JPS5899958A - Pneumatic massager and mat therefore - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention]

Pneumatic pine surge machines that use compressed air are known, but in pine surge machines that perform pneumatic pine surge while supine or prone, the central part of the air bag, which expands and contracts by supplying and discharging compressed air, is located at the periphery. Because the body swells more than the other parts and becomes round as a whole, it has the disadvantage that the body stabilizes quickly. As shown, the disadvantage is that the spinal cord is excessively compressed along the center line of the body, that is, between the pillars and the spinal cord, which actually impairs the pine surge effect. Another disadvantage is that because the central part swells greatly, sufficient air pressure is not applied to areas that require massage, such as both sides of the dorsal column where there are many acupuncture points, making it impossible to obtain an appropriate massage effect. was there. −
The sheets and mats used in such pneumatic pine surge devices usually have one air-filled chamber, but even if they have multiple air-filled chambers, the way each air-filled chamber is inflated as described above will cause the sheet or mat to lie prone. The actual situation was that the pine surge effect could not be obtained at all, and even when used in the supine state, the effect was only that of stretching the waist. In view of the fact that the pneumatic pine surger and the cloak and cloak used therefor which have already been developed have the above-mentioned drawbacks, the present invention solves these inconveniences and improves both legs, lower back,
Pneumatic pine surge device and air pressure developed with the aim of delivering an extremely soft and precise pine surge effect to the entire body, including the back, neck, lower abdomen, and chest. The pneumatic pine surge device of the present invention relates to a pine surge cloak, and the present invention will be explained below based on the embodiments shown in the drawings. An air supply tube 2 for supplying and discharging compressed air into the bag of the mat) and the cloak, and an air supply tube 3 for the pressure section connecting the mat 1 and the air supply source 2. No. 3
The mat 1 is constructed as follows so that it can be used with either the front or back side facing upward. FIG. 1 is a plan view showing a first example of the mat 1, and FIG. 4 is a longitudinal cross-sectional view of the mat taken along the line A- in FIG.
As is clearly shown in Figure 4, a bag is made of two elastic airtight materials 4.4 on the front and back sides, and outer covering materials 5, 5 that have flexibility but no or a slight amount of extensibility. As shown in Fig. 1.4, the pneumatic flat bag has four independent rectangular air-filled chambers 1a, lb, and lc. , ld, in this example, the second air-filled chamber ]b is the largest, followed by the third air-filled room lc, and the fourth valley air-filled chamber 1a and ld. is formed slightly smaller than the third air-filled chamber]C. Reference numeral 6 indicates an airtight ring defining the air-filled chambers 1a, lb, lc, and ld, and 7 indicates an airtight seal symmetrically joining the front and back sides to narrow the air flow path 8 near the center of the chamber IC~d in the long side direction. In the embodiment shown in FIG. 1, a /-le is applied to the chevron, and adjacent, for example, the first . Second air-filled chamber 1
Between a and lb, a diamond shape is formed by the /-ru points 7.7 on both sides. Compared to this, the swelling is less. Figures 2 and 3 show the air-filled chamber 1a I lbl]c
, ld is a vertical cross-sectional view showing compressed air supply and exhaust ports 9 and 10 that are horizontally protruding from the side surfaces of the air conditioners 1 and 1. The latter 10 is a check valve 11 provided only in the second air-filled chamber 1b having the largest volume. In the filling chamber 1b, compressed air first enters from the air supply port 10, then compressed air enters from the supply and exhaust port 9, and while air is being supplied to the supply and exhaust port 9, the compressed air enters from the air supply port 10. The air is not exhausted from 101jl11. Fig. 5 A second example of the mat 1 in which five air-filled chambers 18 to 1e are defined by the point 6.7, and all the chambers are formed to have the same size. Reverse 1)-
Only the supply/exhaust port 9 without the square 11 is provided to protrude sideways as in the first example. FIG. 6 shows a third example in which a plurality of eyelets 12... are formed at both longitudinal ends of the mat 1 of the first example.
2 is attached to connect two cloaks 1.1 with a string 13 as shown in Fig. 7. If a connecting piece other than the string 13 is used, it will not cause pain even if it hits the body. Needless to say, things are preferable. One example of this is a velvet type fastener in which countless steel hooks and transport piles form a pair, and when such a fastener is used, reinforcement such as the eyelet 12 is not required. In addition, in FIG. 8, button holes 14 and 14 are formed at both longitudinal ends of the mat 1 of the first example so that it can be attached to the seat or back of a chair. This is a fourth example in which a constant radius is made possible by using stretchable tape with a button attached to the part, a thread, or a string (none of which are shown). Of course, in this case as well, you can attach it to the chair using a bell-bent Hudesner.
Allows for free removal. Fig. 9 A, B, C, D, E, F are airtightly sealed 7 in the medium heat part in the long side direction in a shape different from that shown in Fig. 9 A, B, C, D, E, F.
Six ways are shown in which the air-filled chambers 10 to 1d are formed. FIG. 9A shows an example in which the sealing portion 7 that narrows the air flow wjS is formed into a semicircular shape, and FIG. Figure 9C shows an example of a circular shape, Figure 9C shows an example of an isosceles triangle with an apex angle of 90 degrees, Figure 9 shows an example of a U-shape, and Figure 9E shows a gentler slope. An example of a roof-shaped structure is shown. In addition, Fig. 9F shows an example in which, in addition to the airtight seal 6 that defines the air-filled chambers 1a to 1d, four parts (7... However, the mat 1 shown in FIGS.
The air-filled chambers 1a and ld are the same size and the smallest, and the third chamber 1c. Since the second chamber lb is formed larger in order, the air flow path 8 is narrowed in the order of the first chamber lb. Only the fourth chambers 1a and 1d are the same and the narrowest, and the other air passages 8 are formed with different widths taking into consideration the capacity of the air-filled chambers 1b and lc. For example, in FIG. 9A, The radius of the semicircular seal 7 that narrows the air flow path 8 in the central part of the second chamber lb is the largest, and the third chamber 1c,
The radius is made smaller in the order of the first chamber 1a. Therefore, the fourth
The radius of the semicircle/'-lua in chamber ld is equal to the first chamber ]a. Next, FIGS. 10 and 11 show the air-filled chambers la, l.
While b, lc, and ld are formed into rectangles,
This figure shows cloaks formed in a chevron shape and an arc shape, respectively, and each air-filled chamber 1a, lb, ]c. Whether to make the size of 1d the same or change the casing height, and what shape the seal 7 in the center part should be, can be determined by following the previous example. Form. Figure 12 shows the rectangular air-filled chambers 1a to d shown in Figure 1.
In the fifth example, the chevron-shaped air-filled chambers 1a to 1d shown in FIG.
N-pressure air is simultaneously supplied to irregularly shaped air-filled chambers in the same order that partially overlap one another. FIG. 13 also shows an example in which two air-tight bags with different shapes of air-filled chambers 9 are stacked, and an arc-shaped air-filled chamber 1 a - shown in FIG. 11 is placed on top of a long, rectangular air-filled chamber. 1d. Therefore, when compressed air is supplied and exhausted to the mat shown in FIGS. 12 and 13, it becomes a mat that repeatedly expands and contracts in an extremely complicated manner. The above Matsu) 1 was formed by integrally sealing the component material 4.5 airtightly 6.7, but the material 4.4 was used to form an airtight flat bag in advance, and a plurality of air-filled chambers were formed. The formed material may be covered with a flat outer bag made of material 5.5. Also, FIGS. 1, 6, 8, and 9A-F. In the embodiment shown in FIGS. 10 to 13, the interior of the mat is partitioned into four air chambers 7^la, lb, lc, and 1d for the compressed air supply #! described below. 2. Because we adopted a 4-air distribution system, the number of rooms can be increased to 5, 6, or 7 as shown in Figure 5, depending on the number of air distributions. Distributor style air supply #! 2, as shown in Fig. wJ7, two four-chambers may be connected and used, or an attachment 15 as shown in Figs. 28 and 29, which will be described later, may be used.
By using , the air can be divided into 8 multiples, so it can also be used as shown in Figure 30. Next, details of the air supply m, 2 will be explained with reference to FIGS. 14 to 29. In FIG. 15, reference numeral 16 denotes a first example of a compressor. This compressor 16 is an electromagnetic type that reciprocates a piston 18 by repeating excitation and demagnetization of an electromagnet 17, and generates compressed air by one reciprocation of the Vinton 18. The electromagnetic reciprocating compressor 16 in the illustrated example has an electromagnet [7] fixed to the compressor frame 19, and when the iron core 20 is attracted by the electromagnet 17, the electromagnet 17 moves to the left in FIG. When coil spring 2 is demagnetized,
A piston 18 that returns to its original position with an elastic force of 1, a compression chamber 2
2. It is composed of an inlet 24 with an inlet valve 23, an outlet 26 with an outlet valve 25, etc., and the electromagnet 17 is connected to an alternating current source via a diode. In FIG. 16, 27 is a pressure@air distributor, the details of which will be explained with reference to the same figure and FIGS. 18 to 25. Reference numeral 28 denotes a synchro motor installed within the main body of the air supply source 2, and a rotating plate 31 having a locking portion 30 is fixed to the drive shaft 29 of this motor 28. Reference numeral 32 denotes a cylindrical rotating member having a smooth surface 33 on the upper surface, and a cutout groove 34 formed in the rotating member 32 is provided in the above-mentioned manner. Communication groove 35
is formed. Reference numeral 36 denotes an exhaust hole formed in the rotating member 32, which is formed to have a small diameter in order to provide a certain amount of resistance to exhaust air. The exhaust holes 36 are provided so as to communicate with the air supply and exhaust holes 38a to 38d of the fixed member 37, respectively. The fixing member 37 is fixed to a frame 39 to which the synchro motor 281c is attached, and a smooth surface 40 is formed on the lower surface of the fixing member 37. 41 is formed, and this air supply hole 42 is connected to a flow rate adjustment valve 43 (described later) to control the discharge 026 of the compressor 16.
It communicates with Note that the upper surface of the fixing member 37 and the 'P smooth surface 4
The air supply/exhaust holes 38a to 38d that communicate with
5 and the exhaust hole 36 in sequence. Reference numeral 44 denotes a compression spring whose upper end is attached to the inside of the rotating member 32 and whose lower end is attached to the rotating plate 31. The elastic force of this compression spring 44 causes the smooth surface 33 of the rotating member 32 to move against the smooth surface 4 of the fixed member 37.
0, the rotating member 32 is pressed against the smooth surface 4 of the fixed member 37.
It is provided so that it can actively rotate in an airtight manner with respect to 0. Reference numeral 45 denotes a socket equipped with sliding tuner connection ports 458 to 45d that communicate with the air supply and exhaust holes 388 to 38d, and connects each air-filled chamber 18 to 1d of the pine surge mat 1 and the air supply and exhaust holes 38a to 38a to 38d.
This is for connecting the base of the air supply/exhaust tube 30 that communicates with the air supply/exhaust tube 8d. Figures 26 and 27 are part 1 of welfare J4 adjustment loop 43.
In the example shown, 46 is a flow adjustment knob that is manually rotated, and this knob 46 is provided with an adjustment rod 47 that hangs down from its lower surface, and the portion where the adjustment rod 47 is connected to the knob 46 is provided. A male thread 48 is formed on the adjustment rod 47, and a pressing portion 49 is attached to the lower end of the adjustment rod 47. This valve 43 mainly consists of an upper valve case 50 and a lower valve case 51, and a diaphragm 520 peripheral portion is fixed between the valve cases 50 and 51. A female screw 53 is provided on the upper part of the upper valve box 50, and the male screw 48 is screwed into the female screw 53 so that the adjustment rod 47 can be slightly moved in the axial direction.
When rotated, the lower end pressing part 49 of the adjustment rod 47 descends and presses the diaphragm 52 of the valve, and when the housing is rotated in the opposite direction, the adjustment rod 47 rises and separates from the diaphragm 52. ing. The diaphragm 52 is usually made of a flexible material such as rubber, and the diaphragm pressing plate 54 is made of a rigid material.
is interposed between the adjustment rod 47 and the diaphragm 52, so that the entire surface of the diaphragm 52 can be suppressed with uniform force. The lower valve box 51 is provided with a fluid inlet 55 and an outlet 056, and normally compressed air is introduced into the lower valve box 51 from the inlet 55 and flows out from the outlet 56. Furthermore, in the lower valve box 51, the lower surface of the diaphragm 52! - Open the exhaust port 57 that communicates with the outside in one direction with a required gap 58, and in the state shown in FIG.
When the compressed air is introduced into the inside of the lower valve box 51 from
The amount of compressed air escaping is reduced. Also, rotate the knob 46 to lower the adjustment rod 47,
When the diaphragm 52 is pressed by the suppressing part 49 and the diaphragm 52 completely closes the opening of the exhaust port 57 of the lower valve box 51, the compressed air that has entered the lower valve box 51 from the inflow port 55 is discharged from the exhaust port 57. The RtA regulating valve 43 is provided at an intermediate position between the compressor 16 and the distributor 27, and the inlet 55 is connected to the outlet 026 of the compressor 16 and the outlet 56 by a hose 59. are connected to the air supply holes 42 of the distributor 27 through hoses 60, respectively. 61 is an intake port for outside air to the compressor 16, and 62 is a timer for the compressor 16. Next, the compressed air supply/exhaust tube 3 will be explained. The air supply/exhaust tube 3 connects the air-filled chambers 18 to 1d of the mat 1.
4. Compressed air is supplied and exhausted independently to the 4 chambers.
It is formed by partially bundling the main tubes 3a, 3b, 3c, and 3d, and a plug 63 that fits into the connection socket 45 of the air supply source 2 is installed on the base side, and a plug 63 that fits into the connection socket 45 of the air supply source 2 is installed on the tip side. A plug 64 that can be attached and detached to the air supply/exhaust port 9 and air supply port 10 provided on the side surface of each air-filled chamber 1 a > 1 d
will be established. Next, the distribution attachment 15 that doubles the 4 distribution by the distributor 27 to 8 distribution will be explained. Figure 28 is a plan view, Figure 29 is a longitudinal front view, and 6
5 is the main body of the distribution attachment. The attachment main body 65 consists of three parts: one plug part 66 and two socket parts 67 and 68. The plug part 66 has a plug 69 in the same shape as the plug 63 provided at the base of the air supply/exhaust tube 73. The inner hole 70 of the plug 69 has four protruding pieces.
The plug portion 66 is passed through the plug portion 66 upward and communicates with the first slot portion 67 . 1st. The second socket portions 67 and 68 are formed in parallel in the horizontal direction, and four communication passages 71 are formed in parallel in the core portion as shown in FIG. Part 6
7.68 has tube connection ports 45a to 4 shown in FIG.
Tube connection port with the same arrangement as 5d? 2a~? 2d
, 73a to 73d. Further, the four communicating paths 71 are connected to the tube connecting lower portions 2a to 7 of the first socket portion 67.
The inner holes 70 that lead to the tubes 2d are individually branched from each other and are electrically connected to the tube connection lowers 3a to 73d formed in the second socket portion 68, respectively. Figure 30 shows eight air-filled chambers 1 a +'l b+ l
c Mat 1I with Iia, ie, lsu, Ig, lhi
C. Supply and exhaust tube 3 using the above distribution attachment 15
This shows a state in which the tube connection ports of the first socket part 67 and the second socket part 68 are connected in the same order,
For example, the outermost air-filled chambers 1a and lh of the mat 1 are connected to 72a and 73a, and the second tube connection lower 2b,
73t) are connected to the second air-filled chambers 1b, 1g from the outside, and so on, and the first air-filled chambers 1d, 1g are connected to the central air-filled chambers 1d, 1e from the outside. The tube connection lowers 2a and 73a of the second pocket portions 67 and 68 are connected to achieve a desired surge effect in which air is supplied and exhausted from the outside toward the center. Next, the operation of the present invention will be explained using the above embodiments. For example, using the pine surf mat 1 shown in FIG.
Among the four chambers formed in the mat 1, air-filled chambers 1a, lb,
lc, 1'dK provided in the supply/exhaust port 9 and the air supply port lO,
Supply and exhaust tubes 3a, 3b. The tip plugs 64 of 3C' and 3d are fitted, and the base plug 63 of the air supply/exhaust tube 3 is fitted into the socket 45 of the air supply source 2. Second air light viewing chamber 1 of the pine surge mat 1 shown in FIG.
When you sleep with your lumbar vertebrae directly above b, the first air-filled chamber 1
The wide section is on top of a, and the third air-filled chamber] L is on top of C.
The r section will now ride. After completing the preparation for pine surge as described above, turn on the power to air supply m and 2. When the air supply source 2 has an AC source ≠-, the AC is half-wave rectified by a diode (not shown), and this half-wave part is energized to the electromagnet 17, which is the driving part of the compressor 16, to excite the electromagnet. In this way, when the iron rod 20 is drawn by the electromagnet 17 while compressing the coil spring 21, the piston 18 moves to the left in FIG. room 2
Inhale air into 2. During the other half-wave part of the alternating current, the electromagnet 17 is not energized, so it is demagnetized, and at this time, the piston 18 moves to the right in the figure due to the elastic force of the coil spring 21, and at the same time, the compressed air in the fluid compression chamber 22 is discharged 026. It is discharged through the discharge valve 25. When the air in the fluid compression chamber 22 is compressed by the movement of the piston 18, the compressed air enters the flow rate adjustment valve 43 through the hose 59, and the diaphragm 52 of the valve 43 is opened as shown in FIG. When the exhaust port 57 is closed, the air enters the distributor 27 through the hose 60. The compressed air that has reached the inside of the distributor 27 passes through the air supply hole 42 and enters the communication groove 35 of the rotating member 32.
5 through the supply/exhaust hole 38a of the fixed member 36, air is supplied from the supply/exhaust tube 3a to the first air-filled chamber 1a of the mat 1, gradually expanding the same chamber 1a, and the first air-filled chamber 1a first moves from the placement part. Apply pressure from below to stimulate. When the power of the air supply source 2 is turned on, the /fukuro motor 28 simultaneously starts rotating at a low speed (for example, 3 times/min), so that the . It contacts the surface 40 in an airtight manner, rotates, and connects the next air supply hole 18b with the communication @35, and the compressed air passes through the air supply tube 3b and enters the air supply port 10 with the check valve 11. 2nd air-filled room】b. On the other hand, an exhaust hole 36 formed in the rotating member 32 on the lower surface of the air supply and exhaust hole 38a.
The air in the first air-filled chamber A is gradually evacuated by υ1 from the exhaust hole 36. When the rotary plate 31 further rotates, the supply/exhaust hole 38C and the communication groove 35 communicate with each other, and compressed air is supplied via the supply/exhaust tube 3c [passing through the air port 9 and entering the same second air-filled chamber 1b]. As is clear in FIG. 1, the air-filled chamber 1b is located in the first. Although the volume is larger than that of the third air filling chambers 1a and lc, the air supply port 10, which does not supply air, has a reverse 1 valve 11, so that the air supplied from the air supply port 10 is not exhausted. It remains as it is in the second air filled chamber lb, and the air supply/exhaust hole 38C
It additionally receives the compressed air sent through the spacer, expands to a larger size than the first aerial light beam chamber 1a, and compresses the area around the lumbar vertebrae from below. As expected, the lumbar vertebrae protrude into the lumbar region as shown in Figures 37 and 38, and when the lumbar region is compressed by a conventional pneumatic pine surf device, the mat becomes stronger as shown in Figures 36 and 38. This puts pressure on the lumbar vertebrae and causes the lumbar vertebrae to curve unnecessarily, but in the present invention, the following actions are performed so that the lumbar vertebrae are not unnecessarily compressed or curved. That is, the pine l-1 of the present invention has a seal portion 7 that airtightly defines the first to fourth air-filled chambers 1a, lb, lc, and ld, and the lengthwise direction of the filled chambers is also the central portion of J. The force that narrows the nearby air flow path 8 is as described above,
For example, the first. When compressed air is sent into the second air-filled chambers 1a and 1b, the expansion around the center is slight as shown in Fig. 37, and the caudal, sacral, and lumbar vertebrae are 3. The fourth air-filled chambers 1c and ld do not put any pressure on the thoracic vertebrae at all, and the numerous acupoints on both sides of the caudal vertebrae, sacral vertebrae, lumbar vertebrae, and dorsal vertebrae. B presses the body at right angles from the diagonal direction shown by the arrow in Figure 37, applying air pressure very effectively to the acupuncture points and their surroundings, giving a pine surge effect that is comparable to that of acupressure. Around the eta, there are countless nerve mechanisms; branching, nerves, and blood vessels are concentrated, so applying air pressure as described above improves blood circulation and softens the muscles. The lower back is said to be the key point of the body, and fatigue tends to accumulate in various parts of the body, but according to the present invention, the above-mentioned effects are achieved. In order to do this, stretch the pillars without forcing yourself, centering on your lower back, for example, press your ischial bones! It works to eliminate the causes of back pain such as pain and herniated discs. As a result, the supply of air to the second full air chamber 1b ends, and as the roller motor 28 rotates, the supply of air to the third full air light chamber C starts, and on the other hand, the air supply from the second full air light chamber 1b starts. When exhaustion begins, the third air-filled chamber IC expands, and the back resting on the third air-filled chamber IC is compressed diagonally from below around the thoracic vertebrae in the same way as the middle and lower back. Thereafter, when the air supply to the third air light chamber t4 IC ends, the air supply starts to the first air light room IC, and then the second air light room IC is supplied again. Pressure a air is repeatedly supplied to the third air light chamber t4 chamber 1b, ic, and pine surgery is performed repeatedly in the order of private parts, waist, and back. Next, in the case of the mantle I shown in FIG. The exhaust tubes 3b, 3c, and 3d are the first. Second. The third air-filled chambers 1b, lc, and 2d are connected in this order and air supply and exhaust are performed in the same manner. However, because the second air-filled chamber Ib of the mat 1 shown in FIG. Care should be taken to place the part to which air pressure should not be applied on top of the second nitrogen light full chamber Ib. In this case, consideration can be given only by moving the mat 1 in the vertical direction or changing the top and bottom of the mat 1, but the amount of air supplied to the air-filled chambers] a to 1 d can be adjusted by using the knob 46 of the flow lid adjustment valve 43. Question 1, exhaust port 57
□ to increase or decrease the equipment from the cabinet,
The pine surf time is set by changing the cent time of the timer 62. Next, the mode of pine surging six parts using the pneumatic pine surge device of the present invention will be explained using mat 1 shown in No. 1M. 2nd air 9th room of mat 1] Place your neck on top of b.
When the head is placed on the first air-filled chamber 1a and the back is placed on the 3.4th air-filled chamber 1c, ld, and the air supply 02 is started, Pine Surge will be placed in the first air-filled chamber 1a. Due to expansion, it starts from the head. First air-filled chamber 1a
The mat that expands wraps around the head from both sides, applying pressure from both sides of the midline. Next, when the second air-filled chamber 1bVc is supplied with air, the mat 1 presses the 6th part from both sides, and at the same time pushes the head slightly upward in the direction of the arrow in FIG. 39. That is, when the mat 1 is inflated by the air supplied to the second air-filled chamber 1b, the mat 1 presses against the hole that unavoidably compresses the cervical vertebrae, but at the same time The part that rides on the mat is mat 1
As the cervical vertebrae expand, the cervical vertebrae are stretched. The cervical vertebrae are constantly bearing the weight of the head, and the inside of the head tends to become congested with dirty blood. Therefore, by gently stretching the cervical vertebrae as described above, the blood vessels around the vertebrae open and the blood circulation of the carotid arteries is improved. Improve your mind and relieve the heaviness in your head. Historically, when air is supplied to the third air-filled chamber IC, it pushes the acupuncture points on both sides of the thoracic vertebrae, such as the air volume, lung life, Shinsuke, Lieutenant, etc., especially,
It is effective when you catch a cold. Next, the action of the example shown in FIG. 30 will be explained. Mat 1 shown in Fig. 30 has 8 chambers of air light/-1 chamber 1a
, lb, lc, ld, Is, 1 ° , 1
g. 1h, with attachment 1 attached to air supply source 2.
5 is attached, and the compressed air distributed in four parts and discharged by the air supply source 2 is converted into eight parts in parallel connection, and the compressed air is distributed in eight parts in parallel. No. 8 nitrogen filled chamber la. 1h to 4th in the center position. Fifth air-filled chamber 1d. It performs an action of repeating centripetal expansion and contraction toward 1θ, and performs manosurf toward the heart when lying supine or prone. According to this example, for example, it is possible to perform pine surgery in a predetermined order from both the head and thigh sides at the same time, but when using the mat l shown in Fig. 1, Similarly, when viewed from the side, the lumbar and cervical vertebrae have large constrictions.

[In order to be able to pine surf evenly around other parts of the body (head, thoracic vertebrae, sacral vertebrae, caudal vertebrae, etc.), the 2nd and 5th air-filled chambers 1b and 1e must be made wider than the other rooms. Alternatively, two cloaks 1.1 with different sizes of air-filled chambers 1a, Ib, lc, and Id are used by aligning them in an appropriate direction as shown in FIG. 7 and joining them together.Next, In the present invention, the features of the compressor 16 shown in FIG. The compressor 16 is of the Akira type, in which the piston 18 moves forward and backward when the electromagnet 17 is demagnetized. It has a self-control effect in which the range of motion is rapidly attenuated.Therefore, it becomes locked at a relatively low pressure relative to the rated pressure, and compressed air is not fed into the mat 1. There is no danger of excessive pine surge pressure being generated.In addition, such an electromagnetic reciprocating compressor] 6, each air-filled chamber of the mat 1] a @ 1 b * 1 c.
By connecting ・, it is possible to apply pine surge pressure with the compressor 16 in the locked state, and
The fluctuation of the pine surge pressure is extremely small and the required pine surge pressure can be obtained. Furthermore, the electromagnetic reciprocating compressor 16 can operate continuously in the locked state because the reciprocating motion of the piston 18 becomes very small in the locked state.
At that time, there is no overload dust phenomenon, and there is no risk of burning out the compressor.In addition, in the present invention,
An electromagnetic reciprocating compressor 16 with a lock pressure of about 0.2 to 0.4 Kf/ol may be used, and there is no need to provide an IJ valve for overpressure leakage in the pressurized fluid supply system. In other words, the flow rate of air in the compressor 16 becomes zero at a lock pressure that is quite close to the rated pressure, and even if a relief valve is not used, air under excessive pressure will not be supplied. Since continuous operation is possible in such a locked state, a constant lock pressure state can be applied as a pine surge pressure, which is a very stable operation. The same applies to the example shown in FIG. 17 in which the diaphragm is replaced with the diaphragm, and in the compressor 16', the diaphragm l8' that moves together with the iron core 20 moves together with the iron core 20 that moves when the electromagnet 17' is excited. When the electromagnet 17' is demagnetized, the electromagnet 17' moves back and forth due to the action of the coil spring 21, and in the process it enters a locked compression state at a relatively low pressure compared to the rated pressure, and the flow rate of compressed air becomes zero at the locking pressure. Therefore, like the former 16, even without using a relief valve, excessive pressure will not be applied to the mat 1, and the diaphragm 18' moves in the locked pressure state, and the desired mat surge pressure can be obtained. In addition, regardless of whether the piston compression method or the diaphragm compression method is used, the electromagnetic reciprocating compressor adopted as an example in the present invention can adopt a shadow type in which the double action is also performed by the action of an electromagnet. In this case, two electromagnets are alternately energized and demagnetized. The present invention has been described above based on some embodiments, but the pneumatic pine surge device of the present invention has two or more, appropriate number of air-filled chambers 1a, lb, lc, ld... arranged in parallel, A mat for pine surge 1 in which the air flow path near the center in the length direction of each air-filled chamber is narrowed so that the number of air-filled particles in the vicinity is smaller than in other parts on the left and right; Each air-filled chamber la. An air supply source 2 that sequentially supplies compressed air to lb, lc, and ld in an appropriate order and sequentially exhausts air, and an air supply/exhaust tube that communicates between each air-filled chamber of the pine surge pressure mat l and the air supply source. 3, the central part of the pine l-1 of the pine surge pressure can be applied during the pine surge without unduly compressing the pillars of the body or protruding parts such as the lumbar vertebrae. Acupuncture points scattered on both the left and right sides can be effectively pine-surged from the right angle direction. Moreover, the present invention is used in a ssn recumbent state or a prone state by placing a complete mat 1 in a plurality of air-filled chambers.
As described above, the mat 1 is configured so that the amount of air filled near the center is small, so that Manosurf pressure can be uniformly and softly applied to each part of the body. By selecting the order of air supply, it is possible to obtain either a centripetal (towards the heart) wave Manosurf effect or a centrifugal (toward the distal direction) wave Manosurf effect. In addition, the pneumatic pine surge device of the present invention can be used in supine and prone positions to improve blood circulation on both sides of the thoracic and lumbar vertebrae, such as the buttocks, shinsuke, kidneys, and daishu, which control blood circulation. It stimulates the acupuncture points, the pillars of fire, wind waves, and other similar acupuncture points, and at the same time stimulates the many acupuncture points that exist in the vicinity of these acupuncture points, resulting in symptoms such as sensitivity to cold, stiff shoulders, insomnia, headaches, etc.
It is effective in relieving irritation, heaviness in the helmet, swelling in the stomach, and many other symptoms.

[Brief explanation of the drawing]

The drawings show embodiments of the present invention, and FIG. 1 is a plan view showing a first example of a pine surfing cloak, FIG. A vertical cross-sectional view of the air supply port of the cloak, Figure 4 is taken along A-A in Figure 1.
Figure 5 is a plan view showing a second example of a pine surge mantle, Figure 6 is a plan view of a third example of a pine surge mantle, and Figure 7 is a diagram showing two pine surge mantles connected. Fig. 8 is a plan view showing a fourth example of a pine surge cloak that can be attached to a chair, etc. Fig. 9 shows A, B, C, D, E, 'F. Narrowing the air flow path near the center of the Mano Surf mat / Part 6
FIG. 10 is a plan view of a mat for pine surfing in which the air-filled chamber is formed in a chevron shape, FIG. 11 is a plan view of a mantle for pine surfing in which the air-filled chamber is formed in an arc shape, and FIG. 12 is a plan view showing the configuration. Air light (a plan view of a pine surge cloak made by overlapping two airtight flat bags with rectangular and chevron-shaped chambers, Figure 13 shows the air-tightness of two air-tight flat bags with rectangular and arcuate air-filled chambers) Fig. 14 is a plan view of a mat for manosurf formed by overlapping flat bags, and Fig. 14 is an fP + view showing an example of the pneumatic pine surf device of the present invention. Fig. 16 is a longitudinal cross-sectional view of the air supply source showing the compressed air distributor and flow M adjustment valve in the upper middle section, and Fig. 17 shows another electromagnetic reciprocating compressor. A schematic sectional view, FIG. 18 is a partially cutaway front view of the distributor, FIG. 19 is a plan view, and FIG. 20 is a plan view of a fixing member of the distributor.
A top sectional view, FIG. 22 is a top sectional view taken along line C-C in FIG. 20,
Fig. 23 is a plan view of the rotating member of the distributor, Fig. 24 is a bottom view, Fig. 25 is a sectional view taken on line D in Fig. 23, and Fig. 26 is a partially cutaway front view of various adjustment valves. Figure, No. 26
The figure is a partially cutaway view showing the exhaust port of the valve in a closed state, Figure 28 is a plan view of the distribution attachment, Figure 29 is a cutaway view taken along line C-C in Figure 20, and Figure 30 is the distribution attachment. FIG. 31 is an explanatory diagram showing the first example of distributing air into eight parts, and FIG. 32 is the same as the second example.
FIG. 32 is an explanatory diagram showing a third example, and FIG. 34 is an explanatory diagram showing a third example. Fig. 35 is a plan view showing the mat for pine surgery of the present invention superimposed on a human body, and Fig. 36 is an explanatory diagram showing the state of curvature of the lower back when using a conventional pneumatic Manosurf device. 37 is an explanatory diagram showing the pine surf effect according to the present invention cut into rings, FIG. 38 is an explanatory diagram showing the compression state of the lower back according to the conventional example shown in FIG. 36, also cut into rings, and FIG. The figure is an explanatory diagram showing a mode of performing pine surgery on the neck with the pneumatic pine surge device of the present invention. 1...Pneumatic pine surge mat, 1a, ]l). lc, ld, 1e, 1 + I F', + 1 h"
・Air-filled chamber, 2...Air supply source, 3, 3a, 3b,
3C. 3d... Supply and exhaust tube, 4.5... Bag constituent material, 6.7... Gas crystal seal portion, 8... Air flow path near the center, 9... Supply and exhaust port, 10...Air supply port, 1]・
・Reverse IE valve, 15...Distribution attachment, 16...
Compressor, 17... Electromagnet, 18... Piston, 18'... Diaphragm, 20... Iron core, 21...
...Coil spring, 22...Compression chamber, 23...Suction valve, 24...Intake port, 25...Discharge valve, 26...Discharge port, 27...Air distributor, 28... .../ink 0 motor, 36 ・DF pores 38a, 38b. 38c, 38d... Supply/exhaust hole, 42... Air supply hole, 4
3...Flow rate adjustment valve, 45...Socket for connecting supply and exhaust tubes, 45a, 45b, 45c
, 45 d...Tube connection port, 46...Knob, 47...Adjustment rod, 57.Exhaust port, 58...Gap, 62...Timer, 63°64...Plug, 65...
・Distribution attachment main body, 66...Plug part, 67
...First socket part, 6B...Second socket part, 7
2 a, 72 b, 72 c, 72 d...
- First tube connection ports, 73a, 73b, 73c. 73d...Second tube connection port. Patent Applicant: Nitto Kohki Co., Ltd. Figure 6, Figure 7, Figure 8, Figure 11゜Figure 9, Figure 9A, Figure 9B, Figure 9, C, Figure 9. Fig. 9 E Fig. 9 F Fig. 10 1dlc lb Ia Fig. 12 Fig. 11 Fig. 13 Fig. 17 Fig. 19 Fig. 22 Fig. 23 Fig. 24 Fig. 25 Fig. 26 Fig. 29 Fig. 31 Figure 34 Figure 35 Figure 36 Figure 37 Figure 38 Figure 39 Procedure Amendment Book February 8, 1980 1. Indication of the incident 1982 Patent Application No. 199393 2. Name of the invention Pneumatics Person who performs mat a correction for pine surge equipment and pneumatic pine surge Contents of correction
I will correct it as "a". (2) The word “do” written in line 3 from page 6 of the same book is corrected to “it is possible.”3゜(3) “Air supply” written in line 3 of page 20 of the same book is corrected. '' is corrected to ``exhaust.'' (4) ``1.2゜3rd
" will be corrected to "2nd. 3rd. 4th." (5) "5th" written in the 9th line of No. 26 of the same book is replaced by "8th"
and [1θj'kr1gJ, respectively. (6) In the same book, page 28, line 3, replace “kara,” with “
"Ku," I corrected. (7) The entire phrase ``90, regardless of what,'' written in the second line of page 29 of the same book is corrected as follows. ``Regardless of the type of compressor, an air supply source equipped with the aforementioned distributor and pressure regulating valve can be used.'' (8) Figure 34 is corrected as shown in the attached sheet. Figure 34 Procedural Amendment (Method) April 13, 1980 Haruki Shimada, Commissioner of the Patent Office, 1, Indication of the case, Patent Application No. 199393, filed in 1982, 2, Name of the invention: Pneumatic pine serge device and pneumatic pine surge cloak (a) Person making the amendment March 5, 1980 (Delivery date: March 30, 1982) (h) Subject of amendment (1) "Figure 26" written in line 6 from the bottom of No. 32 of the specification
has been corrected to read “Figure 27”. (2) "Figure 32" in the first line of page 33 of the same book has been corrected to "Figure 33."

Claims (1)

[Claims] 7.2 or more, an appropriate number of air-filled chambers are arranged in parallel, and the air flow path in the vicinity of the center of the length and direction of each air-filled chamber is narrowed, so that the air-filled chambers in the vicinity are narrowed. A pine surge mat formed to have a length of 74 m smaller than the other parts on the left and right, and an air supply source that sequentially supplies compressed air to each air-filled chamber of the mat in an appropriate order and exhausts the air sequentially; A pneumatic pine surge device comprising an air supply/exhaust tube that communicates each air-filled chamber of the pine surge mat with an air supply source. 22 or more, an appropriate number of air-filled chambers are arranged in parallel, and the air flow path near the center in the length direction of each air-filled chamber is narrowed, so that the air source/f4 amount in the vicinity is smaller than the other parts on the left and right. In addition, each air source is equipped with a pneumatic pine surge mat with compressed air supply and exhaust ports.