The present invention relates to a hallux valgus orthosis, i.e. a bunion correction device.
Hallux valgus is a disease caused by anatomical factors (varus of hallux metatarsal bone, flat feet, and the like) and external factors (shoes, life style, and the like).
A case in which the angle of hallux valgus (R) shown in
Hallux valgus occurs mostly in women, and the patient gender ratio is believed to be one male to ten females. Furthermore, even if a patient recovers from the condition for the moment, when the patient restores the original lifestyle habit, the illness recurs.
Regarding currently available devices for correcting hallux valgus, there are arch or plantar supports (insoles) that are inserted in the sole at the time of walking in the daytime, and nighttime devices for correction that are worn at the time of sleeping. Examples of the nighttime devices include the following.
A schematic perspective view of the state of use of the nighttime device described in Patent Literature 1 is illustrated in
This nighttime device has a hinge (32) provided under the base of the big toe of a springy splint (31) extending across from the big toe to the inner side of the metatarsus. Furthermore, the nighttime device is a device that enables walking, in which the springy splint binds the big toe with a first annular fastening device (34) formed from a flexible and pliable material that does not easily stretch, for example, a fabric tape or a non-stretchable adhesive tape, and the springy splint binds the big toe and the metatarsus in the circumferential direction with a second annular fastening device (33) formed from a flexible and pliable material that does not easily stretch, for example, a fabric tape or a non-stretchable adhesive tape.
The shape of the springy splint (31) is a three-dimensional shape conforming to the shape of the foot. The material of the springy splint (31) is a metal or a plastic, and it is considered preferable to use a thin carbon fiber-reinforced sheet. A representative example is a springy splint made of a plastic.
A schematic perspective view of the state of use of the nighttime device described in Patent Literature 2 is illustrated in
This nighttime device is a device that uses a shape memory alloy for the splint (a correction sheet 21). Since the pliability of superelasticity is used, a corrective effect can be expected as long as the device can be worn for a long time. In the diagram, reference numeral 22 represents a space provided in a correction sheet (21); reference numeral 23 represents an annular fastening device for the metatarsal bone; reference numeral 24 represents an annular fastening device for the big toe; and reference numerals 25 and 25 are hook-and-loop fasteners.
Patent Literature 1: Japanese Patent No. 4917752
Patent Literature 2: Japanese Patent No. 5369321
Since the nighttime device of Patent Literature 1 provides a dramatic improvement in the walking performance, the device is made wearable also in times other than the nighttime. However, while it is said that the springy splint has springiness, since the springy splint (31) has a three-dimensionally shaped hinge (32), the periphery of the hinge area is rigid. Since the springy splint has a structure in which as a portion is farther away from the hinge part, the portion gradually becomes to have spring property, no load can be applied to the entire inner foot side. As such, when only the vicinity of the annular fastening device (34) is bent, a satisfactory corrective effect cannot be obtained.
Furthermore, since the materials for the annular fastening devices (33 and 34) are configured to include a fabric tape or a non-stretchable adhesive tape, when the annular fastening devices come into direct contact with the skin, the patient may have a feeling of strangeness (discomfort). Therefore, it is difficult to wear the device for a long time (for example, overnight wearing).
The nighttime device of Patent Literature 2 applies a correction sheet (21) along the direction of bending or stretching of the big toe, and therefore, movement of the big toe is restricted. Thus, wearing of the device for a long time is difficult.
Furthermore, since the materials for the annular fastening devices (23 and 24) are representatively configured to include a supporter, when the annular fastening devices come into direct contact with the skin, the patient may have a feeling of strangeness (discomfort). Therefore, it is difficult to wear the device for a long time (for example, overnight wearing).
As such, regarding the conventional hallux valgus correction devices intended mainly for nighttime wearing, it has been difficult for users to wear the devices for a long time, because the users feel painful or have an unpleasant feeling of wearing. Furthermore, for example, the joining of a metal (shape memory alloy) part and a supporter may be dislocated because the joining force is weak, or the fixing of the big toe may be dislocated because the fixing force is weak. Even in the case of walking to the bathroom at night, the device may be dislocated, and in some severe cases, the device is broken. Furthermore, since the supporter gets sweaty, the supporter gives a feeling of strangeness to the skin, and the duration of wearing is limited to 2 to 3 hours. Thus, wearing the device overnight has been torments for patients. For example, one of the causative factors for sleep disorders may be restless legs syndrome. The restless legs syndrome is caused by discomfort or pain in the legs, and discomfort or pain in the legs has been mentioned as a causative factor for sleep disorders. The discomfort caused by wearing of a hallux valgus correction device is quite different from the cause of onset. However, since discomfort or pain in the legs significantly affects sleep, it is important for a nighttime device to reduce the pain and a feeling of strangeness at the time of wearing.
Thus, the present invention is contemplated for providing a hallux valgus correction device that maximally reduces a feeling of strangeness (discomfort) to the patient at the time of wearing, suppresses pain by utilizing the characteristics of a superelastic alloy while a high corrective effect can be expected therefrom, and can be worn for a long time or for a long time period.
The inventors of the present invention have conducted a thorough investigation in order to solve the problems described above, and as a result, the inventors have found that a hallux valgus correction device that maximally reduces a feeling of strangeness (discomfort) at the time of wearing, suppresses pain by utilizing the characteristics of a superelastic alloy while a high corrective effect can be expected, and can be worn for a long time or for a long time period, is obtained by providing a hinge part at the base of the big toe of a sheet made of a superelastic alloy and making the hinge part movable.
That is, the present invention is to provide the following means:
(1) A hallux valgus correction device for correcting hallux valgus,
the hallux valgus correction device including:
a corrector made of a superelastic alloy; and
a fixture formed from a fabric to attach the corrector,
in which the corrector has a hinge part that is rotationally movable in the bending direction and the stretching direction of one toe or a plurality of toes in need of correction.
(2) The hallux valgus correction device according to item (1), in which the corrector made of the superelastic alloy is formed from a Cu—Al—Mn-based superelastic alloy.
(3) The hallux valgus correction device according to item (1) or (2), in which the fixture has a first annular bandage enclosing the big toe; a second annular bandage enclosing the metatarsus; and a corrector storage unit that extends over the first annular bandage and the second annular bandage and accommodates the corrector in the inside.
(4) The hallux valgus correction device according to any one of items (1) to (3), wherein in the fabric, a portion that comes into direct contact with the skin is formed from an extra-fine denier resin fiber.
(5) The hallux valgus correction device according to any one of items (1) to (4), in which the fixture includes a cushioning member between the hinge part and the big toe joint.
(6) The hallux valgus correction device according to any one of items (1) to (5), in which the corrector is comprised of a Cu—Al—Mn-based superelastic alloy having a composition containing 3.0 to 10.0 mass % of Al, and 5.0 to 20.0 mass % of Mn, with the balance being Cu and unavoidable impurities, and capable of containing, as an optional additional element, 0.000 to 10.000 mass % in total of at least one selected from the group consisting of Ni, Co, Fe, Ti, V, Cr, Si, Nb, Mo, W, Sn, Mg, P, Be, Sb, Cd, As, Zr, Zn, B, C, Ag, and misch metal (Pr, Nd, and the like).
According to the hallux valgus correction device of the present invention, by providing a hinge part at the base of the big toe of a superelastic alloy sheet and making the hinge part movable, the hallux valgus correction device can be provided, which maximally reduces a feeling of strangeness (discomfort) of the patient at the time of wearing, which suppresses pain while a high corrective effect can be expected, and which can be worn for a long time or for a long time period.
Other and further features and advantages of the invention will appear more fully from the following description, appropriately referring to the accompanying drawings.
The hallux valgus correction device of the present invention will be explained using the drawings. As illustrated in
The corrector (10) is accommodated (stored) in a corrector storage bag (6). Furthermore, the corrector (10) has a hinge part (11) that can rotationally move in the bending direction and stretching direction of the toe that is in need of correction (that is, big toe). It is enough that the hinge part (11) is provided at least in an area in the vicinity of the big toe base, and the hinge part may be further provided in another joint area of the big toe.
By adopting such a configuration, the hallux valgus correction device of an embodiment according to the present invention can exert force (P) on the entirety of the corrector (from the big toe to the metatarsus), with the big toe joint serving as a fulcrum. As a result, there is no force that is partially exerted on the big toe, and therefore, the correction device can be worn for a long time or a for a long time period without causing any feeling of strangeness (discomfort), and the correction device can correct hallux valgus effectively.
When using an integrated material (for example, one sheet of the sheet) of a superelastic alloy that does not have any hinge, a certain force can be applied to the entire inner side of the foot by superelasticity, and correction can be achieved without causing a pain. However, since the toe of the foot cannot be bent, walking is made impossible, and also, the discomfort caused by unintentional moving of toes to cause dislocation of the device in sleeping as well as dislocation of the device is much more severe than one can imagine.
In this regard, according to the present invention, when the superelastic alloy sheet (the corrector 10) and a hinge (11) are combined, to make the hinge (11) movable and rotationally movable, two superelastic alloy sheets (10 and 10) can conform to the angle of bending of the toe by means of the hinge (11). Thereby, the burden on the patient is reduced, and the correction device can be worn for a long time or for a long time period. Thus, the corrective effect of superelasticity can be exhibited to a high level.
In regard to the hallux valgus correction device of the present invention, although not illustrated in the diagram, it is desirable that the hinge (11) joins two superelastic alloy sheets (10 and 10) in a state that the two superelastic alloy sheets do not move vertically or horizontally, but each of them can freely move rotationally. Meanwhile, one of the two superelastic alloy sheets (10 and 10) has a length approximately equal to that of the big toe, and the other one has a length approximately equal to that of the long bone.
In other words, according to the present invention, even though the corrector (10) made of a superelastic alloy has a hinge (11), since the entirety of the corrector has a predetermined elastic force, the corrector can exert a corrective force (P) on the big toe. This is also the same even if the hinge part is in a bent state. It is the technical significance that a certain corrective force (P) can be exerted on the range from the big toe to the metatarsus without causing a feeling of strangeness (discomfort) (even both at the time of walking and in the nighttime).
Here, “sheets made of a superelastic alloy” must be used because an elastic force should be exhibited (force P described in the following paragraph 0017) and deformation should be prevented.
As illustrated in
In regard to hallux valgus correction devices, disadvantages of existing products can be roughly divided into two (the pain in the big toe is also a kind of feeling of strangeness; however, this will be also divided into two).
A superelastic alloy is such that when the amount of deformation is beyond a certain level, the load becomes constant, and a superelastic alloy has a lower rigidity, with the Young's modulus being ⅓ of that of iron. Therefore, the superelastic sheets (corrector 10) do not forcibly bend the big toe but fit themselves so as to stick to the big toe as a whole, and a constant moderate force (P) is applied to the big toe as a whole. Therefore, the superelastic sheets allow the user to feel pain to a significantly reduced degree (see
On the other hand, at bedtime, toes are unintentionally bent, or toes are bent upon walking to go to the bathroom. However, if the toes cannot be bent, this causes the feeling of strangeness (discomfort) that is much severe than one can imagine.
The hallux valgus correction device of the present invention makes the MTP joint (see
Regarding the hallux valgus correction device of the present invention, monitors gave the following mentions on the use of a corrector (10) made of a superelastic alloy and having a hinge part (11) as illustrated in
(1) The hallux valgus correction device has corrective force, while the feeling of wearing is natural.
(2) The band on the dorsum of the foot has a good feeling of fixation or insertion.
(3) Since the corrector made of a superelastic alloy is movable, walking while wearing the device is made easy.
(4) Compared to conventional devices, there is no feeling of strangeness at the time of wearing.
Furthermore, orthopedists gave the following mentions (opinions).
(5) Since the user can have a sound sleep, the correction device is an unprecedented, true nighttime device that can be worn in the nighttime.
(6) Walking is enabled, and thus, the device can be worn in the daytime, too.
(7) The correction device can be worn in the nighttime and in the daytime, the device can be worn for a long time, and a therapeutic effect can be expected.
The hinge (11) can be installed such that one corrector (10) can move around 360° (that is, rotate) with respect to the other corrector (10). At the time of wearing, it is desirable that the hinge actually moves around up to about 90° , that is, up to the angle at which the toe can be bent.
Here, the hinge (11) means an object in which two superelastic alloy sheets (10 and 10) are riveted at the center of rotation, as illustrated in the drawings.
According to the hallux valgus correction device of the present invention, the following can be expected in connection with the therapeutic effect described above. That is, pain can be reduced by inducing contracture of the MTP joint (see
Furthermore, in the hallux valgus correction device of the present invention, since a fabric of an extra-fine denier resin fiber as illustrated in
(1) Since the amount of moisture evaporation is small and the stratum corneum is not damaged, the fabric feels good to the touch, and there is no feeling of strangeness (discomfort).
(2) Since the surface area is made large by the extra-fine denier fibers, the fabric is water-absorbent. The fabric absorbs sweat and does not get sweaty.
(3) Even if the user does exercise, the temperature is not likely to rise. Therefore, even if the correction device is worn in sleep, the fabric does not get sweaty.
(4) Since the fabric has high friction resistance, the correction device does not easily slip away and is not likely to be dislocated.
Meanwhile, the fabric to be used for the hallux valgus correction device of the present invention is not limited to the above-described extra-fine denier polyester fiber. Any fabric having an equivalent effect can be used without being limited to the extra-fine denier polyester fiber.
In regard to the hallux valgus correction device of the present invention, it is preferable that the portion that comes into direct contact with the skin in the fabric is formed from an extra-fine denier polyester fiber. Here, examples of the portion that comes into direct contact with the skin include: the inner side portion of the fixture (3) (annular bandage for the metatarsal bone); and the inner side portion of the fixture (4) (annular bandage for the big toe).
Furthermore, there are no particular limitations on the materials for the fixture (3) (metatarsal bone fastening belt), the big-toe-base inner-side protrusion cushioning pad (5), and the corrector storage bag (6). In the embodiment that will be described below, these are made of synthetic rubber (for example, made of NEOPRENE). However, it is also acceptable that the entirety of the fixture including these is formed from an extra-fine denier polyester fiber.
NANOFRONT is the trade name for an extra-fine denier polyester fiber manufactured by TEIJIN LIMITED, with one strand of the fiber having a diameter of about 700 nm.
Preferably, the hallux valgus correction device of the present invention has: a fastening band (2) that is retained by a first annular bandage (4) at the big toe part and a second annular bandage (3) at the metatarsal part, and fastens the metatarsal part to the outer side of the second annular bandage at the metatarsal part. It is also preferable that the hallux valgus correction device of the present invention has a cushioning pad (cushioning member) (5) on the big toe joint inner side, and the base of the foot and the big toe are retained by these fixtures (first and second annular bandages) (3 and 4). It is also preferable that the hallux valgus correction device has a corrector (10) of sheets made of superelastic alloy, which is accommodated inside the corrector storage bag (6) and extends along the inner side of the foot.
By adopting such a configuration, the contact area between the hallux valgus correction device and the foot can be reduced, and the feeling of strangeness of the device can be reduced.
Furthermore, by providing a cushioning member (5) between the hinge part (11) and the big toe joint, the feeling of strangeness of the hallux valgus correction device can be further reduced. Furthermore, by providing a cushioning member (5) and thereby providing a space between the big toe joint and the corrector (10), the elastic force (P) of the corrector (10) can be exerted more efficiently on the big toe.
The hallux valgus correction device of the present invention illustrated in
Preferably, the hallux valgus correction device of the present invention may be configured to include a fixture having the first annular bandage (4), the second annular bandage (3), the fastening band (2), and the cushioning pads (5) sewed in, for example, the corrector storage bag (6) as an integrated body.
In regard to the hallux valgus correction device of the present invention, the kind of the superelastic alloy that constitutes the corrector (10) and, if necessary, the hinge part (11), is not particularly limited. For example, use can be made of any of various superelastic alloys, such as a Ni—Ti-based alloy and a Cu—Al—Mn-based alloy. Among these, it is preferable to use a Cu—Al—Mn-based alloy as the superelastic alloy. A preferred composition thereof and the like will be described below.
The copper-based alloy to be used in the present invention having shape memory characteristics and superelasticity is an alloy containing Al and Mn. This alloy becomes a β phase (body-centered cubic) single phase (in the present specification, which may be simply referred to as β single phase) at high temperature, and becomes a two-phase microstructures of a β phase and an α phase (face-centered cubic) (in the present specification, which may be simply referred to as (α+β) phase) at low temperature. The temperatures ranges may vary depending on the alloy composition, but the high temperature at which the β single phase is obtained is usually 700° C. or higher, and the low temperature at which the (α+β) phase is obtained is usually less than 700° C.
The Cu—Al—Mn-based alloy to be used in the present invention has a composition containing 3.0 to 10.0 mass % of Al and 5.0 to 20.0 mass % of Mn, with the balance being Cu and unavoidable impurities. If the content of elemental Al is too small, the β single phase cannot be formed, and if the content is too large, the alloy becomes brittle. The content of elemental Al may vary depending onto the content of elemental Mn, but a preferred content of elemental Al is 6.0 to 10.0 mass %. When the alloy contains elemental Mn, the range of existence of the β phase extends to a lower Al-content side, and cold-workability is markedly enhanced. Thus, forming work is made easier. If the amount of addition of elemental Mn is too small, satisfactory workability is not obtained, and the region of the β single phase cannot be formed. Also, if the amount of addition of elemental Mn is too large, sufficient shape recovery characteristics are not obtained. A preferred content of Mn is 8.0 to 12.0 mass %.
In addition to the essential alloying elements described above, the Cu—Al—Mn-based alloy to be used in the present invention can further contain, optional additionally alloying element(s), at least one selected from the group consisting of Ni, Co, Fe, Ti, V, Cr, Si, Nb, Mo, W, Sn, Mg, P, Be, Sb, Cd, As, Zr, Zn, B, C, Ag and misch metal (for example, Pr and Nd). These elements exhibit an effect of enhancing the physical strength of the Cu—Al—Mn-based alloy, while maintaining cold-workability. The content in total of any of these optional additionally elements is preferably 0.001 to 10.000 mass %, and particularly preferably 0.001 to 5.000 mass %. If the content of any of these optional additionally elements is too large, the martensite transformation temperature is lowered, and the β single phase microstructure becomes unstable.
Ni, Co, Fe and Sn are elements that are effective for strengthening of the matrix microstructure. Co makes the grains coarse by forming Co—Al intermetallic compound, but Co in an excess amount causes lowering of toughness of the resultant alloy. A content of Co is 0.001 to 2.000 mass %. A content of Ni and Fe is respectively 0.001 to 3.000 mass %. A content of Sn is 0.001 to 1.000 mass %.
Ti is bonded to N and O, which are inhibitory elements, to form oxynitride. Also, Ti forms boride when added in combination with B, to enhance physical strength. A content of Ti is 0.001 to 2.000 mass %.
V, Nb, Mo and Zr have an effect of enhancing hardness, to enhance abrasion resistance. Further, since any of these elements are hardly solid-solubilized into the matrix, the elements precipitate as a β phase (bcc crystals), to enhance physical strength. Contents of V, Nb, Mo and Zr are respectively 0.001 to 1.000 mass %.
Cr is an element effective for retaining abrasion resistance and corrosion resistance. A content of Cr is 0.001 to 2.000 mass %. Si has an effect of enhancing corrosion resistance. A content of Si is 0.001 to 2.000 mass %. W is hardly solid-solubilized into the matrix, and thus has an effect of precipitation strengthening. A content of W is 0.001 to 1.000 mass %.
Mg has an effect of eliminating N and O, which are inhibitory elements, fixes S that is an inhibitory element as sulfide, and has an effect of enhancing hot-workability or toughness. Addition of a large amount of Mg brings about grain boundary segregation, and causes embrittlement. A content of Mg is 0.001 to 0.500 mass %.
P acts as a de-acidifying agent, and has an effect of enhancing toughness. A content of P is 0.01 to 0.50 mass %. Be, Sb, Cd, and As have an effect of strengthening the matrix microstructure. Contents of Be, Sb, Cd, and As are respectively 0.001 to 1.000 mass %.
Zn has an effect of raising the shape memory treatment temperature. A content of Zn is 0.001 to 5.000 mass %. When appropriate amounts of B and C are used, a pinning effect is obtained, and thereby an effect of coarsening the grains is obtained. Particularly, combined addition of B and C together with Ti and Zr is preferred. Contents of B and C are respectively 0.001 to 0.500 mass %.
Ag has an effect of enhancing cold-workability. A content of Ag is 0.001 to 2.000 mass %. When an appropriate amount of misch metal is used, a pinning effect is obtained, and thereby an effect of coarsening the grains is obtained. A content of misch metal is 0.001 to 5.000 mass %. Misch metal refers to an alloy of rare earth elements, such as La, Ce, and Nd, for which separation into simple substances is difficult.
In regard to the Cu—Al—Mn-based alloy to be used in the present invention, regarding the production conditions for obtaining a superelastic alloy which stably provides satisfactory superelastic characteristics and has excellent resistance to repeated deformations, a production process such as described below may be mentioned.
The production process of the Cu—Al—Mn-based alloy is mainly composed of, as illustrated in
In the entire production process, particularly, when the heat treatment temperature [3] for intermediate annealing [Step 3] is set to the range of 400° C. to 680° C., and the cold-working ratio or the working ratio for cold wire-drawing [5] for the cold-work (specifically, cold-rolling or cold-wire-drawing) [Step 4-1] is set to the range of 30% or more, a Cu—Al—Mn-based alloy which stably provide satisfactory superelastic characteristics is obtained. In addition to those, in the shape memory heat treatment [Step 5-1] to [Step 5-10], the speeds of temperature raising [10] and [16] in heatings [Step 5-3] and [Step 5-7] from the temperature ranges [8] and [14] for obtaining the (α-β) phase (which may vary depending on the alloy composition, but generally 400° C. to 650° C., and preferably 450° C. to 550° C.) to the temperature ranges [11] and [17 ] for obtaining the β single phase (which may vary depending on the alloy composition, but generally 700° C. or higher, preferably 750° C. or higher, and more preferably 900° C. to 950° C.), are each controlled to a predetermined slow range, such as 0.1° C./min to 20° C./min. In addition, the speed of temperature lowering [13] in cooling [Step 5-5] from the temperature range [11] for obtaining the β single phase to the temperature range [14] for obtaining the (α+β) phase, is controlled to a predetermined slow range, such as 0.1° C./min to 20° C./min. Further, after the heating [Step 5-3] from the temperature range [8] for obtaining the (α+β) phase to the temperature range [11] for obtaining the β single phase, a series of steps including: from retention [Step 5-4] in a temperature range [11] for obtaining the β single phase for a predetermined time [12]; cooling [Step 5-5] from the temperature range [11] for obtaining the β single phase to the temperature range [14] for obtaining the (α+β) phase at a speed of temperature lowering [13] of 0.1° C./min to 20° C./min; retention [Step 5-6] in the temperature range [14] for a predetermined time [15]; heating [Step 5-7] from the temperature range [14] for obtaining the (α+β) phase to the temperature range [17] for obtaining the β single phase at a speed of temperature raising [16] of 0.1° C./min to 20° C./min; to retention [Step 5-8] in the temperature range [17] for a predetermined time [18], that is, a series including from [Step 5-4] to [Step 5-8], is repeated at least one time and preferably at least four times (Step [5-9]). Thereafter, rapid cooling [Step 5-10] is carried out lastly.
Preferably, a production process such as follows may be mentioned.
In a usual manner, after melting and casting [Step 1] and hot-working [Step 2] of hot-rolling or hot-forging is carried out, intermediate annealing [Step 3] at 400° C. to 680° C. [3] for 1 to 120 minutes [4], and then cold-working [Step 4-1] of cold-rolling or cold-wire-drawing at a working ratio of 30% or higher [5] are carried out. Herein, the intermediate annealing [Step 3] and the cold-working [Step 4-1] may be carried out once each in this order, or may be repeated [Step 4-2] in this order at a number of repetitions [6] of two or more times. Thereafter, the shape memory heat treatment [Step 5-1] to [Step 5-10] is carried out.
The shape memory heat treatment [Step 5-1] to [Step 5-10] includes: heating [Step 5-3] from a temperature range [8] for obtaining an (α+β) phase (for example, 450° C.) to a temperature range [11] for obtaining a β single phase (for example, 900° C.) at a speed of temperature raising [10] of 0.1° C./min to 20° C./min, preferably 0.1° C./min to 10° C./min, and more preferably 0.1° C./min to 3.3° C./min (hereinafter, referred to a slow temperature raising); retention [Step 5-4] at that heating temperature [11] for 5 minutes to 480 minutes, and preferably 10 to 360 minutes [12]; cooling [Step 5-5] from a temperature range [11] for obtaining a β single phase (for example, 900° C.) to a temperature range [14] for obtaining an (a+β) phase (for example, 450° C.) [14] at a speed of temperature lowering [13] of 0.1° C./min to 20° C./min, preferably 0.1° C./min to 10° C./min, and more preferably 0.1° C./min to 3.3° C./min (hereinafter, referred to a slow temperature lowering); and retention [Step 5-6] at that temperature [14] for 20 to 480 minutes, and preferably 30 to 360 minutes [15]. Thereafter, the resultant alloy is subjected to: the heating [Step 5-7] again from a temperature range [14] for obtaining an (α+β) phase (for example, 450° C.) to a temperature range [17] for obtaining a β single phase (for example, 900° C.) at the speed of temperature raising [16] of the slow temperature raising; and retention [Step 5-8] at that temperature [17] for 5 to 480 minutes, and preferably 10 to 360 minutes [18]. Repetition [Step 5-9] of such slow temperature lowering [13] [Step 5-5] and slow temperature raising [16] [Step 5-7] is carried out at the number of the repetitions [19] of at least one time and preferably at least four times. Then, the shape memory heat treatment includes: rapid cooling [Step 5-10], for example, water cooling.
The temperature range for obtaining an (α+β) single phase and the temperature range to be determined in the present invention is set to 400° C. to 650° C., and preferably 450° C. to 550° C.
The temperature range for obtaining a β single phase is set to 700° C. or higher, preferably 750° C. or higher, and more preferably 900° C. to 950° C.
After the shape memory heat treatment [Step 5-1] to [Step 5-10], it is preferable to perform aging heat treatment [Step 6] at 100° C. to 200° C. [21] for 5 to 120 minutes [22]. If the aging temperature [21] is too low, the β phase is unstable, and if the resultant alloy is left to stand at room temperature, the martensite transformation temperature may change. On the contrary, if the aging temperature [21] is slightly higher, bainite (a microstructure) or it is too high, precipitation of the a phase occurs. In particular, the shape memory characteristics or superelasticity tends to be worsened conspicuously, due to the occurrence of precipitation of a phase.
By repeatedly performing [Step 4-2] intermediate annealing [Step 3] and cold-working [Step 4-1], the crystalline orientation can be integrated more preferably. The number of repetitions [6] of intermediate annealing [Step 3] and cold-working [Step 4-1] may be one time, but is preferably two or more times, and more preferably three or more times. This is because, as the number of repetitions [6] of the intermediate annealing [Step 3] and the cold-working [Step 4-1] is larger, the characteristics can be enhanced.
The intermediate annealing [Step 3] is carried out at 400° C. 680° C. [3] for 1 minute to 120 minutes [4]. It is preferable that this intermediate annealing temperature [3] is set to a lower temperature, and preferably to 400° C. to 550° C.
The cold-working [Step 4-1] is carried out at a working ratio [5] of 30% or higher. Herein, the working ratio is a value defined by formula:
Working ratio (%)={(A1−A2)/A1}×100
wherein A1 represents the cross-sectional area of a specimen obtained before cold-working (cold-rolling or cold-wire-drawing); and A2 represents the cross-sectional area of the specimen obtained after cold-working.
The cumulative working ratio ([6]) in the case of repeatedly performing this intermediate annealing [Step 3] and cold-working [Step 4-1] two or more times is preferably set to 30% or higher, and more preferably 45% or higher. There are no particular limitations on the upper limit of the cumulative working ratio, but the cumulative working ratio is usually 95% or lower.
In regard to the shape memory heat treatment [Step 5-1] to [Step 5-10], first, in [Step 5-1], temperature raising is carried out after the cold-working, from room temperature to a temperature range [8] for obtaining an (α+β) phase (for example, 450° C.) at the speed of temperature raising [7] (for example, 30° C./min). Then, retention [Step 5-2] is performed in the temperature range [8] for obtaining the (α+β) phase (for example, 450° C.) for 2 to 120 minutes, and preferably 10 to 120 minutes [9]. Then, when heating [Step 5-3] is performed from the temperature range [8] for obtaining the (α+β) phase (for example, 450° C.) to the temperature range [11] for obtaining the β single phase (for example, 900° C.), the speed of temperature raising [10] is set to 0.1° C./min to 20° C./min, preferably 0.1° C./min to 10° C./min, and more preferably 0.1° C./min to 3.3° C./min, of the slow temperature raising. Then, the alloy is retained [Step 5-4] in this temperature range [11] for 5 to 480 minutes, and preferably 10 to 360 minutes [12]. Then, cooling [Step 5-5] is performed from the temperature range [11] for obtaining the β single phase (for example, 900° C.) to the temperature range [14] for obtaining the (α+β) phase (for example, 450° C.) at the speed of temperature lowering [13] of 0.1° C./min to 20° C./min, preferably 0.1° C./min to 10° C./min, and more preferably 0.1° C./min to 3.3° C./min, and the alloy is retained [Step 5-6] in this temperature range [14] for 20 to 480 minutes, and preferably 30 to 360 minutes [15]. Then, heating [Step 5-7] is performed again from the temperature range [14] for obtaining the (α+β) phase (for example, 450° C.) to the temperature range [17] for obtaining the β single phase (for example, 900° C.) at the speed of temperature raising [16] of the slow temperature raising, and the alloy is retained [Step 5-8] in this temperature range [17] for 5 to 480 minutes, and preferably 10 to 360 minutes [18]. Repetition [Step 5-9] of such a [Step 5-4] to [Step 5-8] (conditions [11] to [18]) is carried out at least one time and preferably at least four times [19].
The cooling speed [20] at the time of rapid cooling [Step 5-10] is usually set to 30° C./sec or more, preferably 100° C./sec or more, and more preferably 1,000° C./sec or more.
The final optional aging heat treatment [Step 6] is usually carried out at 100° C. to 200° C. [21] for 5 to 120 minutes [22], and preferably at 120° C. to 200° C. [21] for 5 to 120 minutes [22].
Furthermore, the hallux valgus correction device of the present invention also enables the correction to be achieved comfortably and steadily in a stepwise manner using a sheet having a small thickness (weak load) in the early stage, a sheet having a slightly large thickness (moderate load) in the intermediate stage, and a sheet with a large thickness (heavy load) in the final stage, by accommodating superelastic sheets (corrector, 10) in an insertable and removable storage bag (corrector storage unit) (6).
Moreover, when the hallux valgus correction device of the present invention is used, since the correction device can be worn for a long time or for a long time period, the correction device is also applicable to conservative therapy.
The present invention will be described in more detail based on examples given below, but the invention is not meant to be limited by these.
As an Example, the hallux valgus correction device of the present invention illustrated in
The corrector (sheets made of a superelastic alloy) 10 of the hallux valgus correction device of the present invention was produced by the following method. A mixed material of 8.1 mass % of Al and 11.1 mass % of Mn, with the balance being Cu, was melted and cast in a high-frequency vacuum melting furnace, and the resultant material was subjected to hot-forging at 800° C. and hot-rolling at 600° C., followed by repeatedly subjected to intermediate annealing at 520° C. and cold-rolling at a cold-working ratio of 40%. Thus, a sheet having a sheet thickness of 0.4 mm was produced. The sheet was punched into a predetermined shape, and the resultant punched sheet was heated to 500° C. at a speed of temperature raising of 10° C./min in an electric furnace, maintained at 500° C. for one hour, heated to 900° C. at a speed of temperature raising of 1.0° C./min, and maintained for 10 minutes at 900° C. Then, the sheet was cooled to 500° C. at a speed of temperature lowering of 1.0° C./min, maintained at 500° C. for one hour, then heated to 900° C. at a speed of temperature raising of 1.0° C./min, maintained for one hour, and then rapidly cooled in water. Then, the resultant sheet was subjected to aging treatment at 130° C. for a heat treatment time of 30 minutes, and thus, superelasticity was exhibited. In this manner, a corrector (sheets made of a superelastic alloy) was obtained.
Regarding the fastening band 2, use was made of: a belt manufactured by MJ NEOPRENE CO., LTD, in which to one end of a fabric rubber having one surface covered with the loops of a hook-and-loop fastener, a metallic fitting for passing the hooks of the hook-and-loop fastener is attached, and the loops of the hook-and-loop fastener are attached to the other end.
Regarding the second annular bandage 3, use was made of: a tape-like fabric rubber having a width of 50 mm to 100 mm and having one surface covered with a fabric of an extra-fine denier polyester fiber (manufactured by TEIJIN LIMITED, NANOFRONT (trade name)), and the metatarsal circumference diameter of each of the monitors was measured. The fabric rubber was sewed together such that the length was shorter by about 5% than the circumference diameter in the direction in which the fabric rubber would stretch in the metatarsal circumferential direction. At the time of sewing together, the loops of the hook-and-loop fastener for attaching the annular bandage and the corrector storage bag were kept in a sewed state. The tape width was adjusted as appropriate in accordance with the size of the monitor's metatarsus.
Regarding the first annular bandage 4, use was made of: a tape-like fabric rubber having a width of 20 mm to 40 mm and having one surface covered with a fabric of an extra-fine denier polyester fiber (manufactured by TEIJIN LIMITED, NANOFRONT). The hooks of the hook-and-loop fastener were attached to one end of the fabric rubber, and the loops of the hook-and-loop fastener were attached to the other end of the fabric rubber, so that the bandage could be applied to the big toes of individual monitors having different big toe sizes.
Regarding the cushioning member (big-toe-base inner-side protrusion cushioning pad) 5, a member made of neoprene was used.
The corrector storage bag 6 was made of neoprene, and a fabric rubber having one surface covered with the hooks of a hook-and-loop fastener was sewed into a bag shape such that the hook-and-loop fastener would be exposed at the surface. The surfaces of protruding inner sides of the opening of the bag were sewed with the hooks and the loops of the hook-and-loop fastener so that the corrector would not come out.
Regarding Comparative Examples, used were, respectively, a conventional hallux valgus correction device illustrated in
These hallux valgus correction devices of Examples and Comparative Examples were, respectively, used and applied to fourteen (14) hallux valgus patient monitors, and thus the correction devices were evaluated for the following items.
For each of the items, the correction devices were rated as excellent “⊙”, satisfactory “∘”, acceptable “Δ”, or unacceptable or poor “x”. A correction device rated as Δ or x for even a single item was considered inappropriate (poor) as the hallux valgus correction device.
The results for the above evaluation are presented in the following table.
From the results shown in Table 1, the following is clearly understood.
When the hallux valgus correction devices of Comparative Examples 1 and 2 were used, the comprehensive evaluation results were poor. Particularly, the wearability in the nighttime was poor, and specifically, the correction devices got sweaty or easily dislocated. That is, due to a slight feeling of strangeness (discomfort) at the time of wearing, it was difficult to wear the correction devices in the nighttime (in sleep) for a long time (for example, 8 hours or longer).
On the other hand, in the Examples according to the present invention, excellent results were obtained for all of the evaluation items, and seven people out of fourteen monitors saw an improvement of 5° or more in the angle of hallux valgus (an improvement was recognized in
Having described our invention as related to the present embodiments, it is our intention that the invention not be limited by any of the details of the description, unless otherwise specified, but rather be construed broadly within its spirit and scope as set out in the accompanying claims.
This application claims priority on Patent Application No. 2016-132096 filed in Japan on Jul. 1, 2016, which is entirely herein incorporated by reference.
1 hallux valgus correction device
2 fastening band (metatarsal bone fastening belt)
3 fixture (second annular bandage)
4 fixture (first annular bandage)
5 cushioning member (big-toe-base inner-side protrusion cushioning pad)
6 corrector storage bag
10 corrector (sheet made of superelastic alloy)
11 hinge part
R angle of hallux valgus
21 splint (correction sheet, correction sheet made of superelastic alloy)
22 space
23 annular fastening device (for metatarsal bone)
24 annular fastening device (for big toe)
25 hook-and-loop fastener
31 splint with spring property (typically, made of plastics)
32 hinge
33 second annular fastening device
34 first annular fastening device
Number | Date | Country | Kind |
---|---|---|---|
2016-132096 | Jul 2016 | JP | national |
This application is a Continuation of PCT International Application No. PCT/JP2017/024092 filed on Jun. 30, 2017, which claims priority under 35 U.S.C. § 119 (a) to Japanese Patent Application No. 2016-132096 filed in Japan on Jul. 1, 2016. Each of the above applications is hereby expressly incorporated by reference, in its entirety, into the present application.
Number | Date | Country | |
---|---|---|---|
Parent | PCT/JP2017/024092 | Jun 2017 | US |
Child | 16235510 | US |