WO2006060962A2 - Shape, ability and application of a bladder for footwear - Google Patents

Description

 BACKGROUND OF THE INVENTION 1. Field of the Invention

 The technical field of the invention pertains to footwear. Prior art prior to the present invention

 See Chinese Patent No. 90101430 3, Authorization Bulletin No. CN1026056C, Patentee Henry E. Rozena, Inventor Name Adjustable Footwear Structure, Manual Page 1... "In conventional footwear, such a suitable fit can only be achieved approximately by providing a full set of nine or more consecutively graded width increments for each length gauge. However, even with such a full width grading, There is still a need for some further measures of lateral adjustment to accommodate the difference in the length of the left and right feet, as well as the variation in the length of the circumference caused by the daytime activities and other causes of the foot. This is mainly due to the accumulation of liquid in the feet. The changes caused in the process usually reach one and a half or even two entire widths....... 11 pages.... This lining that correctly achieves the considerable adjustment of the lateral length of the shoe should provide at least one whole standard' Width', that is, at least 1/4 inch of lateral length adjustment at the arch and instep of the foot, in order to achieve such adjustment and proper compression, the lining should be 1 more than the lining of the upper. /16" and 1/8" fabric-foam lining material is thicker, starting from about 3/8" to 1/2" thick."

 See "China's footwear industry design, craft design book" Xing Dehai main page 9" ". Season also affects the size of the foot, in order to maintain normal physiological functions in summer, need to increase heat dissipation to the outside, foot blood vessels expansion At this time, the size of the foot is large, and the opposite is true in winter. In order to reduce heat dissipation, the entire foot including the microvessels is in a contracted state, so the winter size is small. "See "Practical Rubber Shoes Design" Sun Jitian 97 Page ".... The circumference is the part of the body that bends frequently when walking. It bears the load of weight and labor. When the foot is not loaded with weight except for the weight load, the size of the movement is very different. The test male foot is increased by 13 · 5 mm and the female foot is increased by 16 mm.

 See "Reference News", April 8, 2002, 15th Edition "'s annoyed high heels, [Russia (Moscow Communist Youth League) March 7 article] Title: High heels (author Ka. Merkumyan) .... Their shoes are getting taller and heavier and thinner. The result paid a heavy price. They felt a pain in their legs and a big corn on their feet. .... Since then, stiletto shoes have become popular. This kind of shoe causes deformity of the foot, .... The American Stock Exchange stipulates that the female staff's heel can only be between 4 and 5 cm. "

No patents have been retrieved for reducing the damage of high heels to the feet and invention patents for reducing the damage of high heels to feet (in China). Purpose of the invention

 The present invention discloses a technique for bearing all or most of the body weight (reducing or eliminating the force on the toes and forefoot) with the sole or upper or sole and the load bearing members of the upper. Technical solution adopted by the invention

 From the majority of the Chinese patents on shoe airbags that have been consulted, the present invention has: 1. The airbag type adjusting device can steplessly adjust the lateral width of the shoe up to 3 standard 'widths, range capacity (referred to as the three standard) Wide/stepless); 2. The airbag type adjustment device can accept the average pressure of the foot surface (referred to as the equalizing pressure); 3. The method of reducing the damage to the foot is the special outer shape of the foot using the airbag type adjusting device. The space between the airbag type aligning device 1, 2, and the space between the filling foot and the annular inner lining sleeve (referred to as the filling space), preventing the foot from moving forward in the shoe, and the resistance is transmitted to the load-bearing member; The sole or the upper or the sole and the load-bearing member of the upper are responsible for all or most of the body weight and can be adjusted; 5. The airbag type adjustment device is applied to the high-heeled shoes (or ballet shoes), and is carried by the load-bearing member to bear all or Part of the body weight for this purpose or to eliminate damage to the foot.

 First, the structure, type and structure of the airbag type adjustment device; Second, the available structure / class / knot of the airbag type adjustment device; Third, the composition of the sandal airbag and the available structure / class / knot; Fourth, the airbag type adjustment device The ability and method and the ability and method of sandbag airbags; 5. Airbag type adjustment device, sandal airbag and load-bearing components; 6. Load-bearing means: sole weight-bearing method, upper weight-bearing method, sole weight-bearing method and The weight of the upper is supported; 7. The implementation scheme of the airbag type adjustment device arranged in the four zones and the load-bearing mode and the seven sandbag airbag implementation schemes; 8. The airbag type adjustment device, the sandal airbag and the load-bearing mode have 'equivalent Features' programs, parts.

 We know that the circumference of a human foot can have a range of 16 mm, which is equivalent to a stepless variation of the standard 'width' of about 2 and a half; the shape of the foot in the concave of the middle and toe areas; the special outer shape of the foot; Can not withstand the pressure concentration and the average pressure, according to the above situation, the airbag type adjustment device must have: 1, stepless adjustment of the shoe circumference to up to 3 standard 'width, the range of ability; 2, the foot surface is subject to the average pressure 3, the space between the filling foot and the inner lining sleeve and the convex shape and the foot recess closely cooperate. In order to prevent the foot from moving in front of the inner phase of the shoe, it can achieve the purpose of taking all or most of the body weight.

 The 'horizontal length' described herein is defined as the lateral circumference around the foot.

 The airbag type adjustment device has: structure; attached.

First, the structure, type and structure of the airbag type adjustment device are characterized by: 5 types of structures, 12 types and structures, arranged in four areas. The structure, type and structure of the airbag type adjustment device are as follows: 5 types of structures, 12 types and structures, arranged in four areas. The general characteristics of the five types of airbag type adjusting device are: 1. The annular air bag is made of a stretchable material, and the annular air bag is arranged inside the annular inner lining cloth sleeve (between two layers of inner lining cloth sleeves); 2. On the outside of the annular airbag, there is a ring-shaped inner lining sleeve (or sole and upper) made of non-stretchable material. 3. The annular airbag can inflate the inner edge of the lining to the upper edge of the sole and the inner edge of the upper to the maximum thickness inside the lining. When reaching 1/2 inch or 12.7 mm and working, the upper and lower sides are not in contact; 4. There is no elastic space between the annular airbags.

 1. Annular lining cloth sleeve and annular airbag; 2. Airtight annular lining cloth sleeve; 3. Hard shell and ring lining cloth sleeve and annular airbag; 4. Hard shell and annular airbag; 5. Airbag airbag .

 Auxiliary: 1, lining; 2, flesh-colored nylon cloth limit ring (hard shell and annular air bag, hard shell and ring inner lining cloth cover and annular air bag not used); 3, around the inner lining cloth cover a few metal rings or Cloth ring.

 1. Ring-lined cloth sleeve and annular airbag (referred to as inner/gas); the following description is mainly for this purpose. There are flesh-colored nylon cloth limit rings in the four areas, and there are no metal rings or cloth rings in the toe area.

 2, airtight ring lining cloth cover (referred to as not leaking cloth cover) in the sewing ring does not leak cloth cover and will not leak cloth cover and load-bearing members, load-bearing steel wire, support ring at the sole four points, the upper four points , need to paint, in order to ensure that there is no air leak. It can be fixedly connected by means of a support ring connection or a wire connection. There are flesh-colored nylon cloth limit rings in the four areas, and there are no metal rings or cloth rings in the toe area.

 3, hard shell and ring-lined cloth sleeve and annular airbag (referred to as shell / inner / gas), 2001 test ballet shoes model structure, is a hard shell and ring-lined cloth sleeve and annular airbag structure, in the shoes When the outer part of the inner lining sleeve is placed close to the inner lining sleeve, a hard plastic sleeve (referred to as a hard shell) is added. The inner shape of the hard plastic sleeve completely matches the outer shape of the foot, but the foot is a little larger (because the foot is larger) Consider the thickness of the inner lining and the lining.) If properly inflated, it can prevent the foot from moving forward in the shoe and bear part of the body weight. The actual working area is in the center of the shoe. Because the annular ring has a vertical circumference of 9 cm and the contact surface is only 3 cm, the test results are good. This structure has no limit ring or cloth ring.

 4, hard shell and annular airbag (referred to as shell / gas), from the medical anatomy, there are five shin bones, three wedge bones, one stern bone in the middle area, no hard shells. There are active joints in the toe area, and there are problems in arranging the hard shell. The hard shell and the load-bearing member are connected at four points on the sole of each area and four points on the upper. A hard plastic sleeve is added between the sole, the upper and the lining, the annular airbag is fixed on the hard plastic sleeve, and the hard plastic sleeve is fixedly coupled with the load-bearing member. This configuration has no restrictions on the 圏, cloth ring.

5, cloth air bag (or cloth / gas) with a cloth air pipe cut out the length of the foot circumference, the two ends are glued into an annular air bag, which is glued inside and outside, the middle is cloth, that is, plastic cloth. See "Chemical Product Manual, Rubber and Rubber Products" Edited by Liu Dengxiang on page 386.... "002 cloth hose.... The structure cloth hose is made of inner layer glue, tape layer and outer layer glue. The tape layer is made of hanging rubber canvas. The number of layers of the cloth is from 1 to 10 layers, according to the specifications of the hose. And the required working pressure is determined....... 004 cloth air hose.... Performance characteristics: soft body, good internal air tightness, good rubber wear resistance, good aging resistance, safety factor 4 times, inner diameter 13 - 152 mm. ...... 041 fiber braided (wound) hose.... "The airbag made of the cloth hose is called a cloth airbag. It differs from the airtight inner sleeve only in that it has glue inside and outside. The inner sleeve is not leaky inside or outside. The cloth/gas and inner/gas, non-leak cloth sleeves have 'equivalent characteristics'.

 The airbag type adjusting device (inner/gas, ie, the inner lining cloth sleeve and the annular air bag) is constructed as follows:

 (1) The shape of the annular airbag of the airbag type adjustment device. The annular airbag of the ballet shoe model is modified by a 28-inch bicycle inner tube. The 28-inch bicycle inner tube has a lateral annular circumference of 9 cm and a vertical annular circumference of about 28 inches. Since the lateral annular circumference of the bicycle inner tube in the ballet shoe model is 9 cm, the front and rear vertical circumferential circumferences of the annular airbag of the ballet shoe model are defined as the vertical annular circumference of the annular airbag; the vertical annular circumference of the bicycle inner tube The length of 28 inches is changed into the horizontal annular circumference of the annular airbag of the ballet shoe model along the circumference of the foot, which is defined as the lateral annular circumference of the annular airbag. The annular airbag of the airbag type adjustment device has the same shape as the annular airbag of the ballet shoe model, and also has a vertical annular circumference of the annular airbag and a lateral annular circumference of the annular airbag, which is simply referred to as the vertical circumference of the airbag and the lateral circumference of the airbag.

 (2) The shape of the annular inner lining sleeve of the airbag type adjusting device is basically the same as that of the annular air bag of the ballet shoe model, the difference is that the annular inner lining cloth sleeve is larger than the size of the annular air bag, and the inner shape of the ballet shoe model is The shape of the lining sleeve is basically the same as the shape of the annular airbag of the ballet shoe model, the difference is that the annular lining sleeve is larger than the size of the annular airbag and the excess portion of the annular lining cloth sleeve is not cut but hangs over the entire hang. Back support

(turned into a barrel type with a stainless steel sheet)). The annular inner lining sleeve of the airbag type adjusting device has a shape similar to that of the annular air bag, so that the vertical annular circumference of the annular inner lining cloth sleeve and the lateral annular circumference of the annular inner lining cloth sleeve are referred to as the vertical circumference and cloth of the cloth sleeve. Set of lateral perimeters.

 1) The ring-lined cloth sleeve is made of non-stretchable material, and the position is surrounded by the left, right, upper and lower sides of the inner lining of the shoe. The front, rear, upper and lower sides surround the annular airbag, and the inner lining cloth sleeve The front, back, upper and lower sides are sewn together and have the strength to bear the weight of the body.

 2) The front side wire and the rear side wire, the front side wire and the rear side wire are installed on the front and rear sides of the outer position of the annular air bag inside the ring-lined cloth cover and surround the front and rear sides of the ring-lined cloth cover, and the front side of the ring-lined cloth cover Coupled with the rear, referred to as the front and rear wires.

3) Airbag type adjustment device in the central area, central area, and shoe center area, in the middle, rear and front positions of the ring-lined cloth sleeve The outer ringing of the ring-lined cloth sleeve surrounds the left, right, and upper sides, and several metal rings are sewn to facilitate the installation of the shoelace. In the outer middle position of the annular inner lining sleeve in the middle of the shoe, the outer upper part of the annular inner lining sleeve of the middle portion of the shoe is close to the position of the rear steel wire, and the lower part of the annular inner lining cloth sleeve of the center of the shoe is close to the outer position of the front steel wire, surrounding the ring A metal ring or a cloth ring is sewn on the outside of the inner lining cloth sleeve, and the two sides of the shoelace are respectively passed through the metal rings or cloth loops, and then respectively wrapped around the soles, and the innermost two loops of the shoelace are wrapped around the lining. Cloth cover, two outer rings around the sole.

 (3) lining, the lining is made of a stretchable material, and the lining is installed inside the annular inner lining sleeve.

 (4) Arrangement The air pipe is threaded out of the annular inner lining cloth sleeve and connected to the valve and the valve switch.

 The inlet and outlet ports are located on the right side of the left shoe and the left side of the right shoe in the middle area to facilitate airing and deflation when wearing.

 (5) A flesh-colored nylon cloth restraining ring (referred to as a restraining ring), which limits the outward expansion of the annular inner lining sleeve, which is the front and rear sides of the annular inner lining cloth sleeve. <

 There are 12 types and structures for airbag type adjustment devices:

 The four-sided circumference means that the annular airbag of the device is wrapped around the outside of the foot along the circumference of the foot or the inside of the shoe, including the upper side, the lower side, the left side, and the right side. Three-sided circumference means that the annular airbag of the device is surrounded by the three sides of the foot or the inside of the shoe, including the upper side, the left side, and the lower side; the left side, the lower side, the right side; the lower side, the lower side, the upper side; the right side, the upper side, the left side, and four types. The two-sided circumference means that the annular airbag of the device is wrapped on the outside of the foot or on the inside of the shoe, including the upper side and the lower side; the left side and the right side; the upper side and the left side; the left side and the lower side; the lower side and the lower side; the right side and the upper side have a total of six types. The bottom wall means that the annular airbag of the device has only the bottom surface, and there are twelve types of four-sided, three-sided, two-sided, and bottom-side enclosures. The four-sided, three-sided, two-sided, and bottom-mounted annular inner liners are the same. of.

 The structure of the four-sided airbag type adjusting device is arranged in the lateral annular circumference of the four-sided annular airbag, and the annular inner lining cloth wraps the front side, the rear side, the upper side and the lower side of the upper and lower airbags on the four sides of the annular airbag; The left side of the airbag, the front side, the rear side, the left side and the right side of the airbag, the trachea passes through the annular inner lining cloth sleeve, and the front and rear steel wires of the annular inner lining sleeve are along the length of the foot and the front and rear sides of the inner lining cloth sleeve. Firmly connected.

 The structure of the three-side airbag type adjusting device is arranged on the lateral annular circumference of the three-sided annular airbag (three sides along the length of the foot circumference), and the inner side of the airbag is wrapped on the front side, the rear side, the upper side and the lower side of the airbag on the four sides; The inner lining cloth wraps the left side of the annular air bag, the front side, the rear side, the left side and the right side of the right air bag, and the air pipe passes through the inner lining cloth cover, and the front and rear side wires of the inner lining cloth are along the leg transverse length and the inner lining cloth. The front and rear sides of the sleeve are firmly connected, and the two sides of the three-sided annular airbag are vertically sewn with steel wires on the inner lining sleeve.

Two-sided airbag type adjustment device structure, two sides of the annular airbag transverse annular circumference (long side of the foot circumference) Arrangement (separate or continuous), the inner lining cloth wraps the upper side of the annular airbag, the front side, the rear side, the upper side and the lower side of the airbag on the four sides; the inner lining cloth wraps the left side of the annular airbag, the front side of the right airbag, the rear side, the left side, the right side The air pipe passes through the annular inner lining cloth sleeve, and the front and rear steel wires of the annular inner lining cloth sleeve are firmly connected with the front and rear sides of the inner lining cloth sleeve along the transverse length of the foot, and the two sides of the annular airbag are continuously connected. The lining sleeve is vertically sewn with steel wire, and the two sides of the two-side annular airbag are separated, and the steel wire is tightly sewn on the annular inner lining cloth sleeve.

 The structure of the bottom wall surrounding airbag type adjusting device is arranged such that the bottom annular surrounding airbag has a lateral annular circumference (long along the long bottom surface of the foot), and the annular inner lining cloth sleeve wraps the front side, the rear side, the upper side and the lower side of the bottom airbag, and the air tube passes through the annular lining The front and rear wires of the annular inner lining sleeve are firmly connected to the front and rear sides of the annular inner lining sleeve along the transverse length of the foot, and the left and right sides of the airbag are placed on the annular inner lining cloth cover. Sewing to the wire.

 The four districts refer to: 1. The central district (including the central district and the shoe core zone) is in the area of L-L'-E'-EL in Figure 27 and the right, upper, left and lower sides of the foot; 2. Central District In Figure 27, L-L'-G, -GL and the right, upper, left, and lower sides of the foot; 3. The center of the shoe is G-G'-E'-EG and the foot in Figure 27. Right, upper, left, and lower areas; 4. The toe area is the T-T'-P'-PT in Figure 27 and the right, upper, left, and lower sides of the foot.

 Second, the available structure/class/junction of the airbag type tuning device is characterized by: 88 available structures/classes/junctions.

 The Central District, the Central District, the Shoe Heart Area, and the Toe Area are referred to as the Four Districts.

 11 types (including 2 types of 2 types) of the 12 types of airbag type adjustment devices in the middle area are available. [The upper and left sides are referred to as (upper, left) and so on], because the left foot is recessed. On the right side, the right foot is recessed on the left side, so (upper, left) and (right, top) are 1; others are (up, left, down, ), (lower, right, upper), four, (left , down, right), (left, bottom), (lower, right), , (up, down, ), down, (left, top, right), (left, right), 11 types and structures of airbags Adjustment device. The airbag type adjustment device of 11 types and structures is also applicable to the central area and the shoe center area.

 The toe area airbag type tuning device 12 types and structures are available in 8 types and structures, which are four, (left, lower, right), (left, ), (lower, right), (up, left, down, ), (lower, right, ±), (up, down, ), down, another (up, left), (right, top), (left, top, right), (left, right) 4 kinds of no cause It is useless.

 1. There are 11 types and structures in the middle zone/gas and non-leakage inner casing; 1 type of structure with shell/inner/gas and shell/gas, total available structure, available type and structure are 2*11+ 2*1=24 kinds.

 2. There are 11 types and structures in the central area/gas and non-leakage inner casing; one type of structure with shell/inner/gas and shell/gas, total available structure, available type and structure are 2*11+ 2*1=24 kinds.

3, there are 11 types and structures in the center of the shoe / gas and no leak inner sleeve; 1 kind of structure with shell / inner / gas and shell / gas Type, total available structure, available type and structure are 2*11+2*1=24.

 4. There are 8 types of 4 structures in the toe area/gas and no leak inner sleeve. The total available structure, available type and structure are 2*8=16 kinds.

 Available in the four regions / class / knot 88

 Third, the composition of the sandals airbag and the available structure / class / knot, which are characterized by the four available structures / classes / knots of the sandals airbag. The airbag airbag is composed of an airbag (an airbag shaped like a bottom airbag type adjusting device), and an outer casing made of a non-stretchable material, and the outer shape of the outer casing is similar to that of a bladder-type airbag adjusting device on the bottom surface. The airbag is slightly larger, arranged in the middle area, the middle area, the shoe center area, and the bottom surface of the toe area. The airbag airbag only has the upper surface and the sole of the foot. The difference between the airbag and the bottom airbag type adjustment device is only the outer casing and the bottom surface of the sandal airbag. The annular inner lining sleeve of the airbag type adjusting device can be said that the sandal airbag is a special bottom wall surrounding airbag type adjusting device.

 Standard: Walking with a height of 20 mm, the measuring point force unit is 0.01 kg as the standard, and the standard and scale are as follows. "Chinese shoe size and shoe last design" Edited by the Light Industry Ministry of Footwear Industry Research Institute 88 pages. "Select a foil-type resistance strain gauge of 2 by 3 mm2 (produced by Zhejiang Huangyan Test Instrument Factory) with a resistance of 108 m and a sensitivity coefficient of 2.09... If the load unit is 1/100 kg, the strain gauge The reading is micro strain ms, .... The repeatability error is less than l/100ms. The Y6D-3A dynamic resistance strain gauge is used in the actual measurement, and the minimum calibration error is plus or minus 1/100 when used in the most sensitive gear. The sensitivity of the force sensor meets the test requirements.... The insole with sensor is called sensor insole, which consists of sensor, rubber and sheepskin insole and measuring wire. The steps are as follows: 1. Describe the footprint according to the standard of male and female. The footprints depict the male and female footprints. 2. Arrange the measuring points to make the measuring points based on the footprints of the feet. Generally, the deeper parts indicate that the force is large. Therefore, the measuring points can be set more; , can be set less. The location, number and number of the insoles of men and women, ...; The number of points and numbers of the main features of the palm and face of men and women are as follows:

 Male, female, female

 Number of measuring points number range measuring point

 Toe area 10 1-10 10 1-10

 Anterior part of the foot 38 11-48 34 11-44

 Foot part 5 49-53 4 45-48

 踵心部 37 51-90 27 49-75

The total number of measuring points is 90 - 75 - the unit of load is abbreviated as unit, and the area of measuring point is equal to the area of foil-type resistance strain gauge 2 by 3 square millimeters is 6 square millimeters. 05 002132 The load cell is a foil-type strain gauge that is measured using a Y6D-3A dynamic resistance strain gauge 6 . A total of 75 foil-type strain gauges were placed. The values below the squares in the figure are the numbers of the foil-type strain gauges, from 1 in the upper right corner to 75 in the lower part. The value in the square is the value of the force measurement. .... "Page 98.... The total value in the table represents the sum of the force values of all the measuring points, which should be equal to half the weight of the tested person. For example, the measured man's weight is 56 kg, and the half is 28 kg. 4-1 knows the 'total value' of the measurement error is +01% to +03%; the woman's weight is 57.5 kg, half of which is 28.75 kg, the measurement error of 'total' is -1. 6% to +3%. For the convenience of analysis and comparison, the data of Table 4 - 1 and Table 4 - 2 are marked on the corresponding measuring point position according to a certain scale, and are connected along the weft line (the force value of the edge of the foot type) 0) and Figure 4- 13 (1) - (4) and Figure 4- 14 (1) - (7). The OW line in the figure is the axis of the chassis, and each latitude is perpendicular to the axis, and the values on the axis are The distance between the latitude line and the axis intersection from the end point 0 of the chassis (mm) ......, ,

 Measured in Figure 27, the distance from the sole of the OW cable to the C-C' is 20 mm, and the actual distance is 43 mm. The measured distance from the bottom of the OW cable to the D-D' is 27 mm, and the actual distance is 57 mm. The distance from the sole of the shoe to the FF is 42 mm, the actual distance is 88 mm, and the scale is between 1:2.09 and 1:2.11. Measured in Figure 33, the distance from the bottom of the OW cable to the H-H' is 59 mm, the actual distance is 121 mm; the measured OW connection sole to the EE distance is 35 mm, the actual distance is 72 mm; the measured OW cable sole The distance to Q-Q' is 93 mm, the actual distance is 190 mm, and the scale is between 1:2.043 and 1:2.057. The scale of the current map is 1:2.

 4. The ability and method of the airbag type adjusting device and the difference between the ability and the method of the airbag airbag are characterized in that: the airbag type adjusting device has three standard width/stepless, equalizing pressure, filling space, two large and small small capacity Sandals airbags are less than three standard width / stepless; the method has a middle area method; the middle method; the shoe heart method, the toe method.

 The ability of the airbag type adjustment device refers to three standard width / stepless, pressure equalization, filling space, two small and medium:

 Three standard width / stepless: Mathematical method to prove: The adjustment device has the ability to adjust the horizontal length of 3 standard 'width' or more, see the "Secondary Practical Handbook" Cao Bin compiled 226 pages "... Figure 3. As shown in Figure 3-11, the point P on the curve C and the secant of the point Q. When the point Q approaches the point P infinitely along the curve, if the secant approaches a straight line T, the line is called Τ is the tangent of the curve C at the point 。. Such a point Ρ is called the tangent point of the tangent.... A line that crosses a point on the curve and is perpendicular to the tangent of the curve at that point is called the normal of the curve at that point.

 The difference between the four-sided encirclement method and the three-sided encirclement method (including some two-sided encirclement method) is that the three-sided encirclement method has no airbags on one or both sides, and there is no airbag and airbag transition. Ρο point and P(x+1) point and Α1, Β1 point and Ρο point are connected, Αχ, Βχ point and Ρ(χ+1) point are connected.

In the three-sided painting method and the two-sided painting method, there are the same as the circumference, the right and the top of the circumference; the upper and the left; the left and the lower; the lower, There are 8 on the right, plus the circumference of the three sides, the right, the upper, the left; the upper, the left, the lower; the left, the lower, the right; the lower, the right, the upper; there are eight, the two have 16 The three-sided painting method is different from the two-sided painting method. There are four upper and lower sides, and the left and right sides are combined. There are two paintings in the four sides of the four sides.

 The difference between the three-sided painting method and the partial two-sided painting method is that the upper and lower parts are not connected in the middle of the left and right parts. Therefore, PLo, PL1, PLx, PL(x+1) are added. The complete set of symbols such as C, D, PLo, PL1, PLx, and PL(x+1) are equivalent to Po, P1, Px, and P(x+1). The descriptions of C and D are equivalent to A and B, respectively. On the lower and right sides, the drawing on each side is the same as the three-sided painting.

 Description of symbols and numbers in the drawings:

 A ——the position inside the inner lining when the airbag is not inflated

 B - The position of the inner lining of the airbag expansion end point (design point).

 P0—the joint point (design starting point) of the adhesive point of the airbag and the fixed inner lining.

 P (x+1) - the point of attachment (design end point) between the balloon and the attachment point in the fixed lining.

 P1→0 is the point on the periphery of the foot (including the circumference or the circumference).

 Px ~ +1 points on the periphery of the foot (including the circumference or the circumference).

 The secant of L1 - P1; Ax - the point of the secant outward, at the position of A.

 A1 - L1 secant outward point, in the position of A.

 B1 - L1 secant inward point, at position B; Bx - secant inward point, at position B. The four-sided symbols are: PI Al Bl Px LI T1 Q1 A B Ax Bx

 The symbols of the three sides are: · P0 PI Al Bl Px P(x+1) A B Ax Bx

The symbols of the two sides are: P0 PI Px P(x+1) PLo PL1 Pb PL(x+l) ABCD Figure 1 is a cross-sectional shape of the circumference of a person's left foot in the autumn (the closed approximation in the middle) Line) The measured circumference is 243 mm. The length of the ankle and the scale of the figure are 1: 1. Draw a point on the upper right side of the circle of Figure 1. This is defined as Pl, which is drawn on the map. The point PI and the secant L1 of the point Q1, when the point Q1 approaches the point PI infinity, if the secant line L1 approaches a tangential line of a certain straight line tl around the point P1, such a point P1 is called the tangent Cut the point to draw a point P1 around the circle and perpendicular to the line around the line at the point where the line is called the normal around the point P1, draw a point from the point P1 along the normal line to 2 mm outside the circumference. This point is defined as A1; draw a point from the point P1 along the normal to 2 mm inside the circle, which is defined as Bl. A similar painting is drawn until a point is drawn a few millimeters to the right of the PI point. This is defined as PX, and the Ax point and the Bx point are drawn in a similar manner. Finally, the points of AX to A1 are connected by a drawing line, so that there is a closed curve at 2 mm outside the long circumference of the ankle in Fig. 1, and the closed curve is defined as the circumference A; Connect the points of BX to B1 with a line, so that there is a closed curve at 2 mm inside the circle. The closed curve is defined as the circle 8.

 In Figure 1, the circumference A is the maximum circumference. When the air bag in the sheet is airless, the position of the inner lining cloth is actually shown in Figure 1 in Figure 1, and the horizontal circumference is 254 mm. After the airbag is inflated and expanded in the minimum circumference, according to the design position of the inner lining cloth of Fig. 1, the actual measurement of the circumference B, the circumference of the circumference B is 234 mm, and the circumference of the circumference is reduced by 234 mm. To the circumference of the B, the length of the circumference of the circumference is 22 mm, which is equivalent to 3 standard 'widths'.

 Figure 6 is a cross-sectional view of the circumference of a person's left foot in the autumn (the closed round line in the middle). The measured circumference is 243 mm, and the scale of the ankle is 1 : 1. The curve inside and outside the ankle is drawn according to the method of drawing in Figure 1. The difference is that the Px is selected at the lower left of the circumference (not including the side of the sole, that is, the four sides become the left. Upper. Right Three sides) At the point P1, move 5 mm to the left (according to the actual number). Draw a point on the circle, define this point as P0, draw a short line to connect A1 to P0, and draw a short line to connect B1 to P0. At the PX point to the right 5 mm (according to the actual external shift), draw a point on the circle, define this point as P (X+1), draw a short line to connect AX to P (X+1), draw A short line connects BX to P (X+1). Thus, a curve and a P (X+1) to P0 curve are formed together on the left, upper, and right sides of the outer circumference to form a closed curve, and the closed curve is defined as eight. A curve and a P (X+1) to P0 curve are combined to form a closed curve at 2 mm on the left, top, and right sides of the inside of the circle, and the closed curve is defined as the circle B.

 In the actual map 6, the width of the circumference of the fence A is 240 mm, and the circumference of the fence B in Figure 6 is measured. The length of the circumference of the fence B is 214 mm, and the circumference of the fence A is subtracted from the circumference of the perimeter B. The length of the circumference is adjusted to 26 mm, which is equivalent to 3 semi-standard 'width'. The lining is 5 mm thick.

The scale of Figure 14 is 1:1. We actually measured the curve A in Figure 14 and the curve B plus curve D are 130 mm and 82 mm, respectively. The difference between the two values is 48 mm. The length range is 0 to 48 mm, and we actually measure 9 mm between ellipse A and ellipse B (the distance between the variable portion is 9 mm and the thickness of the airbag is 9 mm). Therefore, we can say that the thickness of 12.7 mm can reach 0 to 3 standard 'width' or 0 to 21 mm or more to adjust the length of the horizontal length. In Fig. 14, the distance of the adjustable lateral length in the two-sided circumference is the shortest, and the adjustment range is the most unfavorable for increasing the range of the adjustment lateral length, and then various other two-sided, three-sided, The four sides have a good adjustment range. .... In the curve of the left group, the curve outside the ankle is the circumference A, and the curve inside the ankle is the circumference B. The curve outside the ankle in the right curve is the circumference C, and the curve inside the ankle is the circumference. D, the measured circumference A is 72 mm in length, the measured circumference B is 48 mm in length, and the measured circumference is 58 mm in length. The measured circumference D is 34 mm in length. The adjustment range is from 0 to 48 mm. Equivalent to more than six and a half standard 'width', with a lining thickness of 9 mm.

 The actual situation is different from the results obtained by the above mathematical methods, but one point can be adjusted to a standard width of 0 to 3 standard 'width' or 21 mm or more when the thickness of the two sides is 9 mm. Then, when the thickness of the three sides or the four sides is 9 mm, the adjustment of the horizontal length must be 3 or more. "

 It is proved by mathematical method that the adjustment device has the ability to adjust the horizontal length by more than 3 standard 'width'; and it is the stepless adjustment of the shoe transverse length (referred to as the three standard width / stepless). The inflation of the airbag in the airbag type adjusting device is proportional to the length of the airbag type adjusting device to adjust the lateral length of the shoe. The smaller the lateral length of the shoe, the shorter the distance the foot moves downward in the shoe, and the body weight is on the toe. The lower the pressure, the pressure is zero until the toes are off the ground. In this way, in a certain gas volume range, the airbag in the airbag type adjusting device is proportional to the weight of the toe to bear the body weight, and the inflation amount can be 1 cubic centimeter or 1 cubic millimeter, which is stepless, so It is also stepless to bear the weight of the body. According to the actual needs, adjust the amount of air in the airbag type adjustment device, so that the body weight on the toes is a suitable value.

 2, see "Ordinary Physics Book" Li Zhendi, 342 pages ".... Pressure, volume, temperature are three parameters necessary to describe the characteristics of a certain amount of gas. If a certain amount of gas occupies a certain volume, and the temperature inside the gas When the pressure is the same, the gas is said to be in equilibrium. ...... It should also be noted that when the gas is in equilibrium, it is macroscopically expressed as the same relative static state at various pressures in the gas.... 7.2. 1 Boyle-Malillo's law is a gas of a certain mass. Under the condition that the temperature remains unchanged, the relationship between the pressure and the volume is inversely proportional, that is, P1V1=P'V'=P"V"=... =P2V2 = constant or writable as PV-constant (M and T are unchanged)

 (7.2.1) .... "See "Secondary Middle School Physics" [English] Abbot Nercon, pp. 303, "... We define pressure as the pressure acting vertically on a unit area. ", therefore pressure = total pressure value / area. Assumptions: 1, air quality is unchanged, 2, temperature is constant (ambient temperature) 3, the pressure area is constant, 4, "pressure temperature is the same everywhere" 5, the condition is to make The airbag can be inflated onto the airbag and the lower two sides will not touch.

 According to the above theory, after the airbag in the shoe is inflated (put on) and after standing for a while, the temperature is the ambient temperature (the temperature remains unchanged, unchanged), or the gas of a certain mass in the airbag (unchanged), the pressure Everywhere is the same, in balance.

See "Structure, Type and Structure of Airbag Type Securing Device, Capacity and Application 1" on page 7 "The average pressure of the foot surface (referred to as the average pressure), the theoretical pressure value of the test, the total force is the body weight down The generated gravity is 60 kg, which bears the area of gravity. Since the toes do not bear gravity, all the area of the airbag that is in contact with the surface of the foot is the area of gravity. The lateral circumference of the inner tube of the 28-inch bicycle is 9 cm (measured), because Gas tight The surface of the foot is only 4.5 cm to the side of the foot, and is now set to 3 cm. In the actual picture 1, the center of the shoe is close to the circumference of the foot, the length of the foot is 24 cm, and the length of the foot is 24.5 cm. Set to 24 cm, the area is 72 square centimeters, the formula P = F / A = 60 kg / 72 square centimeters = 6000 units / 7200 square mm = 0.8333 units / square mm

 0.8333 units / square mm * 6 square mm = 4.99999 units / measuring point, in Figure 6 (excluding zero), most of the unit / measuring point pressure value is greater than 4.99999 units / measuring point. "

 3. Fill all the excess space between the circumference of the ring-lined cloth cover and the foot (referred to as the filling space), and the inner cloth cover is closely attached to the foot, thereby preventing the foot from moving forward in the shoe.

 4. In normal operation, first tighten the shoelace (or buckle), then inflate the excess space. Due to the characteristics of the airbag, it will be near the shoelace (or buckle) in the middle or middle zone or the shoe center. (In the ring-lined cloth sleeve), the two sides (upper and lower) are formed in a large middle and small shape (referred to as two large and medium-sized ones), and the effect is better. The sandals of the sandals are made of a non-leakable, non-stretchable material that is hollow and inflatable. It is wide and, when in use, is inflated and inflated to make it comfortable to wear.

 5. The airbag type adjusting device can only expand inward, reducing the lateral length of the shoe. When the gas in the annular air bag is increased, since the outer layer is made of non-stretchable material, the annular air bag can only expand inward. , reduce the length of the waist inside the shoe. When the gas in the annular airbag is reduced, since the annular airbag and the lining are made of a stretchable material and are closely adhered to the outer layer, the elastic force of the annular airbag lining can only be contracted outward to increase the lateral length. When there is no air in the annular airbag, the maximum length of the shoe is long. The elastic force of the lining is to ensure that the gas in the annular airbag is basically discharged when the air is not inflated.

When the air is used, the elastic force of the airbag itself or the film outside the airbag is used to increase the horizontal length.

 The installation position of the airbag type adjustment device refers to the position between the sole, the upper, the upper sole, or the upper to the insole or the lining under the Τ-Γ-F-E-L of Fig. 6.

 The method of the airbag type adjusting device refers to the middle area method; the middle method; the shoe core method, the toe method

 The method is airbag type adjustment device or sandal airbag of available structure/class/junction in the middle area, middle area, and shoe center area. The use capacity: three standard width/stepless, pressure equalization, filling space, two small, medium or small Pressing, filling space, two large and medium, preventing the foot from moving forward in the shoe, taking all or most of the body weight by the upper or sole or the load-bearing member of the upper and the sole; the airbag type of the available structure/category/junction in the toe area Surrounding device, ability to use: equalize pressure, fill space, reduce pressure, increase area, reduce or eliminate the damage to the feet when wearing high heels; available in the toe area sandals and airbags, use ability: pressure equalization, Reduces pressure and reduces or eliminates damage to the foot when wearing heel.

 The method is arranged in the middle zone is the middle zone method; the method is arranged in the middle zone is the middle zone method; the method is arranged in the shoe core zone is the shoe core method; the method is arranged in the toe zone is the toe method.

From the effect point of view, the best area in the central area has doubled, and the average pressure has doubled, followed by the heart area, the middle area, In the toe area, they have the same functional mode, they have a good effect compared to current ballet shoes, so they have 'equivalent features'.

 The mid-zone method, the ability to use a four-sided airbag-type adjustment device or a sandal airbag, (the concave shoelace that produces the convex-filled foot fits with the inner lining sleeve, and the airbag produces a large sash on both sides), which is blocked in the middle zone. The foot moves downward in the shoe, and the other 10 types of airbag type adjustment devices and the four-sided airbag type adjustment device have 'equivalent characteristics'.

 The middle method, using the ability of a four-sided airbag type adjustment device or a sandal airbag, fills the space in the lower part of the middle area; the four-sided airbag type adjustment device or the sandal airbag is matched with the shoelace, and the shoelace is tightened and the upper part of the middle area is inflated. , the airbag is formed on both sides, and the middle lace is small, thereby preventing the foot from moving downward in the shoe. The other 10 types of airbag type adjustment devices and four-sided airbag type adjustment devices have 'equivalent characteristics'.

 In the shoe method, the ability to use a four-sided airbag type adjustment device or a sandal airbag, (four-sided airbag type adjustment device or sandal airbag and laces, the airbag produces small laces on both sides), blocked in the shoe core area The foot moves down inside the shoe. The other 10 types of airbag type adjustment devices and four-sided airbag type adjustment devices have 'equivalent characteristics'.

 See "Structural, Type and Structure, Capability and Application of Airbag Type Securing Devices 1", 8 pages - 9 pages.... "In 2001, the model of the ballet shoes model (see Figure 52) was constructed. The inner lining cloth cover (made of stainless steel mesh cloth) was not surrounded by the airbag (the back was closed and connected with a stainless steel sheet bent into a barrel shape), and the trachea was worn out. The inner lining cloth sleeve is made of bicycle (28 inch) inner tube. The inner circumference of the inner tube is 9 cm. The airbag is arranged in the middle of the stainless steel mesh cloth. The connection method and the point are the inner lining cloth sleeve hanging on the back support. (Using a stainless steel sheet into a barrel shape), the upper (U-shaped bracket bent by a grooved aluminum alloy) is fixedly coupled with the front plate and the rear support, and the entire bracket can be fixed on the wooden base and perpendicular to the ground for convenient testing. .

 Operation process: Put the foot into the stainless steel sheet barrel type, then inflate, and then puncture the air bag into and out of the air tube. Then stand up on one foot, because the barrel is perpendicular to the ground, so the feet are also perpendicular to the ground. After the test, the one leg stands on the tip of the toe and the sole of the foot does not bear the weight of the body, and the single leg stands successfully many times and feels comfortable.

 The lateral circumference of the foot of the measured foot is 240 mm, the lateral circumference of the foot is 245 mm, the vertical circumference of the inner tube is 9 cm, and the front to back distance of the contact surface is not more than 45 mm. The distance from front to back is 30 mm, assuming an average transverse length of 240 mm, an area of 30 mm * 240 mm = 7200 mm 2 , at that time the weight is 60 kg equivalent to 6000 units, 6000 units divided by 7200 square mm by 6 to 4.999 units /Measuring point.

According to Figure 8 (Achilles tendon 20 mm walking state) E-E' line minimum is 88.6 units / measuring point, FF line minimum is 22.4 units / measuring point (foot value is zero), G-G ' line minimum is 77.8 units / At the measuring point, the H-H' line has a minimum of 25.8 units/measuring point, 88.6, 22.4, 77.8, 25.8, and all of them are greater than 4.999 units/measured points. (The value is zero, indicating that the measuring point is not accepted. If the instep and the sole are 90 degrees to the ground, the one foot does not bear the weight of the body on the toes and the soles of the feet. It is located in the shoe core area (G-G'-E'-EG) in Figure 10. The four-sided adjustment device bears all the body weights. It is theoretically calculated that the pressure on the sole of the ballet model is less than the pressure of the soles of the shoes that are 20 mm higher than the height of the heel. Actually, I feel that my foot is also stressed. The heart area bears all the body weight and feels good.

 The standard is based on the pressure value of the measuring point when the heel is 20 mm high, because it is an extreme situation to take all the body weight on one foot while walking. If the ballet toe is standing on one leg, the pressure value of the measuring point on the foot is It is smaller than the pressure value of the measuring point when most of the heel is 20 mm high. It can be seen that the device for adjusting the horizontal length of the shoe is effective for eliminating the uneven pressure distribution of the body weight on the foot. (Figure 8 in the previous paragraph is equal to Figure 30 in this article)

 From the above results, it can be seen that the use of the airbag type adjustment device can make the toes not bear the weight of the body, so that in the heel shoes, the damage to the feet when wearing the high heels can be reduced or eliminated.

 The toe method, using the ability of a four-sided airbag-type enclosure, creates a recess in the convex fill foot and fits snugly, thereby preventing the foot from moving downward within the shoe.

 The case of the airbag type adjustment device on the bottom of the toe area is inferior. The measured Τ-Γ is 23 mm in Fig. 27; the S-S' is 30 mm; the R-R' is 33 mm; the Q-Q' is 35 mm. Because the scale is 1:2, so 23*2=46; therefore 30*2=60; therefore 33*2=66; therefore 35*2=70. In Figure 27, the distance from 0 to W is vertical, between 225 and 210 = 15 between TS; 210-201 = 9 between SR; 201-190 = 11 between RQ; the area of Τ-Γ to S-S' (46 + 60) * 15/2=795; area of S-S' to R-R' (60+66) *9/2=567; area of R-R' to Q-Q' (66+70) *11/2= 748. The total area of the bottom wall is not covered (left, right, top) = 795 + 567 + 748 = 2110 square mm. Gravity = 57.5 kg *100 = 5750 units, 5750 units / 2110 square mm * 6 square mm = 16.35 units / measuring point. See Figure 30 (20 mm walking height) with only 36 (9.9 units/measuring point) and 36 (5.4 units/measuring point) with a pressure value less than 16.35 units/measuring point, so the effect is good (toe area) The area of Q-Q' to P-P' is not counted).

 Eight types and configurations of the airbag type adjustment device are available. The other seven types of airbag type adjustment devices have the same 'equivalent characteristics' as the four-sided airbag type adjustment device.

 The method of sandbag airbag is as follows: sandbag airbags arranged in the middle zone, middle zone, and shoe center area, using the shape of the foot, using the three capabilities of the sandal airbag, preventing the foot from moving forward on the shoe, and the resistance is grounded by the bearing member . The sandals airbags placed in the toe area use the equalizing ability of the sandals and airbags to eliminate the damage to the feet when wearing high heel sandals.

The sandals airbag is placed in the toe area, which is the worst when used alone, but it is good to eliminate the impact on the foot when wearing high heels (for no improvement). See Figure 31 for the total force in the toe area of 1221.5+2961.7+1485.2+ 731. 2+1392. 4+642. 1=8434. 1 unit (this value is greater than the tester's weight, with impact in it). In Figure 27, the length of Q-Q' contact with the foot is 27 mm; the length of P-P' contact with the foot is 35 mm; the height of the Q-Q' and P-P' lines is 190-178=12 mm. Since the scale of Fig. 27 is 1:2, 27*2=54 mm, 35*2=70 mm. The area is (54 + 70) * 12 / 2 = 744 square millimeters. Assuming that the thumb area is 10*20=200 mm2, the two smaller thumbs are round, 8 mm in diameter, and the area is (8/2) * (8/2) * 3. 14 * 2 = 100.48 square In millimeters, the two smallest thumbs are round, 6 mm in diameter, and the area is (6/2) * (6/2) * 3.14 * 2 = 56.52 mm 2 . The total area is 744+200+100.48+56.52=1101 square millimeters. The average pressure is 8,434. 1 unit / 1101 square mm = 7.7 units / square millimeter, 7. 7 units / square meter * 6 square millimeters / measuring point = 46. 2 units / measuring point; the value is greater than (Figure 30) There are No. 3 force/measuring point, No. 13 force value/measuring point, No. 14 force value/measuring point, and the value is less than (Fig. 30) other force values/measuring points in the toe area (shoes) The force received by the belt is not calculated).

 5. The airbag type adjusting device, the sandbag airbag and the load-bearing member are connected, and are characterized by: a coupling mode and a joint portion.

 (1) The connection mode and joint part of the airbag type adjusting device and the load-bearing member (referred to as the coupling mode and the connecting part):

 Airbag type adjustment device, sandbag airbag in four areas of connection and connection: the airbag type adjustment device or the lower part of the sandbag airbag is bonded to the upper part of the four-zone sole (leaving the shoelace passage), the airbag type adjustment device The left and right (or upper) sides are bonded to the inside of the upper of the four zones.

 (Of course, the upper and right sides of the upper can be bonded to the inner lining cloth cover; the upper of the sole is bonded to the underside of the annular inner lining, but the lace passage is required)

 Sixth, the weight-bearing method refers to: the sole weight-bearing method, the upper load-bearing method, the shoe 3⁄4 load-bearing method and the upper weight-bearing method, which are characterized by: There are three kinds of weight-bearing methods.

 The difference between the weight of a ballet or high heel and the weight of a normal sole is: This type of weight refers to the weight of the body from the heel to the toe area or the toe when wearing ballet shoes or heel shoes, instead of wearing the flat foot Pressure down to the sole of the foot. The airbag type adjustment device or the sandal bag airbag disposed in the middle area, the central area, and the shoe center area is load-bearing; the airbag type adjustment device or the sandal bag airbag disposed in the toe area is generally load-bearing.

 The classification of load-bearing methods: (1) the weight-bearing method of the sole; (2) the weight-bearing method of the upper; (3) the weight-bearing of the sole and the weight-bearing method of the upper

 (1) The sole structure of the sole load-bearing method is as follows: 1. The sole load-bearing member.

The sole load-bearing member; the elastic bottom load-bearing member comprises two elastic bottom load-bearing members and three elastic bottom load-bearing members. The elastic bottom load-bearing member has a spring bottom;

 1. The sole weight-bearing method (referred to as the sole load-bearing or sole) means that the weight of the body is borne by the sole load-bearing member. There are 1 type of load-bearing method for the sole weight-bearing method.

 (2) The upper structure of the upper load-bearing method is as follows: 1. The upper load-bearing member.

 The upper load-bearing member; the elastic-assisted load-bearing member comprises two elastic support members and three elastic support members. Elastic support load-bearing components are available, elastic help;

 2. The upper load-bearing method (referred to as the upper load-bearing or upper) means that the weight of the body is borne by the sole load-bearing member. There are 1 load-bearing methods for the upper load-bearing method.

 (Load-bearing members include sole load-bearing members and upper load-bearing members)

 (3) The sole structure and the upper structure of the sole bearing and the upper load-bearing method are as follows: 1. The sole load-bearing member and the upper load-bearing member.

 1. The sole load-bearing member and the upper load-bearing member; the elastic bottom load-bearing member and the elastic support load-bearing member bear the same weight. Elastic bottom load-bearing members and elastic support members, with elastic bottom and elastic support;

 The weight-bearing method of the sole and the weight-bearing method of the upper means that the weight of the sole is shared by the structure of the sole and the structure of the upper, and the weight-bearing method of the sole and the weight-bearing method of the upper have a load-bearing method.

 The weight-bearing methods include the sole weight-bearing method, the upper load-bearing method, the sole weight-bearing method and the upper weight-bearing method. These three types of weight-bearing methods.

 Noun description

 Elastic bottom - three elastic bottom and two elastic bottom; elastic help - three elastic support and two elastic support;

 Figure 1 A person's left foot measured in the autumn. The circumference of the ankle is 225 mm. The length of the ankle and the scale of the figure are 1:1. The curve outside the ankle is the circumference A. The curve inside the foot. It is the circumference B, left, lower * right * upper four sides, the circumference A is 239 mm, the circumference B is 213 mm, and the horizontal adjustment range is 26 mm and the thickness is 4 mm.

 Figure 2: A person's left foot in the autumn measured the surrounding area, the circumference of the ankle is 243 mm, the length of the ankle and the scale of the figure is 1: 1, the curve outside the ankle is the circumference A, the curve inside the foot It is the circumference B, left, lower, right * upper four sides, the circumference A is 254 mm, the circumference B is 243 mm, and the horizontal adjustment range is 22 mm and the thickness is 4 mm.

Figure 3, "Handbook of Practical Mathematics in Middle School", Cao Bin, Li Wannian, 26 pages. "Fig. 3 · 3 · 11" Figure 4 The structure of the high-heeled heel pumping mechanism: 1 is the upper part corresponding to the piston barrel, 2 is the lower part equivalent to the piston, 3 is a return spring, 4 is a fixed steel piece, the figure is in a normal use state (non-energized state), and the fixed steel piece 4 passes through the upper piston barrel 1 and the lower piston 2, so that the lower piston 2 cannot move. 5 is the air inlet, 6 is the air outlet, leading to the valve switch. When pumping, the fixed steel sheet 4 is pulled out to the right, and the lower piston 2 can be pumped up and down. The upper piston barrel 1 and the lower piston 2 are the heels of the high heels.

 Figure 5 is a plot of the left foot of a person in the fall. The circumference of the ankle is 225 mm. The length of the ankle is 1 : 1. The curve outside the ankle is the circumference A. The curve is the circle B. The curve outside and outside the ankle is drawn according to the drawing method of Fig. 6. The difference is that since it is left*low*right three sides, P1 is selected in the upper left corner, Px Click on the upper right corner, Po point is selected to move to the right in the upper left corner by a few millimeters or tens of millimeters (according to the actual right shift), Px+1 is selected to move to the left in the upper right corner by a few millimeters or tens of millimeters (according to the actual left) How much to move). Measured in Figure 5, the perimeter of the perimeter A, the perimeter of the perimeter A is 235 mm, the measured perimeter of the perimeter B in Figure 5, the transverse length of the perimeter B is 207 mm, the circumference of the perimeter A minus the circumference B. The horizontal circumference of the circumference is adjusted to a length of 28 mm, which corresponds to four standard 'width' lining thicknesses of 5 mm.

 In Figure 6, the circumference A is the width of the circumference of the circumference A is 240 mm. In the actual picture 6, the circumference B is 214 mm, and the circumference A is minus 跖 circumference B. The adjustment range of the length of the raft is 26 mm, which is equivalent to 3 semi-standard 'width'. The lining is 5 mm thick.

 Figure 7 is a measured view of the left foot of a person (the middle of the approximate circle). The measured circumference is 243 mm. The scale of the ankle and the figure is 1:1. The curve outside the ankle is 跗Around A, the curve inside the ankle is the circumference B. Figure 7 is drawn according to the drawing method of Figure 6. The difference is that the picture is the circumference instead of the circumference. , 横 A A's transverse length is 260 mm; measured in Figure 7 跗 ^ 跗 B B B B B B 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 234 The thickness of the three multi-standard 'width' linings is 4 mm.

 Figure 8 is a measured view of the left foot of a person (the middle of the approximate circle). The measured circumference is 243 mm. The scale of the ankle and the figure is 1:1. The curve outside the ankle is 跗Around A, the curve inside the ankle is the circumference B. Figure 8 is drawn according to the drawing method of Figure 6. The difference is that the picture is the circumference instead of the circumference. , 横 A A's transverse length is 296 mm; measured in Figure 8 跗 B B, 跗 B B transverse length 271 mm, 跗 A A minus 跗 B B B 跗 跗 跗 跗 调节 调节 调节 调节 调节 调节 调节 调节 调节 调节, equivalent to three multi-standard 'width' linings with a thickness of 5 mm.

Figure 9 is the horizontal cross-section of a person's left foot in the autumn (the closed elliptical line in the middle). The measured cross-length is 225 mm, and the scale of the ankle and the figure is 1:1. The outer curve is the circle A, the curve inside the ankle is the circle B, and the figure 9 is drawn according to the drawing method of Fig. 6. The difference is that since it is the upper * left * the lower three sides, the P1 Click on the upper right corner, Px is selected in the lower right corner, and Po point is selected to move down a few millimeters to tens of millimeters in the upper right corner. How much is moved down?) Px+l is selected to move up to several tens of millimeters in the lower right corner (according to the actual movement). The measured circumference is 4, and the circumference of the circumference A is 250 mm. In Figure 9, the circumference B is 208 mm. The circumference of the circumference is reduced by 208 mm. The length of the circumference of the circumference is reduced by the length of the circumference of the circumference. The adjustment range of the circumference of the circumference is 0 to 42 mm, equivalent to 6 standard 'width', with a lining thickness of 8 mm.

 Figure 10: The measured area of the left foot of a person in the autumn (the closed ellipse in the middle). The measured circumference is 2 mm, and the scale of the ankle and the scale of Figure 10 is 1:1. It is the circumference, the curve inside the ankle is the circumference, and Figure 10 is drawn according to the drawing method of Figure 6. The difference is that because it is upper * right and lower three sides, P1 is selected in the lower left corner. Px is selected in the upper left corner, Po point is selected to move upwards in the lower left corner by a few millimeters to tens of millimeters (according to how much is actually moved), Ρχ+l is selected to move down a few millimeters to tens of millimeters in the upper left corner (according to the actual How much to move), measured in Figure 10, the circumference of the 跖 Α 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 233 The length of the 跖B is reduced by the length of the circumference of the 跖B. The adjustment range of the circumference of the 跖B is 0 to 26 mm, which is equivalent to 3 semi-standard 'width' and the lining thickness is 6 mm.

 Figure 11 is a measured view of the left foot of a person (the middle of the approximate circle). The measured circumference is 243 mm, and the scale of the ankle and the figure is 1:1. The curve outside the ankle is 跗In the circumference A, the curve inside the ankle is the circumference B, and the figure 8 is drawn according to the drawing method of Fig. 6. The difference is that the drawing is the circumference instead of the circumference, and the measurement of the circumference A in Fig. 11 , 横 A A's transverse length is 252 mm; measured 图 B 图 图 图 图 实 实 实 实 实 实 实 实 实 实 实 图 图 217 217 217 217 217 217 217 217 217 217 217 217 217 217 217 217 217 217 217 217 217 217 217 217 217 217 217 217 217 Equivalent to five standard 'width' linings with a thickness of 5 mm.

 Figure 12 is a measured map of the left foot of a person (the middle of the approximate circle). The measured circumference is 243 mm. The scale of the ankle and the figure is 1:1. The curve outside the ankle is 跗Around, the curve inside the ankle is the circumference B, and the figure 12 is drawn according to the drawing method of Fig. 6. The difference is that the drawing is the circumference instead of the circumference, and the circumference A in Fig. 12 is actually measured. The circumference of the perimeter A is 252 mm; the measurement of the perimeter B in Figure 12, the circumference of the perimeter B is 220 mm, and the circumference of the enclosure A minus the perimeter of the enclosure B is 32 mm. The thickness of the four multi-standard 'width' linings is 5 mm.

Figure 13 is a plot of the measured area of the person in the fall (the approximate elliptical line in the middle). The measured transverse length is 225 mm, and the scale of the ankle circumference and the circumference of the figure is 1:1. Figure 13 is drawn according to the method of Figure 9, except that Figure 13 lacks the left side of the circumference, only the upper and lower sides, so there are two sets of upper and lower curve segments, the upper curve section uses Pl. Px Po. Px+1 four symbols, the lower curve segment uses PLl. PLx. Po. PLx+1 four symbols, drawn in a counterclockwise direction. In the curve of the upper group, the curve outside the ankle is the circumference A, and the curve inside the ankle is the circumference B. In the curve of the lower group, the curve outside the ankle is the circumference C, and the curve inside the ankle is the circumference. D, measured the circumference of the circumference A is 119 mm, measured The circumference of the perimeter B is 108 mm. The measured length of the perimeter is 121 mm. The measured length of the perimeter D is 106 mm. The adjustment range of the transverse length is 0 to 26 mm, which is equivalent to more than three and a half. Standard 'width, lining thickness is 9 mm.

 Figure 14 is a plot of the measured area of the person in the fall (the approximate elliptical line in the middle). The measured transverse length is 225 mm, and the scale of the ankle circumference and the circumference of the figure is 1:1. Figure 14 is drawn according to the method of Figure 5, the difference is that Figure 14 lacks the lower side of the face, only the left and right sides, so there are two sets of left and right curve segments, the left curve segment uses Pl. Px Po. Px+1 four symbols, the right curve segment uses PLl. PLx. Po. PLx+1 four symbols, drawn in a counterclockwise direction. In the curve of the left group, the curve outside the ankle is the circumference A, and the curve inside the ankle is the circumference B. The curve outside the ankle in the right curve is the circumference C, and the curve inside the ankle is the circumference. D, the measured circumference A is 72 mm in length, the measured circumference B is 48 mm in length, and the measured circumference is 58 mm in length. The measured circumference D is 34 mm in length. The adjustment range is from 0 to 48 mm, which is equivalent to six and a half standard 'width' and the inner lining thickness is 9 mm.

 Figure 15 is the measured map of a person's fall in the autumn (the middle of the approximate circle). The measured cross-length is 243 mm, and the scale of the ankle and the circle in the figure is 1:1. Fig. 15 is drawn in accordance with the method of Fig. 13, except that the object to be drawn is a circle instead of a circle, and is drawn counterclockwise. In the curve of the upper group, the curve outside the ankle is the circumference A, and the curve inside the ankle is the circumference B. In the curve of the lower group, the curve outside the ankle is the circumference C, and the curve inside the ankle is the circumference. D, the measured circumference A is 95 mm in length, the measured circumference B is 75 mm in length, and the measured circumference is 47 mm in length. The measured circumference D is 32 mm in length and the length is 32 mm. The adjustment range is 0 to 35 mm, which is equivalent to five standard 'widths' and the inner liner is 9 mm thick.

 Figure 16 is the measured map of a person's fall in autumn (the middle of the approximate circle). The measured cross-section is 225 mm long, and the scale of the ankle and the circle in the figure is 1:1. Fig. 16 is drawn in accordance with the method of Fig. 14, except that the object to be drawn is a circle instead of a circle, and is drawn counterclockwise. In the curve of the right group, the curve outside the ankle is the circumference A, and the curve inside the ankle is the circumference B. In the left curve, the curve outside the ankle is the circumference C, and the curve inside the ankle is the circumference. D, the measured circumference A is 85 mm in length, and the measured circumference B is 61 mm in length. The measured circumference C is 44 mm in length. The measured circumference D is 26 mm in length. The adjustment range is 0 to 42 mm, which is equivalent to six standard 'width' and the inner liner thickness is 9 mm.

Figure 17 is a plot of the measured area of the person in the autumn (the approximate elliptical line in the middle). The measured transverse length is 225 mm, and the scale of the ankle circumference and the circumference of the figure is 1:1. The curve outside the ankle is the circumference A, and the curve inside the ankle is the circumference B. Figure 17 is drawn according to the drawing method of Figure 5, except that it is the left and the lower two sides. Less on the right side. The measured circumference A has a transverse length of 244 mm, the measured circumference B has a transverse length of 210 mm, the transverse circumference has a length adjustment range of 0 to 34 mm, and the inner lining has a thickness of 9 mm. Figure 18 is a plot of the measured area of the person in the fall (the approximate elliptical line in the middle). The measured transverse length is 225 mm, and the scale of the ankle circumference and the circumference of the figure is 1:1. The curve outside the ankle is the 跖 Α, the curve inside the ankle is the 跖 Β, Figure 18 is drawn according to the drawing method of Figure 6, the difference is that because it is the right side, the upper side, The side of the right side is missing. The actual length of the weir is about 250 mm. The measured length of the B is 211 mm. The length of the weir is about 0 to 39 mm and the thickness of the lining is 9 mm.

 Figure 19 is the measured map of the person's fall in the autumn (the middle of the approximate circle). The measured cross-section is 243 mm, and the scale of the ankle and the circle in the figure is 1:1. The curve outside the ankle is the circumference A, the curve inside the ankle is the circumference B, and the figure 19 is drawn according to the drawing method of Fig. 17, both of which are left and the next two sides, the difference is that The object of the painting is the circumference rather than the circumference. The measured circumference A has a transverse length of 260 mm, and the measured circumference B has a transverse length of 225 mm. The lateral length of the crucible is adjustable from 0 to 35 mm, which is equivalent to five standard 'widths' and the inner lining thickness is 8 mm.

 Figure 20 is the measured map of the person's fall in the autumn (the middle of the approximate circle). The measured cross-length is 243 mm, and the scale of the ankle and the circumference of the figure is 1:1. The curve outside the ankle is the circumference A, the curve inside the ankle is the circumference B, and the figure 20 is drawn according to the drawing method of Fig. 18, both of which are right and upper two sides, the difference is that The object of the painting is the circumference rather than the circumference. The measured circumference A is 258 mm in length, the measured circumference B is 231 mm in length, and the lateral circumference is adjusted to 0 to 27 mm, which is equivalent to three and a half standard 'width', and the thickness of the lining is 8. Millimeter.

 Figure 21 is the measured map of a person's fall in the middle (the approximate elliptical line in the middle). The measured transverse length is 225 mm, and the scale of the ankle circumference and the circumference of the figure is 1:1. The curve outside the ankle is the circumference A, the curve inside the ankle is the circumference B, and the figure 21 is drawn according to the drawing method of Fig. 9, the difference is that since it is the upper left side, The side of the right side is missing. The measured circumference A has a transverse length of 242 mm, the measured circumference B has a transverse length of 212 mm, the transverse circumference is adjusted to a range of 0 to 30 mm, and the inner lining is 8 mm.

 Figure 22 shows the measured area of the person in the fall (the approximate elliptical line in the middle). The measured transverse length is 225 mm, and the scale of the ankle circumference and the circumference of the figure is 1:1. The curve outside the ankle is the circumference A, the curve inside the circumference is the circumference B, and the figure 22 is drawn according to the drawing method of Fig. 10, except that it is the lower right side and the right side. The side of the upper side. The measured circumference A has a transverse length of 240 mm, the measured circumference B has a transverse length of 207 mm, the transverse circumference has a length adjustment range of 0 to 33 mm, and the inner lining has a thickness of 9 mm.

Figure 23 is a plot of the measured area of the person in the autumn (the middle of the approximate circle). The measured transverse length is 243 mm, and the scale of the ankle circumference and the circumference of the figure is 1:1. The curve outside the ankle is the circumference A, the curve inside the ankle is the circumference B, and the figure 23 is drawn according to the drawing method of Fig. 21, both upper and left sides, the difference is that The object of the painting is the circumference rather than the circumference. The measured circumference A is 257 mm in length, and the measured circumference B is 233 mm in length. The circumference adjustment range is 0 to 24 mm, which is equivalent to three multi-standard 'widths, and the inner liner thickness is 8 mm.

 Figure 24 is the measured map of a person's fall in autumn (the middle of the approximate circle). The measured cross-section is 243 mm, and the scale of the ankle and the circumference of the figure is 1:1. The curve outside the ankle is the circumference A, the curve inside the ankle is the circumference B, and the figure 24 is drawn according to the drawing method of Fig. 22, both the lower and the right two sides, the difference is that The object of the painting is the circumference rather than the circumference. The measured circumference A is 273 mm in length, and the measured circumference B is 246 mm in length. The adjustment range of the transverse length is 0 to 27 mm, which is equivalent to three and a half standard 'width', and the thickness of the lining is 8. Millimeter.

 Figure 25, "Chinese shoe size and shoe last design", Institute of Light Industry, Institute of Footwear Industry, 97 pages.... "Table 4-2 (1) The distribution of the force value of the woman's measuring point is 20 mm high and the standing unit is 0.01 kg". The total value in the figure is the total measured value of the right foot when standing still.

 Figure 26, "Chinese shoe size and shoe last design", Institute of Light Industry, Shoe Industry Institute, 99 pages ...... "form

4-2 (7) Distribution of force values of women's measuring points Height 80 mm State Standing unit 0.01 kg" Both Figure 26 The total value of the figure is the total measured value of the right foot when standing still.

 Figure 27, "Chinese shoe size and shoe last design", Institute of Light Industry, Institute of Footwear Industry, 100 pages .... Figure 4-14 (1) The distribution curve of the latitudinal force value of the female foot surface is 20 mm high and the static unit is 0.01 kg".

 Figure 28, "Chinese shoe size and shoe last design", Institute of Light Industry, Shoe Industry Institute, p. 102. "Fig. 4-14 (7) Distribution curve of latitudinal force value of women's foot palm with 髙 80 mm state static unit 0.01 kg ' irrigation Fig. 28.

 Figure 29, "Chinese shoe size and shoe last design", Institute of Light Industry, Institute of Footwear Industry, 118 pages ...... "Fig. 4-23 (7) The distribution curve of the latitudinal force value of the female foot surface is 80 mm in height and the walking unit is 0.01 kg".

 Figure 30, "Chinese shoe size and shoe last design", Institute of Light Industry, Institute of Footwear Industry, 114 pages ...... "Form 4-8 (1) The distribution of the force value of the woman's measuring point is 0.01 kg with the walking unit of the height of 20 mm". Figure 30; Figure 31, "Design of Chinese shoe size and shoe last". 116 pages... "Table 4-8 (7) Distribution of force values of women's measuring points with a height of 80 mm and a walking unit of 0.01 kg" is shown in Figure 31; Figure 32 see "Chinese shoe size and shoe last design". 117 pages... "Figure 4-23

( 1 ) The distribution curve of the latitudinal force value of the female foot surface is 20 mm higher than the walking unit of 0.01 kg " both figure 32 ;

Figure 33 is a concrete implementation of Figure 1, a sandal bag; 2, a valve; 3, a mounting plate; 4, a shoe buckle; 5, a sole. Example

 7. The embodiment of the airbag type adjustment device arranged in the four zones and the load-bearing mode and the seven sandbag airbag embodiments are characterized in that: 88 types are arranged in the central zone, the central zone, the shoe core zone, and the toe zone. The airbag type adjustment device is combined with three kinds of load-bearing methods (single action, combined action) to produce 3672 embodiments and seven sandbag airbag embodiments. A total of 3,679, the implementation includes separate action embodiments and combined action embodiments.

 Separate action embodiment (one of the 24 available airbag style adjustment devices in the Central or Central Zone or the shoe core zone, resulting in a specific implementation, referred to as a separate action implementation.)

 In the central area, 24 airbag-type adjustment devices can be combined with three load-bearing methods to produce 72 separate action implementations.

 In the central area, 24 airbag-type adjustment devices can be combined with three load-bearing methods to produce 72 separate action plans.

 In the shoe core area, 24 airbag-type adjustment devices can be combined with three load-bearing methods to produce 72 separate action implementations.

 [1] Individual action (1) Central area 24 kinds *3=72 types.

 (2) 24 types in the central area *3=72 species.

 (3) Heart area 24 types *3=72 types.

 There are a total of 216 implementations for the single-acting embodiment (the toe area, the 4 available configurations, and the 8 available types, the available structure of the airbag type tuning device cannot be used alone).

 Combination of specific embodiments (one type and three types of airbag type adjustment devices of one type of eleven types of airbag type adjustment devices in the middle or middle area or the center of the shoe area) The specific implementation scheme of the load-bearing method in the load-bearing mode is called the combined action implementation.

 In the central area, there are 24 kinds of airbag type adjustment devices and 16 kinds of airbag type adjustment devices in the toe area, which can cooperate with three kinds of load-bearing methods to generate 1,152 different combinations.

 In the central area, there are 24 kinds of airbag-type adjustment devices and 16 kinds of airbag-type adjustment devices in the toe area, which can be combined with three kinds of load-bearing methods to generate 1,152 different combinations.

 In the shoe core area, there are 24 kinds of airbag type adjustment devices and 16 kinds of airbag type adjustment devices in the toe area, which can cooperate with three kinds of load-bearing modes, and can generate 1,152 different combined action embodiments.

 [2] Combination

(1) 16 kinds of toe area and 24 kinds of middle area, 3 kinds of weight-bearing methods, 16*24*3=1152 kinds; (2) 16 kinds of toe area and 24 kinds of middle area, 3 kinds of weight-bearing methods, 16*24*3=1152 kinds;

 (3) 16 kinds of toe area and 24 kinds of shoe heart area, 3 kinds of load-bearing methods, 16*24*3=1152 kinds; There are 3456 kinds of implementation schemes for combined action schemes (8 kinds of inner/gas and 8 kinds of non-leakage in toe area) The inner sleeve has an 'equivalent feature' and there are 16 available types and available structures; shell/inner/gas and shell/gas, not used).

 [3] A total of 72 kinds of effects and combinations alone *3+1152 kinds *3=3672 kinds

 VIII. The airbag type adjustment device, the sandal airbag and the weight-bearing method have the 'equivalent feature' scheme and components, and are characterized by: 16 kinds of airbag type adjustment devices, sandbag airbags and load-bearing modes, which have 'equivalent characteristics', component.

 See the Patent Law and its supporting regulations. Page 49 “Several Provisions of the Supreme People's Court on the Application of Legal Issues in the Trial of Patent Dispute Cases” (June 19, 2001, the 1180th meeting of the Judicial Committee of the Supreme People's Court passed the Interpretation [2001] No. 21). 52 pages... Article 17 The scope of protection of the invention or utility model patent right referred to in the first paragraph of Article 56 of the Patent Law shall be subject to the contents of its claims, and the specification and drawings may be used to explain the claims. The scope of protection of a patent right shall be determined by the scope determined by the necessary technical features clearly stated in the claims, and also the range determined by the features equivalent to the necessary technical features.

 Equivalent features refer to substantially the same function as the described technical features. A substantially identical function is achieved. Substantially the same effect is achieved, and a person of ordinary skill in the art will be able to ascertain the features without the inventive work. ,,

 1. 56,304 kinds of embodiments and lining cloth sleeves (made of stainless steel mesh cloth) The test model of the four-sided surrounding airbag (the latter is closed on a stainless steel sheet bent into a barrel type) has an 'equivalent characteristic'. I personally understand that "Implementing basically the same function. Achieving basically the same effect" means: having the function and effect of not taking all or most of the body weight by the foot.

 2, hard sole or plate bracket (plate bracket refers to the elastic and can bear the weight of the hook) and the elastic sole has 'equal characteristics'.

 3. Hard-shoe uppers or U-shaped brackets (U-shaped brackets are U-shaped brackets that are elastic and load-bearing, similar to the model-shaped aluminum alloy). They have an 'equivalent feature' with the elastic upper.

 4, buckle belt and shoelace have 'equivalent characteristics'.

 5. Making an airbag type adjusting device and an annular inner lining cloth sleeve and an annular air bag with a non-stretchable material by using a ring-shaped inner lining cloth sleeve which has no air leakage or processing, and has a non-leakable and non-stretchable material; The airbag type tuning device made of a cloth airbag or the like has an 'equivalent feature'.

6. The connection method of ballet shoes and the connection mode of high heels have 'equivalent characteristics'. 7. In the toe area, 8 types and configurations of the airbag type adjusting device 12 are available, and the other 7 types of air bag type adjusting devices have the same 'equivalent characteristics' as the four-sided air bag type adjusting device.

 8. In the Central, Central, and Shoe areas, 11 types and configurations of the 12 types of airbag type adjustment devices are available. The other 10 types of adjustment devices and the four-sided air bag type adjustment device have 'equivalent characteristics'.

 9. The load-bearing steel wire can be replaced by various filaments or fibers with a tensile strength greater than 56 kg.

10, stainless steel screen cloth (non-stretchable material) and nylon cloth, plastic cloth, silk cloth, fiber cloth, carbon fiber cloth, glass fiber cloth, metal cloth, leather, tire cloth have 'equivalent characteristics'.

 11. Rubber (stretchable elastic material) and 'styrene block copolymer; 2. Polyurethane or polyether ester block copolymer; 3. Polyolefin blend and thermoplastic vulcanizate. '(See "Thermoplastic elastomer" [United States] G. Holden, N.R. Legge, et al., p. 604) has 'equivalent features'.

 12, airbag clip stainless steel screen cloth (non-stretchable material) to make airbag type adjustment device and airbag type adjustment device made of annular inner lining cloth sleeve and annular airbag with non-stretchable material, having 'equivalent characteristics' . (The airbag clamp is not like a tire casing.)

 13. Metal rings, plastic rings and cloth rings have 'equivalent characteristics'.

 14. The weight-bearing method of ballet shoes and the weight-bearing method of high-heeled shoes have 'equivalent characteristics'.

 15. The general features of the sandal airbag and the general features of the airbag style tuning device have 'equivalent features'.

 16. The connection method of ballet shoes and the connection method of high heels have 'equivalent characteristics'.

Claims

Spur demand

1. The structure, type and structure of a bladder type enclosure;

 - available structure / type / knot of the air bag type adjustment device;

 - the composition and available structure / type / knot of the sandal airbag;

 - the ability and method of the airbag type adjustment device and the difference in the ability and method of the airbag airbag;

 - the connection of the airbag type adjusting device, the sandal bag airbag and the load bearing member;

 - The weight-bearing method refers to: the weight-bearing method of the sole, the weight-bearing method of the upper, the weight-bearing method of the sole, and the weight-bearing method of the upper;

- an embodiment of the airbag type adjustment device arranged in the four zones combined with the load-bearing mode and seven airbag airbag embodiments;

 - The airbag type adjustment device, the sandal bag and the load-bearing method have the 'equivalent feature' scheme and components.

 The construction, type and structure of the airbag type aligning device according to claim 1, characterized in that: five configurations, twelve types and structures, are arranged in four zones.

 3. The available structure/category/junction of the airbag type aligning device of claim 1 wherein: 88 available structures/classes/junctions.

 4. The construction and usable structure/junction of the sandal airbag of claim 1 wherein: the sandal airbag is a special bottom airbag type enclosure and has four available configurations/categories/junctions.

 5. The capability and method of the airbag type aligning device of claim 1 and the capability and method of the airbag airbag, characterized in that: the airbag type aligning device has three standard widths/stepless, equalizing pressure, filling space, Two large and small abilities and sandals airbags lack the capacity of three standard widths/steplessness; the method has a middle area method; the middle method; the shoe heart method and the toe method.

 6. The coupling of the airbag type aligning device and the load-bearing member according to claim 1, characterized by: a coupling mode and a joint portion.

 7. The load-bearing method according to claim 1 is: the sole weight-bearing method, the upper weight-bearing method, the sole weight-bearing method, and the upper weight-bearing method, and the following features: There are three types of weight-bearing methods.

8. The embodiment of the four-zone airbag type tuning device according to claim 1 and the load-bearing manner, and seven sandbag airbag embodiments, characterized in that: arranged in the middle zone, the central zone, the shoe core zone, The 88 airbag type adjustment devices in the toe area were combined with the three load-bearing methods (single action, combined action) to produce 3,672 implementations and seven sandbag airbag implementations, with a total of 3,679 implementations.

9. The airbag type arranging device according to claim 1 and the solution and component having the 'equivalent feature' in the load-bearing mode, characterized in that: the airbag type aligning device and the 16 types of components having the 'equivalent feature' in the load-bearing mode .