one of the two components is provided with a metal annular portion, while the other is provided with a shaft-shaped portion for attachment in the annular portion, the interface is made of a hard porous carbonaceous material.

According to this construction, the contact surface constituting the friction surface is formed of a hard porous carbonaceous material, the non-lubricating function being achieved in the same way as in the first aspect of the invention.

The structure with the shaft-shaped portion and the annular portion can be applied to shaft and bearing structures that represent the driving portion of the sewing machine, as shown, for example, in the illustration of Fig. 1.

Thus, the lubrication-free function of the shaft-bearing contact parts can be achieved.

In this case, it is not necessary for the members forming the outer and inner cylindrical portions to be formed from a single member, as they may be formed from a plurality of members.

In addition, a member formed of a hard porous carbonaceous material that acts as an inner cylindrical portion may have any shape, such as a cylindrical shape or a plate shape, and may be attached to a surface forming

• friction surface.

A third aspect of the present invention is directed to a movement device for a sewing machine in accordance with the first or second aspect of the present invention, wherein the contact surface formed from the hard porous carbonaceous material has a large number of concave portions based on the pores of the hard porous carbonaceous material.

In such a construction, the frictional powder, which is formed in the initial stage of abrasion, is embedded in concave portions arranged on the frictional surfaces of at least two members coming in contact with each other. Thus, contact can be achieved, causing friction, concave parts, reducing friction (self-lubricating self-lubricating operation).

According to this construction, a large number of concave pores formed in the hard porous carbonaceous material are formed on the friction surface. The concave portions may further be impregnated with a lubricant such as a grease. As a result, abrasion resistance and galling resistance can be increased.

As described above, the density (porosity) of the hard porous carbonaceous material may vary depending on the manufacturing conditions. Therefore, in such a construction, a hard porous carbonaceous material with high porosity! impregnated with a lubricant, such as a grease, the material may be impregnated with a larger amount

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lubricants. Thus, abrasion resistance as well as galling resistance can be increased.

Furthermore, the hard porous carbonaceous material is a so-called porous material. That is, a plurality of pores are also contained within the material. Consequently, if the surface of the hard porous carbonaceous material is abraded, new internal pores forming a large number of concave portions on the surface will also be exposed.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be explained in more detail by way of examples of specific embodiments thereof, the description of which will be given with reference to the accompanying drawings, in which:

Fig. 1 is an exploded perspective view showing the driving portion of the sewing machine 10 according to an exemplary embodiment of the present invention;

Fig. 2 is a side view showing the driving portion of the sewing machine 10 according to an exemplary embodiment of the present invention;

Fig. 3 is an exploded perspective view showing the driving portion of the sewing machine 20 according to an alternative exemplary embodiment of the present invention;

side elevation

the view showing FIG. 4 shows the retaining part of the upper hook forming the contact part of the sewing machine; and Fig. 5 is a cross-sectional view of the rice ceramics, the inner surface, and a view showing with the housing formed a bearing attached to its typical section of rice ceramics.

DETAILED DESCRIPTION OF THE INVENTION

A sewing machine 10 according to an exemplary embodiment of the present invention will be described with reference to the illustration of Fig. 1 and Fig. 2.

The sewing machine 10 is provided with known oil supply means, which in particular serve to supply oil to the contact parts for sliding movement and for rotating movement of the drive part. The description will therefore be given in particular to the contact portion of the drive portion of the sewing machine 10 according to an exemplary embodiment of the present invention. The same construction as the known sewing machine can also be applied to the construction of parts other than the drive part.

The friction drive portion of the sewing machine 10 according to the first exemplary embodiment of the present invention has a shaft for performing a translational or rotational movement, and a bearing for receiving the shaft. The drive portion further has an upper shaft 11 for rotating about the central axis, a front bearing 11 of the upper shaft 11 forming the upper shaft bearing 11, a crank rod 13 of the needle bar 17 for converting the rotational movement of the upper shaft 11 to

sliding movement in the vertical direction, rocker arm 16 for feeding the needle thread to the needle 1B, sliding bearing 15 of rocker arm 16 forming the bearing of the shaft 16A arranged in the rocker arm 16, needle bar 17, needle bar holder 18B arranged in the needle bar 17 , a rocking needle bar, a rocking shaft ID for carrying out a rocking plate 22 'comprising a lower bearing 19B, an upper bearing of a needle bar.

19A square piece of swivel plate

14, to be guided in the notch

12 '

19C for performing a vertical movement, and a pivot shaft bearing 1C that forms the pivot shaft bearing ID.

The component to be a bearing for receiving the shaft performing the translational movement and the rotational movement in the components, is

designed as a bearing, for example, in the illustration 100 (annular portion) of FIG. 5 (b). shown Bearing 100 has such a construction that pouzdrovitý

a member 102 (inner cylinder) formed of rice ceramic (as described above) is mounted in a cylindrical sheath member 101 (outer cylinder) formed of a metal material that acts as the outer frame of the bearing 100. In addition, the bearing 100 serves to receive a shaft (shaft-shaped component not shown) for performing translational and rotational movement through the inner surface 102A of the housing member 102.

As shown in Figure 5 (a), a plurality of concave pore-shaped portions 102B contained in the rice ceramics are formed on an inner surface 102A that is a friction surface with a shaft side surface (not shown), wherein the abrasive powder 102C formed at the initial stage of friction is

located in the concave portions 102B. When the shaft (not shown) generates friction with the inner surface 102A, the abrasive powder 102C acts as a solid lubricant so that an oil-free function is achieved.

The front bearing 11A of the upper shaft 11 comprises an inner cylindrical portion 11Aa as shown in the figures of Figures 1 and 2, wherein a housing made of rice ceramics is attached to the inner surface of the inner cylindrical portion HAa. The front bearing 11A of the upper shaft 11 forms a bearing for sliding and rotating mounting of the upper shaft 11 for rotational movement.

The counterweight 11B of the crank rod 13 is attached to one of the ends of the upper shaft 11. The counterweight 11B of the crank rod 13 is provided with a receiving opening UBa. A connecting engagement shaft 12 for engaging the counterweight 11B of the crank rod 13 with the crank rod 13 of the needle bar 17 can be mounted in the receiving bore UBa.

The intermeshing shaft 12 is provided with a notch 12A and is mounted in the receiving bore UBa of the counterweight 11B of the crank rod 13 by means of bolts HBc for the receiving bores HBb provided with screw threads arranged in the counterweight 11B of the crank rod 13. the crankshaft 13 and the connecting engagement shaft 12 rotate integrally.

The crank rod 13 of the needle bar 17 comprises an inner cylindrical portion 13A for sliding and rotating the engagement shaft 12, a receiving hole 13B for securing the shaft 15B disposed in the sliding bearing 15 of the rocker arm 16, and an inner cylindrical portion 13C for sliding and rotating the shaft 18A.

9 disposed in the needle bar holder 18. The bush, made of rice ceramics, is mounted in the inner cylindrical portions 13A and 13C, serving as a bearing for the shafts 12B and 18A to perform the sliding and rotating movements respectively.

serves as a sliding bearing arranged on the rocker arm 16.

it is attached to the needle bar 17

18A. This shaft 18A is mounted in the shaft

13C formed in the crank rod 13 is such that the end of the inner cylindrical portion 13C of the crank

The slide bearing 15 of the rocker arm 16 comprises an inner cylindrical portion 15A and a shaft 15Β to be mounted in a receiving bore 13B arranged in the crank rod 13 of the needle bar 17. A bush formed of rice ceramics is mounted in the inner cylindrical portion 15A; 16A,

Needle bar holder 18 by screwing a screw 18C into a receiving hole 18Β formed in the needle bar holder 18 and provided with a screw thread. In addition, the needle bar holder 18 comprises a shaft of the inner cylindrical portion of the needle bar 17.

The square piece 14 of the shaft 18A, inserted by the dc rod 13 of the needle bar 17, is fixed in the receiving opening 14A of the square piece 14.

In addition, the square piece 14 is guided in a notch 19C formed in the pivot plate 19, and can be moved vertically along the notch 19C. As a result, the needle bar 17 can move vertically relative to the pivot plate 19. The square piece 14 is entirely made of rice ceramics, with both the side surfaces and the back surface

The square piece 14 comes into contact with the slot 19C, causing friction and displacement along the slot 19C.

The whole of the square piece 14 is not always made of rice ceramics, since the member made of rice ceramics can be attached to both the side surfaces and to the rear face of the square piece 14, which form the friction surfaces with the notch 19C.

The pivot plate 19 comprises an upper bearing 19A of the needle bar 17 arranged at the upper end, a lower bearing 19B of the needle bar 17 arranged at the lower end, and a notch 19C for guiding the square piece 14. Besides, it is. one of the ends of the pivot shaft ID attached to the pivot plate 19, and can perform a pivot movement integrally with the pivot movement of the pivot shaft ID.

The upper needle rod bearing 19A comprises an inner cylindrical portion 19Aa and the lower needle rod bearing 19B comprises an inner cylindrical portion 19Ba, wherein the housing made of rice ceramics is mounted in the inner cylindrical portions 19Aa and 19Ba. The needle bar upper bearing 19A and the needle bar lower bearing 19B serve as bearings for the vertical and sliding fit of the needle bar 17, arranged to cooperate with the needle bar upper bearing 19A and the needle bar lower bearing 19B.

A member formed of rice ceramics may be attached to the contact portion of the notch 19C with the square piece 14.

In addition, the needle clamp 1A is arranged at the lower end of the pivot plate 19. The needle clamp 1A comprises a shaft 1AA provided with a screw thread, which may be

screwed and fastened in a receiving hole 17A provided with a screw thread which is arranged at the lower end of the needle bar 17 arranged in the pivot plate 17. The needle clamp 1A can fasten the needle 1B in the screw threaded bore 1AB with the help of screws 1AC.

The pivot shaft bearing IDC comprises an inner cylindrical portion 1CA. A housing made of rice ceramics is fixed to the inner cylindrical portion 1CA. The pivot shaft bearing IDC serves as the pivot shaft bearing ID for performing the pivot movement.

In the general manufacturing process, the hardness of the rice ceramics can be adjusted depending on the firing temperature during manufacture. Therefore, the hardness of the rice ceramic to be used in this embodiment is set to the hardness of. Vickers (HV) of approximately 40 to 150 (MPa), which can be used for sliding or rotating parts of the sewing machine.

As the porosity of the rice ceramic varies depending on the firing temperature, the density can be adjusted accordingly. For the sewing machine parts, the density is appropriately set to about 1.08 x 10 ³ to 2.0 x 10 ³ (kg / m ³ ). For example, the weight reduction is about five to eight times greater than that of copper, and about one to three times greater than that of aluminum.

Therefore, in the case of use, the rice ceramics for the above-described bearings can be reduced in weight. As a result, the surface pressure acting on the shaft and the bearing coming into contact and causing friction can be reduced,

Where the PV value can be reduced and the abrasion resistance as well as the galling resistance can be increased.

When rice ceramics is used for a contact portion having a high PV value, the interior of the pores may be impregnated with a lubricant such as a grease. In this case, the abrasion resistance as well as the galling resistance can be increased. Furthermore, by employing a structure in which rice ceramics having a high porosity, i.e. low density, are impregnated with a lubricant, the abrasion resistance as well as the galling resistance can be increased.

The rice ceramics may further have a coefficient of friction set to 0.06 to 0.18 based on the firing temperature in the manufacturing process.

In addition, the rice ceramics may have a set compressive strength of 50 to 100 MPa based on the firing temperature of the manufacturing process.

The process for manufacturing the components of the sewing machine 10 according to an exemplary embodiment of the present invention is the same as the conventional manufacturing process except that the frictional surface portion of the contact portion of each component of the driving part of the sewing machine 10 is made of rice ceramics.

More specifically, for example, a bush made of rice ceramics manufactured by the manufacturing process is attached to the parts forming the inner frictional surfaces of the inner cylindrical portions HAa, 13A, 13C, 15A, 19Aa, 19Ba and 1CA, which are bearings for the front bearing 11A of the upper shaft 11, crank rod 13 needle bar 17, plain bearing 15 ·

The rocker arm 16, the pivot plate 19 and the pivot shaft bearing ID 1C, using an adhesive or mechanical fastening method (for example, screwing).

In addition, the entire square piece 14 is formed, for example, of rice ceramics. In this case, the rice ceramic member may be affixed to the friction surface forming portion using an adhesive or mechanical fastening method such as screwing.

The sewing machine 10 may further be manufactured using any component having rice ceramics on the friction surface in the same manner as in the prior art.

In the sewing machine 10 according to the embodiment described above, the bearing-forming parts are arranged in the front bearing 11A of the upper shaft 11 and in the crank rod 13 of the needle bar 17, and the frictional surfaces which come into contact and cause friction, such as for example, a square piece 14 formed from rice ceramics having a low coefficient of friction.

In addition, a large number of concave pore-forming portions are arranged on the third surface. Therefore, the friction powder acting as a solid lubricant can be deposited here. As a result, the amount of abrasion can be reduced, and heat generation can also be reduced. Thus, the lubrication of the sewing machine 10 can be achieved.

In addition, lubricating oil is not required. There is therefore no need for oil supply means for supplying lubricating oil to the sewing machine, so the weight of the sewing machine

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can be reduced. Rice ceramics having low density are also used. As a result, the weight of the sewing machine can be further reduced.

In particular, in the embodiment of the present invention the entire pivot plate 19 is made of rice ceramics. Therefore, the PV value applied to the pivot shaft bearing 1C to which the pivot plate 19 is attached can be reduced, and the abrasion resistance of the pivot shaft bearing 1C can be increased. Furthermore, the inertial force caused by the pivoting movement of the pivoting plate 19 can be reduced. As a result, a very good stitch can be created.

In addition, no oil supply means are required. Therefore, the number of parts of the sewing machine can be reduced, whereby the manufacturing effort of the sewing machine as well as the manufacturing costs can be reduced.

As a variant, the present invention may also be applied to the drive portion of the sewing machine 20 having the structure shown in FIG. 3.

The drive part shown in FIG. 3 comprises a counterweight 21 of the crank rod 24 of the needle bar 26, a rocker arm 22, a connecting engagement shaft 23 for engaging the counterweight 21 of the crank rod 24 of the needle bar 26, the crank arm 22 and the crank rods. 24, a crank rod 24 for converting rotary motion to vertical movement, a square piece 25 attached to the crank rod 24, a needle bar 26 for accommodating the needle 29 at its lower end, a needle bar holder 27 for &quot;

4, ': if ^! engagement of the needle bar 26 with the crank rod 24,

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and a needle clamp 28 secured to the lower end of the needle bar 26.

When the drive portion of the sewing machine 20 is to be operated, the inner surface portion of the inner cylindrical portion 22A arranged in the rocker handle 22 and the side surface of the shaft 23A arranged on the engagement shaft 23, the portion of the inner cylindrical portion 24B arranged in the crank rod 24 , and a side surface of the shaft 23B disposed on the coupling engagement shaft 23, and a portion of the inner cylindrical portion 24B disposed on the crank rod 24, and a side surface of the shaft 27A disposed on the needle rod holder 26 acts as shaft and bearing contact portions they come into contact with each other and cause friction.

Accordingly, the sheath member formed from the rice ceramic is attached to the inner surfaces of the inner cylindrical portions 22A, 24A and 24B. It is thus possible to achieve the lubrication-free operation of the driving part of the sewing machine 20.

In addition, when the square piece 25 comes into contact with other parts causing friction, the rice ceramic member may be attached to the friction surface portion of the square piece 25.

As shown in FIG. 4, the present invention may further be applied to the receptacle portion 40 of the upper hook holder.

The upper hook holder housing 40 includes an upper hook drive shaft 42 for driving the upper hook, and an upper hook guide bearing 41 for sliding and rotatably mounting the upper hook drive shaft 42.

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The side surface of the upper hook drive shaft 42 for performing translation and rotational movement, and the side surface 41a of the upper hook guide bearing 41 come into contact with each other, causing friction. Therefore, the sleeve member 41A formed of rice ceramics is attached to the inner surface of the guide grip 41 of the upper hook. This allows lubrication-free operation.

In addition, the guide hook 41 of the upper hook, for example, is rotatably supported on the guide support of the upper hook (not shown). The side surface 41a of the upper hook guide bearing 41 and the upper hook guide support (not shown) act as parts which come into contact with each other, causing friction. Therefore, a member made of rice ceramics and having a shape adapted to the outer circumferential surface of the guide grip 41 of the upper hook can be fastened there.

The entire guide bearing 41 of the upper hook can be made of rice ceramics, since the inner surface 41Aa and the side surface 41a act as friction surfaces.

As shown in Figure 5 (b), for example, the portion (bearing 100) of the contact portion is of such a construction that the member (cylindrical casing member 101) forming the outer frame can be formed using a material other than a hard porous material. the carbonaceous material, the member (sleeve member 102) formed of a hard porous carbonaceous material may be attached to the frictional surface portion of the outer frame member.

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In this case, a metal material is used for a material that is different from the hard porous carbonaceous material, for example, mechanical strength and durability can be imparted to the parts that come into contact with each other, causing friction.

It will be appreciated that the hard porous carbonaceous material may also be used for parts of the sewing machine other than those described in the above embodiment.

Industrial applicability

In accordance with a first aspect of the present invention, the frictional surface portion is formed of a hard porous carbonaceous material having a low coefficient of friction. Thus, lubrication-free operation touching the parts of the sewing machine can be achieved.

In addition, oil supply means, such as lubricating oil, do not need to be used for the contact portions. As a result, weight reduction can be achieved. Further, the hard porous carbonaceous material has, for example, a lower density than the metal material. Therefore, the weight can be further reduced.

In addition, no oil supply means are required. As a result, the number of parts of the sewing machine can be reduced, as a result of which the manufacturing effort of the sewing machine as well as the corresponding manufacturing costs can be reduced.

In accordance with a second aspect of the present invention, the shaft-shaped portion then performs rotational movement in a circumferential manner

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and.

9 směru% · * · <···· direction along the inner surface of the annular portion, or a translational movement in axial direction along the inner and the friction surface is formed of a hard porous carbonaceous material. Therefore, it is possible to achieve the lubrication-free operation of the shaft and the bearings that represent the driving portion of the sewing machine in the same manner as in the first aspect of the present invention.

In accordance with a third aspect of the present invention, the friction powder formed at the initial stage of wear is deposited in concave portions formed on the friction surface. This friction powder has self-lubricating properties, thus reducing the coefficient of friction during contact which causes friction. In this way, lubrication-free operation can be achieved.

Claims (3)

PATENT CLAIMS Movement apparatus for a sewing machine in which two Components coming to mutual intercourse, performed relative sliding movement or rotating motion F confesses c E that at least one of contact surfaces included Yippee created from hard porous carbonaceous material. A sewing machine locator according to claim 1, characterized in that at least one of the two components has a metal annular portion, the other component having a shaft-shaped portion for receiving in the annular portion, wherein at least one of the contact surfaces is made of hard porous carbonaceous material. Sewing machine locator according to claim 1 or 2, characterized in that the contact surface formed from the hard porous carbonaceous material has a large number of concave parts based on the pores of the hard porous carbonaceous material. > <• i »» • ·· 9 ·· • · •> • • · • · · · · E • · • · • • • ·· ' • ·· * '