JP2009268396A - Device facility and method for promoting blood circulation for horse, and wrapper therefor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To promote the blood circulation of a horse to stimulate the horse's metabolism and enhance the horse's curing effect, leading to relieving the horse from fatigue, preventing the horse from injuries and promoting curing such injuries. <P>SOLUTION: A device 3 for promoting the blood circulation for horse is provided, being characterized by having a carbon dioxide feeder 60 in order to absorb carbon dioxide into carbon dioxide-absorbing materials 64 and 65 to be fitted on the percutaneous surface of the horse in question. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a horse blood circulation promotion device, a horse blood circulation promotion facility, a horse blood circulation promotion method, and an enclosure. The present invention can also be used as an immunity enhancing apparatus for horses that enhances the immunity of horses.

  Competing horses and passenger horses run in numerous races throughout their lifetime. In addition, training using a training device is performed in order to achieve higher grades in a race to run (see, for example, Patent Document 1).

JP 07-289108 A

  However, in such a harsh environment, fatigue of competing horses and passenger horses accumulates, causing injury. For example, a disease called flexor tendonitis (also called shrimp harassment), in which the flexor tendon is inflamed and swollen, is known. This flexor tendinitis is said to be caused by overuse of the legs due to long-term exercise load, and a large number of racehorses have developed. Furthermore, it has been reported that the fracture rate of racehorses has reached about 1% of the total number of races.

Therefore, it is very beneficial to prevent injuries by quickly recovering from fatigue in race horses, passenger horses, etc. in such a harsh environment. In addition, it is desired that an injured race horse, passenger horse, etc. be restored as a race horse, passenger horse, etc. at an early stage by promoting treatment.
The present invention has been made in view of the above-described problems, and promotes the blood circulation of horses to promote metabolism and enhance the healing effect, thereby promoting fatigue recovery, injury prevention, and injury treatment. With the goal.

The equine blood circulation promoting device of the present invention is characterized by having a supply device for supplying carbon dioxide gas so that the absorbent material attached to the percutaneous surface of the horse absorbs carbon dioxide gas.
Further, the equine blood circulation promotion facility according to the present invention includes a spraying device that sprays an absorbent material on the percutaneous surface of the horse, and an isolation space that is filled with carbon dioxide gas and into which at least a part of the horse part to which the absorbent material is attached enters. It is characterized by having.
Further, the method for promoting blood circulation for horses of the present invention includes a step of attaching an absorbent material to the percutaneous surface of a horse, a step of causing the attached absorbent material to absorb carbon dioxide, and an absorbent material having absorbed the carbon dioxide gas. And a step of absorbing carbon dioxide into the body of the horse through the body.
The enclosure of the present invention is an enclosure that surrounds at least a part of the percutaneous surface of a horse, and has a supply space in which carbon dioxide gas is supplied. The enclosure is in contact with the percutaneous surface. It is characterized by being made of a material having adhesion and durability against pressure applied to the carbon dioxide gas supplied to the inside.

  According to the present invention, by promoting the blood circulation of a horse, the metabolism can be promoted, the healing effect can be enhanced, and fatigue recovery, injury prevention, and injury treatment can be promoted.

Hereinafter, with reference to the drawings, a configuration of a horse blood circulation promoting device according to an embodiment of the present invention will be described. Note that carbon dioxide is used as an example of carbon dioxide gas.
(First embodiment)
The first embodiment is an embodiment in the case where a foamy mousse is directly applied and used as an absorbent material to be attached to the percutaneous surface of a horse.

FIG. 1 is a diagram illustrating an example of the configuration of the blood circulation promoting device according to the first embodiment. The blood circulation promotion device according to the first embodiment includes a supply device. The supply device shown in FIG. 1 is a mousse generating device (spray gun) 10 that generates mousse by making carbon dioxide into bubbles.
The mousse generating apparatus 10 includes a container body 11, an injection port 12, a handle portion 13, an injection switch 14, and an insertion port 15. The container body 11 contains a foamable gel as an absorbent material that adheres to the horse's percutaneous surface. Here, the foamable gel as the absorbent is a liquid that contains components suitable for foam generation and can melt carbon dioxide. In addition, you may mix the nanoized chemical | medical agent (henceforth a nano chemical | medical agent etc.) with a DDS (Drug Delivery System) effect into an absorber.

As shown in FIG. 1, the nozzle 15 of the cartridge 16 or the cylinder 17 can be connected to the insertion port 15. Here, the cartridge 16 contains carbon dioxide compressed. The cylinder 17 is a container in which carbon dioxide is highly compressed and stored in a liquefied state. The cylinder 17 is provided with a decompressor, a scale, a cock, and the like, and can release gaseous carbon dioxide by reducing the pressure to a desired pressure.
After the user attaches the nozzle of the cartridge 16 or the cylinder 17 to the insertion port 15, the user presses the injection switch 14 provided in the handle portion 13, so that the mousse generating device 10 causes the foamable gel to foam, and the bubbles The mousse 20 containing the carbon dioxide in the form is generated, and the generated mousse 20 is injected from the injection port 12. Of the injected mousse, the bubbles are carbon dioxide, and the rest are absorbent.

Next, a method of directly applying mousse to the percutaneous surface of the horse will be described with reference to FIG. Here, the percutaneous surface of the front leg 1 of the horse will be described as an example of the percutaneous surface of the horse.
The user applies the mousse to the percutaneous surface of the front leg 1 by pressing the injection switch 14 in a state where the injection port 12 of the mousse generating apparatus 10 is close to the front leg 1 of the horse as shown in FIG. be able to. In addition, the user arranges the shape of the mousse so that the applied mousse covers the entire percutaneous surface of the front leg 1. The user may spray the mousse once on his / her hand and then apply it directly to the horse's percutaneous surface. Moreover, the user can apply | coat easily by injecting a mousse directly to a horse body.

  Next, the action of the bubble-like carbon dioxide contained in the mousse applied to the percutaneous surface will be described with reference to FIG. FIG. 3 is a view showing a cross section of a front leg of a horse to which mousse is applied. Fig.3 (a) is a figure which shows the state immediately after apply | coating a mousse. As shown in FIG. 3A, the mousse 20 contains a large number of bubble-like carbon dioxide 18 uniformly. Since the bubble-like carbon dioxide 18 is surrounded by the mousse 20, it does not escape from the mousse 20 to the outside.

  In the mousse 20 attached to the percutaneous surface of the horse, the carbon dioxide 18 gradually melts into the absorbent material. The absorbent material in which carbon dioxide is melted is absorbed into the body from the transdermal surface of the horse. Therefore, carbon dioxide can be absorbed into the body through the absorbent material. By absorbing carbon dioxide into the body, carbon dioxide enters the red blood cells in the blood through the tissues in the body, a chemical reaction occurs in the red blood cells, and the red blood cells release oxygen. Each cell is activated by the oxygen released from the red blood cells spreading to the cells in the body. Activation of each cell can bring about effects such as dilation of blood vessels, promotion of blood circulation, and reduction of blood pressure. Hereinafter, an effect caused by absorbing carbon dioxide in the body is referred to as an effect of promoting blood circulation.

  Next, as time elapses, the mousse 20 located near the transcutaneous surface gradually liquefies by being warmed by the transcutaneous temperature. Therefore, the absorbent material liquefied near the percutaneous surface hangs downward according to gravity, so that the applied mousse 20 is reduced as shown in FIG. However, in the mousse 20 shown in FIG. 3 (b), the mousse located near the percutaneous surface has disappeared, and the mousse 20 located outside has moved to the percutaneous surface side. Here, even if the mousse 20 located on the outer side uniformly contains bubble-like carbon dioxide, even if the mousse 20 is reduced as shown in FIG. 3B, FIG. As in the state shown in Fig. 5, fresh carbon dioxide can be melted in the absorbent material.

Here, the mousse 20 which the mousse production | generation apparatus 10 produces | generates can adjust the time which maintains a mousse shape by changing the component of a foamable gel. For example, a mousse shape can be maintained even after 12 hours, for example, by using a foamable gel mixed with a viscous material.
In the embodiment described above, only the case where mousse is applied to the front leg 1 of the horse has been described, but the present invention is not limited to this case. For example, as shown in FIG. 4, the mousse 20 may be applied to the shoulders, back, waist, and rear legs in addition to the front legs.

  Thus, according to the first embodiment, carbon dioxide can be absorbed into the body via the absorbent material by including bubbled carbon dioxide in the mousse and applying it to the percutaneous surface of the horse. . By using mousse as an absorbent material, the mousse disappears naturally after the mousse is applied, so that it is possible to improve the usability of absorbing carbon dioxide in the body.

(Second Embodiment)
The second embodiment is an embodiment in which an enclosure filled with a foamy mousse is surrounded by a part of the percutaneous surface of a horse.
FIG. 5 is a diagram illustrating an example of the configuration of the blood circulation promoting device according to the second embodiment. The blood circulation promoting device 2 according to the second embodiment includes the mousse generating device 10 and the enclosure 30.
The surrounding body 30 shown in FIG. 5A is formed so as to be able to surround the front leg or the rear leg by wrapping around the front leg or the rear leg of the horse. The enclosure 30 includes an enclosure 31, a transmission member 32, a filling portion 33, and locking members 34 (34 a and 34 b). The enveloping member 31 has a shape that can surround the front leg or the rear leg of the horse, and is formed of, for example, flexible polyvinyl chloride, nylon, synthetic resin, cloth, rubber, chloroprene rubber, or the like. The surrounding material 31 is preferably made of a material that does not transmit the mousse to the outside.

  A mesh-shaped transmission member 32 is attached to the inner peripheral surface of the surrounding material 31 over substantially the entire surface of the surrounding material 31. A plurality of pocket-shaped filling portions 33 that can be filled with mousse are formed as a mousse accommodating portion between the transmissive member 32 and the surrounding material 31. The mousse filled in the filling portion 33 can pass through the mesh-shaped transmission member 32. Locking members 34 (34 a, 34 b) are provided on the outer peripheral surface of the envelope 31. The locking members 34 (34a, 34b) are so-called hook-and-loop fasteners, and are configured as a pair of one locking member 34a of the envelope 31 and the other locking member 34b facing each other.

Next, a method of surrounding the envelope 30 filled with the foamy mousse with a part of the percutaneous surface of the horse will be described with reference to FIGS. 5 (a) and 5 (b).
First, as shown in FIG. 5A, the user presses the injection switch 14 with the injection port 12 of the mousse generating device 10 facing the pocket-shaped filling unit 33 and fills the filling unit 33 with mousse. Let The user fills all the filling portions 33 uniformly with mousse, and then winds the inner circumferential surface of the enclosure 30 so as to face the percutaneous surface of the horse's front leg 1 as shown in FIG. 5 (b). . At this time, the user locks one locking member 34a provided on the enclosure 30 to the other locking member 34b. In this way, the wrapping body 30 is wrapped around the horse's front leg 1 and surrounded, so that the mousse that has passed through the mesh-shaped transmission member 32 adheres to the entire percutaneous surface of the horse's front leg 1.

  Thereafter, as described in the first embodiment, carbon dioxide gradually melts into the absorbent material in the mousse attached to the horse's percutaneous surface. The absorbent material in which carbon dioxide is melted is absorbed into the body from the transdermal surface of the horse. Therefore, carbon dioxide can be absorbed into the body through the absorbent, and effects such as blood circulation promotion can be brought about.

  In the above description of the second embodiment, only the enclosure that surrounds the front leg 1 of the horse has been described. However, the present invention is not limited to this case. FIG. 6A shows an example of the shoulder enclosure 36 and the waist enclosure 37. The shoulder envelope 36 is wrapped around the shoulder so as to cover the entire shoulder. The shoulder enclosure 36 is provided with a locking member 34 such as a hook-and-loop fastener that locks the neck and abdomen of the neck. Further, the waist enclosure 37 surrounds the waist by covering the entire waist from the upper part of the waist. The waist enclosure 37 is provided with a locking member 34 such as a hook-and-loop fastener that locks the base of the abdomen and the rear leg.

FIG. 6B shows an example of a horse-mounted envelope 38. The horse-mounted envelope 38 surrounds the shoulder, back, waist, and abdomen. The horse-mounted envelope 38 is provided with a locking member 34 such as a hook-and-loop fastener that locks the base of the neck, the abdomen, and the buttocks.
Since the inner peripheral surfaces of the shoulder enclosure 36, the waist enclosure 37, and the horse-mounted enclosure 38 are filled with mousse in the same manner as the enclosure 30 described above, the shoulder, waist and whole body of the horse are filled. The carbon dioxide can be absorbed into the body through the absorbent. In this way, by making the enclosure in accordance with the part of the horse, the enclosure can be used properly according to the degree of fatigue of the fatigued part of the horse and the progress of the symptoms.

In the description of the second embodiment described above, only the filling portion 33 formed in a pocket shape between the transmission member 32 and the surrounding material 31 has been described, but the present invention is not limited to this case. FIG. 7 is a diagram illustrating an example of an enclosure having a filling portion of another form. In addition, about the structure similar to the enclosure 30 mentioned above in FIG. 5, the same code | symbol is attached | subjected and description is abbreviate | omitted.
The envelope body 40 includes an envelope member 31, a filling portion 41, and locking members 34 (34a, 34b). The filling portion 41 is formed of a material such as cloth so that friction is easily generated with the mousse and does not hang down due to gravity. As shown in FIG. 7, the user directly fills the mousse directly on the filling portion 41 and then winds the wrapping body 40 so that the inner peripheral surface of the enclosure 40 faces the percutaneous surface of the front leg 1 of the horse. Thus, the wrapped mousse adheres directly over the percutaneous surface of the horse's front leg 1 directly on the filling portion 41 by winding the enclosure 40 around the horse's front leg 1 and surrounding it.

  Moreover, although the case where the enclosure formed according to each site | part of a horse was used was demonstrated in the description mentioned above, it is not restricted to this case. For example, a mousse may be filled on a supporter, cloth, non-woven fabric, etc., and the filled side may be wound so as to face the percutaneous surface of the horse.

  Thus, according to the second embodiment, the mousse containing bubbled carbon dioxide was filled in the enclosure, and the enclosure filled with the mousse was wound around the percutaneous surface of the horse. Therefore, since the filled mousse can be attached to the transdermal surface of the horse, carbon dioxide can be absorbed into the body through the mousse. At this time, the mousse is in a state covered with an enclosure, and the mousse is not wiped off by the horse, so that carbon dioxide can be absorbed into the body with certainty.

(Third embodiment)
The third embodiment is an embodiment in the case where carbon dioxide is supplied into the enclosure after enclosing at least a part of the percutaneous surface of the horse in a sealed state with the enclosure.
FIG. 8 is a diagram illustrating an example of the configuration of the blood circulation promoting device according to the third embodiment. The blood circulation promotion device 3 according to the third embodiment includes an enclosure 50 and a supply device 60.
A surrounding body 50 shown in FIG. 8A is formed so as to be wrapped around and wrapped around the front leg 1 or the rear leg of the horse. The enclosure 50 includes an enclosure 51, a joint portion 52, a suction port 53, and locking portions 54 (54a, 54b).

  The envelope member 51 is in the form of a sheet, and is formed of, for example, chloroprene rubber. Chloroplane rubber has stretchability, adhesion, flexibility, durability, and sealing properties. The enveloping material 51 is not limited to chloroprene rubber, and latex, soft urethane, ethylene vinyl acetate, polyvinyl chloride, silicon rubber, or the like, which is similar to chloroprene rubber, may be used.

  The joint portion 52 is a portion that comes into contact with the percutaneous surface of the horse, and is provided on the inner peripheral surface of the envelope member 51 along the outer edge of the envelope member 51. The joint portion 52 is formed of a material having flexibility and sealing properties. Moreover, as shown to Fig.9 (a) mentioned later, the junction part 52 has a rectangular cross section, and the inside is formed in the hollow shape. Thus, by forming in a hollow shape, it can be easily deformed following the shape of the percutaneous surface of the front leg 1 of the horse, and pressure on the percutaneous surface can be prevented. By surrounding the enclosure 50 so as to be wrapped around at least a part of the percutaneous surface of the front leg 1, a space surrounded by the enveloping material 51, the joint 52 and the percutaneous surface serves as a supply space for supplying carbon dioxide. It is formed.

The suction port 53 has a hole inserted into the supply space described above, and can supply carbon dioxide to the supply space through the hole. The suction port 53 is a check valve so that carbon dioxide supplied to the supply space does not flow backward.
The locking portion 54 is configured by one locking portion 54a of the surrounding member 51 and the other locking portion 54b. The enclosure 50 shown in FIG. 8 is provided with six pairs of locking portions 54.

  Further, the supply device 60 shown in FIG. 8A supplies carbon dioxide to the supply space formed by the enclosure 50. The supply device 60 includes a container body 61 and a decompressor 62. The container body 61 is a so-called handy cylinder, and contains carbon dioxide in a highly compressed state. The decompressor 62 decompresses the highly compressed carbon dioxide in the container body 61 to release it. The user adjusts the desired pressure and flow rate with the decompressor 62 and then opens the stopper of the decompressor 62, so that the carbon dioxide contained in the container body 61 is connected to the decompressor 62. Can be released from

Next, a method of surrounding the enclosure with a part of the percutaneous surface of the horse and a method of supplying carbon dioxide will be described with reference to FIGS. 8 (a) and 8 (b).
First, as shown in FIG. 8A, the user applies an absorbent material 64 to the percutaneous surface to which the enclosure 50 is to be attached in the front leg 1 of the horse. Here, the absorbent material 64 is a liquid (medium) capable of melting carbon dioxide, and is, for example, water, alcohols, fats and the like. Moreover, it is preferable that the thickener is contained so that it may remain at the applied position of the applied absorbent material 64 when applied to the percutaneous surface. Further, the absorbent material 64 may be weakly acidic with a pH of 4.0 to 6.5 in order to reduce the influence of the transdermal surface, and glycerin or petrolatum may be added for moisturizing and protecting the transdermal surface. The user applies the absorbent material 64 from above the hair growing on the percutaneous surface and allows it to penetrate to the percutaneous surface. In particular, the absorbent material 64 is preferably a nanonized absorbent material such as nanonized water that is easily absorbed into the body from the percutaneous surface.
Further, as shown in FIG. 8 (a), the user has a gel-like shape having a medium viscosity or a high viscosity in which a thickener is further contained in a portion of the percutaneous surface in contact with the joint portion 52 of the enclosure 50. The absorbent material 65 is applied. At this time, the user preferably applies the absorbent material 65 thicker than the absorbent material 64 described above. In particular, the percutaneous surface of the front leg 1 of the horse has a dent, and the dent is thickly applied.

  Next, as shown in FIG. 8B, the user winds the inner circumferential surface of the enclosure 50 so as to face the percutaneous surface of the front leg 1 of the horse. The user locks one locking portion 54a provided on the enclosure 50 to the other locking portion 54b. At this time, since the absorbing material 65 having a high viscosity is applied between the percutaneous surface of the horse and the joint portion 52, gas leaks from between the joint portion 52 of the enclosure 50 and the percutaneous surface. Can be prevented. Moreover, even if a horse moves and the envelope 50 shifts | deviates by apply | coating the high absorbent material 65, the adhesiveness is maintained. Thus, by attaching the enclosure 50 to the percutaneous surface of the front leg 1 of the horse, the inside of the supply space can be sealed.

Next, the user releases carbon dioxide from the supply device 60 in a state where the outlet 63 of the supply device 60 is connected to the suction port 53 of the enclosure 50. Here, if necessary, the user adjusts the pressure and flow rate of the desired carbon dioxide by the decompressor 62. The user can uniformly fill the supply space with carbon dioxide by releasing the carbon dioxide from the supply device 60 for a while.
Further, when the user continuously releases carbon dioxide, the carbon dioxide supplied to the supply space is compressed by the continuously supplied carbon dioxide. The compressed carbon dioxide causes the enclosure 50 to expand. In addition, after supplying carbon dioxide to the enclosure 50, the user accommodates the supply device 60 in the accommodation portion 55 provided on the outer peripheral surface of the enclosure 50.

Here, the enclosure 50 before and after supplying carbon dioxide to the supply space will be described with reference to FIG. FIG. 9 is a view showing a cross section of a portion surrounded by the enclosure 50 in the front leg 1 of the horse. FIG. 9A shows a state before supplying carbon dioxide to the supply space. As shown in FIG. 9 (a), the front leg 1 of the horse has a shape whose tip is thin and becomes thicker as it goes rearward. Further, as shown in FIG. 9A, the joint 52 adjacent to the latching portion 54 superposes the joint portions 52 facing each other, and then causes the latching portion 54a to latch the latching portion 54b. Thus, the sealing property of the supply space is maintained.
FIG. 9B is a diagram illustrating a state after carbon dioxide is supplied to the supply space. As shown in FIG. 9B, the compressed carbon dioxide presses the inner peripheral surface of the envelope 50, so that the envelope 50 expands. Similarly, the compressed carbon dioxide also presses against the transdermal surface of the horse.

  Here, the carbon dioxide filled in the supply space and pressurized is efficiently melted in a large amount in the absorbent materials 64 and 65 attached to the percutaneous surface of the horse. By absorbing the absorbents 64 and 65 in which a large amount of carbon dioxide is melted into the body, more carbon dioxide can be absorbed into the body. Further, the absorbent materials 64 and 65 adhering to the percutaneous surface are pressed against the percutaneous surface by carbon dioxide pressurized in the supply space. Therefore, the pressing force brings the absorbent materials 64 and 65 into close contact with the percutaneous surface, so that the efficiency of absorbing carbon dioxide from the percutaneous surface can be further improved. Thus, carbon dioxide can be absorbed into the body via the absorbent material, and effects such as blood circulation promotion can be brought about.

In the description of the third embodiment described above, only the case where a rectangular shape having a hollow inside is used as the joint portion 52 of the enclosure 50 has been described. However, the present invention is not limited to this case. FIG. 10 is a diagram illustrating an example of another enclosure. Note that the enclosure shown in FIG. 10 is illustrated with the locking portion omitted.
The joints 71 (71a, 71b, 71a ′, 71b ′) of the enclosure 70 shown in FIG. 10A are the inner peripheral surfaces of the enclosure member 51, and are provided double along the outer edge. In Fig.10 (a), it has illustrated in the state which cut part of the junction part 71 and the surrounding material 51. FIG. Here, the joint part 71a and the joint part 71a ′ are the same joint part, and the joint part 71b and the joint part 71b ′ are the same joint part. Moreover, the junction part 71 is formed in the hollow cylindrical shape.

  When the user superimposes the joint as shown in FIG. 9 (a) to surround the front leg 1, the envelope 70 shown in FIG. 10 (a) has a connection between the joint 71a and the joint 71b. In the meantime, the joint portions 71a 'or 71b' on the opposite side are fitted and superposed, and then locked by the locking portion. In this way, by configuring the joint portion 71, the joint portion 71 is polymerized several times, so that the carbon dioxide that has been pressurized in the supply space is pressed and prevented from leaking carbon dioxide. Can do.

  The joint portion 73 of the enclosure 72 shown in FIG. 10B is formed to have a three-dimensional shape that matches the percutaneous surface of the horse's front leg 1. That is, the joint portion 73 has a shape in which the tip 73a is thin and thick at the rear portion 73b. Thus, by comprising the joining part 73, since it closely_contact | adheres with the front leg 1 of a horse, the leakage of a carbon dioxide can be prevented as it was pressed with the carbon dioxide pressurized in the supply space.

  In the joint portion 75 of the envelope 74 shown in FIG. 10C, a balloon filled with gas is an inner peripheral surface of the envelope member 51 and is provided along the outer edge. Since the joint 75 formed of a balloon is freely deformable, the joint 75 is freely deformed according to the shape of the percutaneous surface of the horse's front leg 1. Moreover, since the joining part 75 formed of a balloon does not transmit gas, it is possible to prevent carbon dioxide from leaking, assuming that the joint 75 is pressed by carbon dioxide pressurized in the supply space.

  In the above description of the third embodiment, only the enclosure that surrounds the front leg 1 of the horse has been described. However, the present invention is not limited to this case. FIG. 11A shows an example of the shoulder enclosure 80. The shoulder envelope 80 is wrapped around the shoulder so as to cover the entire shoulder. The enclosure 80 includes an enclosure member 81, a joint portion 82, a suction port 83, and locking members 84 (84a and 84b).

  The envelope member 81 is formed in a sheet size so as to cover the entire shoulder. The joining portion 82 is an inner peripheral surface of the surrounding material 81 and is provided along the outer edge of the surrounding material 81. By surrounding the surrounding material 81 so as to be wound around the entire shoulder, a space surrounded by the surrounding material 81, the joint portion 82, and the percutaneous surface is formed as a supply space for supplying carbon dioxide. The suction port 83 has a hole inserted into the supply space described above, and can supply carbon dioxide to the supply space through the hole. The locking member 84 is configured by one locking member 84a of the surrounding member 81 and the other locking member 84b.

  When the enclosure 80 is surrounded by a portion of the horse's percutaneous surface, the user applies an absorbent material to the percutaneous surface of the horse's shoulder. In addition, the user applies a gel-like absorbent material having a medium viscosity or a high viscosity containing a thickener to the portion of the percutaneous surface that contacts the joint portion 82 of the envelope 80. Next, as shown in FIG. 8 (b), the user winds the inner peripheral surface of the enclosure 80 so as to face the percutaneous surface of the horse's shoulder. The user can make the inside of the supply space a sealed structure by locking one locking member 84a provided on the enclosure 80 to the other locking member 84b. Here, only the shoulder enclosure 80 has been described, but as described in the second embodiment, carbon dioxide is absorbed into the body using a waist enclosure or a horse-mounted enclosure. Also good.

  In the above description of the third embodiment, only the enclosure that surrounds the enclosure by wrapping the enclosure around the percutaneous surface of the horse has been described. However, the present invention is not limited to this case. Moreover, although the case where an absorber was made to adhere to a transcutaneous surface by apply | coating an absorber was demonstrated, it is not restricted to this case. Next, a surrounding body that is surrounded by covering at least a part of the percutaneous surface of the horse will be described with reference to FIG. Further, a case where carbon dioxide and an absorbent material are mixed and supplied into the enclosure will be described.

  The enclosure 90 shown in FIG. 12 has an enclosure 91, a suction port 93, and a locking member 94. The surrounding material 91 has a bag shape that can cover the front leg 1 or the rear leg of the horse, and a supply space to which carbon dioxide is supplied is formed in the surrounding body 90. As the material of the surrounding material 91, for example, chloroprene rubber or the like is used. In addition, the surrounding material 91 is formed with an insertion port 92 into which the front leg 1 or the rear leg can be inserted.

The suction port 93 has a hole inserted through the supply space described above, and can supply carbon dioxide to the supply space through the hole.
The locking member 94 is, for example, a belt that can change the position to be locked stepwise or steplessly. The locking member 94 suppresses expansion of the surrounding material 91 due to carbon dioxide compressed in the supply space, or prevents carbon dioxide from leaking outside through the insertion port 92.

  Next, the supply device 60 shown in FIG. 12 is provided with a mist generating device 95. The mist generating device 95 generates mist, preferably nanonized mist (nanomist) from a liquid absorbent material. Here, the absorbent material is a liquid (medium) capable of melting carbon dioxide as described above, and is, for example, water, alcohols, fats and the like. Further, in the mist generating device 95, a connecting tube is provided on the distal end side of the decompressor 62 of the supply device 60 in order to release the generated mist together with the carbon dioxide released from the decompressor 62 of the supply device 60 from the outlet 63. It is connected. Therefore, the carbon dioxide released from the supply device 60 is mixed with the mist absorbent material before reaching the outlet 63 from the connection point of the mist generating device 95. Therefore, the carbon dioxide and the mist-like absorbent are discharged from the outlet 63 of the supply device 60 in a mixed state. Note that carbon dioxide is in a state of being melted to a certain degree in a mist-like absorbent material before reaching the outlet 63 from the connection location. In the mist generating device 95, a nano-ized drug having a DDS effect may be mixed with a mist-like absorbent material. Moreover, you may make it the mist production | generation apparatus 95 spray the nano-ized absorbers, such as water nano-ized from the beginning.

  Next, a method for supplying carbon dioxide and a mist-like absorbent to the inside of the enclosure 90 placed on the front leg 1 by the supply device 60 will be described. First, as shown in FIG. 12, the user connects the suction port 93 of the enclosure 90 and the blowing port 63 of the supply device 60. The user adjusts the desired pressure and flow rate with the decompressor 62 to open the stopper of the decompressor 62 and drives the mist generating device 95 to generate a mist-like absorbent material. Then, carbon dioxide and a mist-like absorbent can be released from the outlet 63 of the supply device 60. The carbon dioxide and the mist-like absorbent supplied from the suction port 93 of the enclosure 90 via the blow-out port 63 of the supply device 60 are uniformly filled in the supply space formed around the front leg 1 of the horse. . At this time, the filled mist-like absorbent material comes into contact with the percutaneous surface of the horse's front leg 1 and thereby adheres to the percutaneous surface and changes to a liquid absorbent material. Here, when nano mist is used as the mist, since the mist particles are very fine, they can easily reach the percutaneous surface through the hair growing on the percutaneous surface. Thus, the carbon dioxide can be absorbed into the body through the absorbent material by adhering the absorbent material in which carbon dioxide is melted to the percutaneous surface of the horse. When a nano-ized drug or the like is mixed with a mist-like absorbent material, the nano-ized drug or the like is absorbed into the body together with the absorbent material, so that it efficiently reaches the affected area to be treated.

  When the user continuously releases the carbon dioxide and the mist-like absorbent, the carbon dioxide and the mist-like absorbent supplied to the supply space are continuously supplied with the carbon dioxide and the mist-like absorbent. Compressed by absorbent material. The pressurized carbon dioxide is efficiently melted in a large amount in the absorbent material attached to the percutaneous surface of the horse's front leg 1. By absorbing the absorbent material in which a large amount of carbon dioxide is melted into the body, more carbon dioxide can be absorbed into the body. In addition, the absorbent material adhering to the transdermal surface is pressed against the transdermal surface by carbon dioxide pressurized in the supply space. Therefore, the pressing force brings the absorbent material and the percutaneous surface into close contact with each other, so that the efficiency of absorbing carbon dioxide from the percutaneous surface can be further improved.

  Thus, according to the third embodiment, carbon dioxide is filled into the supply space formed in the sealed structure. Therefore, since carbon dioxide does not leak from the enclosure, carbon dioxide can be reliably absorbed into the body.

(Fourth embodiment)
The fourth embodiment is an embodiment in the case where carbon dioxide is supplied into the enclosure after the whole body of the percutaneous surface of the horse is enclosed in a sealed state with the enclosure, and the carbon dioxide supplied into the enclosure is It can be pressurized to some extent.
FIG. 13 is a diagram illustrating an example of the configuration of the blood circulation promoting device according to the fourth embodiment. The blood circulation promotion device 4 according to the third embodiment includes an enclosure 100 and a supply device 110. The blood circulation promoting device 4 is fixedly installed in a predetermined facility, for example.

The envelope body 100 includes an envelope box 101, an envelope member 102, a joint portion 103, locking members 104 (104 a to 104 d), and a suction port 105.
The surrounding box 101 is a box formed by four front, rear, left and right surfaces so as to surround the horse. The four surfaces of the enclosing box 101 are made of a material that does not transmit gas. In addition, the back of the four sides of the enclosure 101 is a door that can be opened and closed, for example, up and down so that the horse can enter the enclosure 101. In addition, soft materials are attached to the four inner peripheral surfaces of the surrounding box 101 so that a horse that enters the surrounding box 101 does not come into contact with the surrounding box 101 to be injured. A plurality of hooks 107 for locking the locking members 104 (104a to 104d) are provided on the outer peripheral surface of the surrounding box 101.

  The surrounding material 102 has a shape that can surround the shoulder, back, and waist of the horse, and is formed of a material that does not transmit gas and has excellent weather resistance, such as chlorosulfonated polyethylene (hypalon). An insertion opening into which the head of the horse can be inserted is formed in a part of the surrounding material 102. A joint 103 that contacts the percutaneous surface of the horse is provided at the opening edge of the insertion opening. For example, chloroprene rubber is used as the material of the joint portion 103. Here, the horse's head is protruded from the insertion opening of the surrounding material 102, and the surrounding surface is surrounded by the surrounding material 102 so as to be surrounded by the surrounding material 101 and the surrounding material 102. A space is formed as a supply space for supplying carbon dioxide.

When the locking members 104 a to 104 d cover the four outer peripheral surfaces of the enclosure 101 with the enclosure 102, the carbon dioxide supplied to the supply space does not leak from between the enclosure 102 and the enclosure 101. The surrounding material 102 is locked to the surrounding box 101. The locking members 104a to 104d are made of, for example, rubber that can be expanded and contracted. The locking members 104 a to 104 d are extended from the hooks 107 of the surrounding box 101 and hung around the upper ends of the four faces of the surrounding box 101, thereby locking the surrounding material 102 to the surrounding box 101.
The suction port 105 has a hole inserted into the above-described supply space, and can supply carbon dioxide to the supply space through the hole.

Next, FIG. 13 shows a supply device 110 that supplies carbon dioxide to the supply space formed by the enclosure box 101. The supply device 110 includes a carbon dioxide supply device 111, an air supply device 112, and a concentration adjusting device 113. The carbon dioxide supply device 111 is provided with a container body in which carbon dioxide is highly compressed and accommodated, a decompressor, a scale portion, and a cock portion, and releases the decompressed gaseous carbon dioxide.
The air supply device 112 is provided with a container body in which air is highly compressed and accommodated, a decompressor, a scale portion, and a cock portion, and discharges the decompressed air.

  The concentration adjusting device 113 is for adjusting the concentration of carbon dioxide supplied to the enclosure 100. The carbon dioxide concentration is adjusted by the concentration adjusting device 113 because the speed and amount of carbon dioxide absorption varies depending on the body part of the horse or the individual difference of the horse. By setting the concentration of carbon dioxide according to the difference, it is possible to bring out effects such as blood pressure promotion according to individual differences.

FIG. 14 is a diagram illustrating an example of the configuration of the density adjusting device.
As shown in FIG. 14, the concentration adjusting device 113 is supplied with carbon dioxide from the carbon dioxide supply device 111 and with air from the air supply device 112. The concentration adjusting device 113 includes a route 114 for supplying carbon dioxide, a route 124 for supplying air, pressure adjusting units 115 and 125, check valves 116 and 126, flow meters 117 and 127, and a flow rate adjusting unit 118. 128, a mixer 119, and a discharge valve 120. The flow rate adjusting units 118 and 128 and the mixer 119 constitute a switching device 121.

  The pressure adjusters 115 and 125 adjust the pressures of carbon dioxide and air that have flowed in from the carbon dioxide supply device 111 and the air supply device 112. Here, the user adjusts the pressures of carbon dioxide and air to be equal in each of the pressure adjusting units 115 and 125. Next, the check valves 116 and 126 prevent the backflow of the carbon dioxide and air that flowed in. Next, in the flow meters 117 and 127, the user can check the flow rates of the introduced carbon dioxide and air. Next, the flow rate adjusting units 118 and 128 adjust the concentration of carbon dioxide by changing the flow rates of carbon dioxide and air. Next, the mixer 119 mixes the carbon dioxide and air whose flow rate has been changed in the flow rate adjusting units 118 and 128 to generate carbon dioxide whose concentration is adjusted. Finally, the discharge valve 120 discharges carbon dioxide whose concentration is adjusted by opening the valve. A discharge port is provided at the tip of the discharge valve 120 of the concentration adjusting device 113 and is connected to the suction port 105 of the enclosure 100. Therefore, the carbon dioxide whose concentration is adjusted by the concentration adjusting device 113 is supplied into the enclosure 100.

  The user is not limited to adjusting the concentration of carbon dioxide by changing the flow rate of carbon dioxide and air in each of the flow rate adjustment units 118 and 128. The flow rate adjustment units 118 and 128 and the mixer 119 You may adjust the density | concentration of a carbon dioxide with the switch 121 comprised. Specifically, the user adjusts the concentration of carbon dioxide to 25, 50, 75 percent, etc. stepwise, for example, by rotating the operation knob connected to the switcher 121, etc. The concentration of carbon dioxide can be adjusted. Here, when it is configured to adjust steplessly, it is configured so that the concentration of carbon dioxide can be adjusted to approximately 1000 ppm to approximately 95 percent. The concentration adjusting device 113 may be configured by changing the order of the pressure adjusting units 115 and 125 and the check valves 116 and 126, the order of the check valves 116 and 126 and the flow meters 117 and 127, and the like. It should be noted that a PC (personal computer) may be connected to the density adjustment device 113 so that the density is adjusted from the personal computer.

Next, a method for surrounding the enclosure with a part of the percutaneous surface of the horse and a method for supplying carbon dioxide will be described.
First, the user applies an absorbent material to the percutaneous surface of the whole body of the horse. Here, the absorbing material is a liquid (medium) capable of melting carbon dioxide, and is, for example, water, alcohols, fats and the like. Further, as shown in FIG. 13, the user has a gel-like absorbent material of medium viscosity or high viscosity containing a thickener in a portion of the percutaneous surface that comes into contact with the joint portion 103 of the envelope material 102. 65 is applied. At this time, it is preferable that the user apply the absorbent material 65 thicker. In this way, by applying the absorbent material 65 having a high viscosity, it is possible to prevent gas from leaking from between the percutaneous surface of the horse and the joint 103. In addition, if the absorbent material is made into a nano-structured absorbent material such as nano-structured water, it is easily absorbed into the body from the skin surface.

  Next, the user makes the inner peripheral surface of the surrounding material 102 face the percutaneous surface of the horse and covers the horse with the surrounding material 102. The user protrudes the horse's head from the insertion opening of the surrounding material 102 and accommodates it in the surrounding box 101. Next, the user uses the locking members 104 a to 104 d to lock the surrounding material 102 to the surrounding box 101 to form a supply space surrounded by the surrounding box 101 and the surrounding material 102. Next, the user adjusts the concentration adjusting device 113 so as to obtain an arbitrary carbon dioxide concentration in a state where the blowing port of the supplying device 110 is connected to the suction port 105 of the enclosure 100, and the carbon dioxide supplying device 111. And the cock of the air supply device 112 is released.

  Then, the carbon dioxide whose concentration is adjusted from the suction port 105 of the enclosure 100 is uniformly filled into the supply space through the blowout port of the supply device 110. The user continuously releases carbon dioxide, so that the carbon dioxide supplied to the supply space is compressed by the continuously supplied carbon dioxide. Although the envelope member 102 is expanded by pressurized carbon dioxide, it is a material that does not transmit gas, and the envelope member 102 is locked by the locking member 104. Even if the inside of the 100 is pressurized, carbon dioxide in the supply space does not leak.

  The pressurized carbon dioxide is efficiently melted in a large amount by the absorbent material attached to the transcutaneous surface of the whole body of the horse. By absorbing the absorbent material in which a large amount of carbon dioxide is melted into the body, more carbon dioxide can be absorbed into the body. In addition, the absorbent material attached to the percutaneous surface is pressed against the percutaneous surface by carbon dioxide pressurized in the supply space. Therefore, the pressing force brings the absorbent material and the percutaneous surface into close contact with each other, so that the efficiency of absorbing carbon dioxide from the percutaneous surface can be further improved.

  In the above description of the fourth embodiment, only the case where the absorbent material is applied to the whole body of the horse has been described, but the present invention is not limited to this case. As shown in FIG. 13, the mist generated by the mist generating device 95 may be supplied to the injection port of the concentration adjusting device 113. By using the mist generating device 95 in this way, carbon dioxide and mist can be mixed and supplied to the supply space from the outlet of the supply device 110, so that it is not necessary to apply an absorbent material to the whole body of the horse. . In the mist generating device 95, a nanochemical agent having a DDS effect may be mixed.

Next, the case where the above-described blood circulation promotion device 4 is applied to the blood circulation promotion facility 5 shown in FIG. 15 will be described. In the blood circulation promotion facility 5, the step of supplying the absorbent, the step of supplying carbon dioxide, and the step of drying the absorbent are performed in a room separated in stages.
First, in the room for supplying the absorbent material, a spraying device 301 for spraying the absorbent material in a shower shape from the head of the horse is provided. The absorbent material sprayed by the spraying device 301 adheres to the entire percutaneous surface of the horse. Note that the spraying device 301 is not limited to spraying in a shower shape, and for example, the absorbent material may be supplied in a mist shape, preferably a nanomist shape, or the absorbent material may be supplied in a steam shape.

Next, in the room for supplying carbon dioxide, the blood circulation promoting device 4 having the enclosure 100 and the supply device 110 described above is installed. Since the blood circulation promoting device 4 is the same as that described above, the description thereof is omitted. Next, in the room for drying the absorbent material, a drying device 302 for drying the absorbent material attached to the whole body of the horse is provided. The drying device 302 is configured to blow warm air, for example, over the entire body. In the room for drying the absorbent material, the absorbent material attached to the horse may be simply wiped off.
Thus, in the blood circulation promotion facility 5, a large number of horses can efficiently absorb carbon dioxide in the body.

In the above description of the fourth embodiment, only the case where the blood circulation promoting device 4 is installed and used in a predetermined facility has been described. However, the present invention is not limited to this case. In FIG. 16, the case where the blood circulation promotion apparatus 4 is installed in a transport vehicle is demonstrated. FIG. 16A is a perspective view of the transport vehicle. FIG. 16B is a diagram illustrating the internal configuration of the transport vehicle.
As shown in FIGS. 16A and 16B, the transport vehicle 130 has a vehicle body main body 131 provided with a closed storage 135 for storing the blood circulation promotion device 4 described above. The enclosure 135 stores the enclosure 100 and the supply device 110.

  The rear door 132 of the vehicle body 131 is configured to be able to open and close in the vertical direction. By opening the rear door 132, a slope for introducing the horse into the vehicle body 131 is formed. The vehicle body 131 is provided with a fan 133 for taking outside air into the vehicle body 131 and a fan 134 for discharging the gas in the vehicle body 131 to the outside. That is, when carbon dioxide is supplied to the supply space of the enclosure 100 and then the enclosure 100 is removed from the horse, the body body 131 is filled with carbon dioxide. At this time, by driving the fan 133 and the fan 134, the carbon dioxide filled in the vehicle body 131 can be discharged to the outside. By applying the blood circulation promoting device 4 to a transport vehicle, the blood circulation promoting device 4 can be easily transported.

  Thus, according to the fourth embodiment, carbon dioxide is filled in a state where the enclosure is pressurized using the enclosure that can surround the whole body of the horse. Efficiently melts a large amount into the absorbent material adhering to the skin surface. Therefore, more carbon dioxide can be absorbed in the body by absorbing the absorbent material in which a large amount of carbon dioxide is melted in the body. In addition, since a concentration adjustment device that adjusts the concentration of carbon dioxide supplied by the supply device is added, blood circulation promotion according to individual differences, etc. by adjusting the concentration of carbon dioxide according to the body part of the horse or a fixed difference The effect can be brought out.

(Fifth embodiment)
The fifth embodiment is an embodiment in the case where carbon dioxide is supplied into the enclosure after the whole body of the percutaneous surface of the horse is enclosed in a sealed state with the enclosure, and the carbon dioxide supplied into the enclosure is pressurized. Can be pressurized.
FIG. 17 is a diagram illustrating an example of the configuration of the blood circulation promoting device according to the fifth embodiment. The blood circulation promoting device 6 according to the fifth embodiment includes an enclosure 150, a supply device 160, and a reverse tank 190. The blood circulation promotion device 6 is fixed and installed in a predetermined facility, for example.

The enclosure 150 includes an enclosure 151, an enclosure 152, a joint 153, a locking member 154, a suction port 155, and an insertion port 156.
The encircling box 151 is a box formed by front and rear, right and left, and an upper surface so as to surround the horse. A part of the enclosure 151 has an opening so that the head of the horse can protrude. The five surfaces of the enclosure 151 are formed of a material that does not transmit gas. In addition, the back surface of the five surfaces of the enclosure box 151 is a door (a kannon door) that can be opened and closed from the center to the left and right so that the horse can enter the enclosure box 151. In addition, the upper surface of the five surfaces of the enclosure box 151 is a door that can be opened and closed from the center to the left and right, for example, so that the horse can enter the enclosure box 151 (see FIG. 19A described later). A space surrounded by the enclosure 151 is formed as a supply space for supplying carbon dioxide. The enclosure box 151 is configured to be durable even when the supply space is pressurized to a high pressure.

The surrounding material 152 has a shape that can surround the neck of the horse, and is formed of a material that does not transmit gas, such as a synthetic resin. The enclosure member 152 is integrally attached to the upper surface of the enclosure box 151 described above, and can be opened and closed in the same manner as the upper surface of the enclosure box 151. In addition, a joint portion 153 formed of a material having stretchability, adhesion, flexibility, durability, and airtightness is provided in a portion that contacts the surrounding material 152 and the horse's percutaneous surface.
The locking member 154 locks the joint portion 153 so that carbon dioxide supplied to the supply space does not leak from between the joint portion 153 and the percutaneous surface of the horse.

The suction port 155 has a hole inserted through the supply space described above, and can supply carbon dioxide to the supply space through the hole.
The insertion port 156 has a hole through which the reverse tank 190 is inserted, and transfers carbon dioxide supplied to the supply space through the hole to the reverse tank 190 or transfers carbon dioxide from the reverse tank 190 to the supply space. Can do.

Next, FIG. 17 shows a supply device 160 that supplies carbon dioxide to the supply space formed by the enclosure 150. The supply device 160 includes a carbon dioxide supply device 161, an air supply device 162, and a concentration adjustment device 163. The carbon dioxide supply device 161 is provided with a container body in which carbon dioxide is highly compressed and accommodated, a decompressor, a scale portion, and a cock portion, and discharges decompressed gaseous carbon dioxide.
The air supply device 162 includes a container body in which air is highly compressed and accommodated, a decompressor, a scale portion, and a cock portion, and discharges the decompressed air.

  The concentration adjusting device 163 adjusts the concentration of carbon dioxide supplied to the enclosure 150. The carbon dioxide concentration is adjusted by the concentration adjusting device 163 because the speed and amount of carbon dioxide absorption vary depending on the body part of the horse or the individual difference of the horse. By setting the concentration of carbon dioxide according to the difference, it is possible to bring out effects such as blood pressure promotion according to individual differences. A personal computer is connected to the density adjusting device 163.

FIG. 18 is a diagram illustrating an example of the configuration of the density adjusting device.
As shown in FIG. 18, the concentration adjusting device 163 is supplied with carbon dioxide from the carbon dioxide supply device 161 and with air from the air supply device 162. The concentration adjusting device 163 includes a path 164 for supplying carbon dioxide and a path 174 for supplying air, pressure adjusting units 165 and 175, check valves 166 and 176, residual pressure sensors 167 and 177, and a flow rate adjusting unit. 168, 178, electromagnetic valves 169, 179, a mixer 170, and a discharge electromagnetic valve 171. Further, the concentration adjusting device 163 includes a residual pressure alarm device 172, a control circuit 180, a timer 181, a storage device 182, a power supply circuit 183, a communication device 184, and an operation panel 185.

  In the pressure adjusting units 165 and 175, the user adjusts the carbon dioxide and air pressures flowing from the carbon dioxide supply device 161 and the air supply device 162 to be equal. Next, the check valves 166 and 176 prevent the backflow of the introduced carbon dioxide and air. Next, the residual pressure sensors 167 and 177 measure the pressure of the introduced carbon dioxide and air. The pressure values measured by the residual pressure sensors 167 and 177 are transmitted to the residual pressure alarm device 172. When the transmitted pressure value becomes a predetermined pressure value or less, the residual pressure alarm device 172 issues an alarm that the carbon dioxide supply device 161 and the air supply device 162 have no carbon dioxide or air remaining. Next, the flow rate adjustment units 168 and 178 adjust the concentration of carbon dioxide by changing the flow rates of carbon dioxide and air. Similarly, the solenoid valves 169 and 179 adjust the concentration of carbon dioxide by changing the flow rates of carbon dioxide and air. The concentration adjustment of this embodiment is performed exclusively by the electromagnetic valves 169 and 179, and the flow rate adjustment units 168 and 178 make supplementary adjustments. The concentration adjusting device 163 of the present embodiment is configured so that the concentration of carbon dioxide can be adjusted to approximately 1000 ppm to approximately 95 percent.

Next, the mixer 170 mixes carbon dioxide and air whose flow rates have been changed in the electromagnetic valves 169 and 179 to generate carbon dioxide with adjusted concentration. Finally, the discharge electromagnetic valve 171 discharges carbon dioxide whose concentration is adjusted by opening the valve.
Here, the solenoid valves 169 and 179 and the discharge solenoid valve 171 are connected to the control circuit 180. That is, the control circuit 180 controls the solenoid valves 169 and 179, thereby changing the flow rates of carbon dioxide and air to adjust the concentration of carbon dioxide. Further, the control circuit 180 controls the opening and closing of the discharge electromagnetic valve 171 so that the carbon dioxide whose concentration is adjusted can be discharged or the discharge can be stopped.

  In addition, a timer 181 and an operation panel 185 are connected to the control circuit 180. Therefore, by setting the time for which the user continuously discharges carbon dioxide using the operation panel 185 and the concentration of carbon dioxide, the control circuit 180 can set the solenoid valve based on the set time and concentration. 169 and 179 are controlled so that the set concentration is obtained, and the timer 181 can be used to close the discharge electromagnetic valve 171 and stop the discharge of carbon dioxide when the set time has elapsed. .

Further, a storage device 182 is connected to the control circuit 180. The storage device 182 can store a plurality of programs to be executed by the control circuit 180. Here, the program refers to, for example, discharging the carbon dioxide concentration for the first few minutes at a low concentration, and then discharging the carbon dioxide concentration gradually for several minutes, after a certain period of time, This is for causing the control circuit 180 to execute a menu such as stopping the discharge of carbon. As described above, because the speed and amount of carbon dioxide absorption differ depending on the body part or depending on the individual difference, a program corresponding to the body part and individual difference that the carbon dioxide is to be absorbed is stored in the storage device 182. The user operates the operation panel 185, selects a corresponding program from a plurality of programs stored in the storage device 182, and is executed by the control circuit 180. It is possible to bring out effects such as blood circulation promotion.
The program corresponding to the body part or individual difference described above is not limited to being stored in the storage device 182, but may be configured to be transmitted from the personal computer connected to the communication device 184 to the concentration adjustment device 163. Good. Alternatively, the density adjusting device 163 may be directly controlled from a personal computer connected to the communication device 184.

  The concentration adjusting device 163 may be configured such that the control circuit 180 can also control the pressure adjustment by using an electromagnetic valve for the pressure adjusting units 165 and 175. For example, by creating a program that changes the pressure adjustment of carbon dioxide and air, the pressure of carbon dioxide applied to the percutaneous surface can be changed, so that a massage effect on the percutaneous surface can be expected. Further, the control circuit 180 may control the temperature of carbon dioxide and air by adjusting the pressure. For example, by creating a program that changes the pressure adjustment of carbon dioxide and air, the temperature of the carbon dioxide that has been subjected to concentration adjustment discharged from the concentration adjustment device 163 can be changed. Such an effect can be expected.

  Next, a compressor 191 is connected to the reverse tank 190 shown in FIG. The compressor 191 transfers the carbon dioxide supplied to the supply space to the reverse tank 190. The reverse tank 190 temporarily stores carbon dioxide. The compressor 191 transfers the carbon dioxide returned to the reverse tank 190 to the supply space in order to reuse it. The reverse tank 190 is provided with a carbon dioxide concentration measuring device, and measures whether the carbon dioxide satisfies a predetermined concentration.

  Next, a supply method for supplying carbon dioxide to the enclosure will be described. Note that the method for surrounding the enclosure 150 with a part of the percutaneous surface of the horse is the same as in the fourth embodiment, and a description thereof will be omitted. The user forms a supply space surrounded by the enclosure 150, and then connects the outlet of the supply device 160 to the inlet 155 of the enclosure 150 to a predetermined carbon dioxide concentration based on a predetermined program. Then, the density adjusting device 113 is executed. Then, carbon dioxide adjusted to a predetermined concentration is uniformly filled in the supply space from the supply device 160.

  By continuously releasing carbon dioxide based on the program, the carbon dioxide supplied to the supply space is compressed by the continuously supplied carbon dioxide. Since the enclosure 150 is configured to have durability against high pressure, the enclosure 150 is not damaged even when the enclosure 150 is pressurized at high pressure, and the carbon dioxide in the supply space is not There is no leakage. The pressurized carbon dioxide is efficiently melted in a large amount by the absorbent material attached to the transcutaneous surface of the whole body of the horse. By absorbing the absorbent material in which a large amount of carbon dioxide is melted into the body, more carbon dioxide can be absorbed into the body. In addition, the absorbent material attached to the percutaneous surface is pressed against the percutaneous surface by carbon dioxide pressurized in the supply space. Therefore, this pressing force brings the absorbent material and the percutaneous surface into close contact with each other, so that the efficiency of absorbing carbon dioxide from the percutaneous surface can be further improved.

  Next, when the predetermined time has elapsed and the enclosure 150 is removed, the user uses the compressor 191 to transfer the carbon dioxide supplied to the supply space to the reverse tank 190. Therefore, carbon dioxide is not discharged outside when the enclosure 150 is opened. Next time, when supplying carbon dioxide to the supply space, the user can reuse the carbon dioxide by returning the carbon dioxide stored in the reverse tank to the supply space using the compressor 191. At this time, by measuring the concentration of the reverse tank 190 with the concentration measuring device provided in the reverse tank 190, the supply space is replenished with carbon dioxide adjusted to a predetermined concentration as needed. Thus, the desired carbon dioxide in the supply space can be obtained.

  In the above description of the fifth embodiment, only the case where the absorbent material is applied to the whole body of the horse has been described, but the present invention is not limited to this case. As shown in FIG. 17, the mist generated by the mist generating device 95 may be supplied to the injection port of the concentration adjusting device 163. By using the mist generating device 95 in this way, carbon dioxide and mist can be mixed and supplied to the supply space from the outlet of the supply device 160, so that the work of applying the absorbent material to the whole body of the horse is omitted. can do. In the mist generating device 95, a nanochemical agent having a DDS effect may be mixed.

In the description of the fifth embodiment described above, only the case where the blood circulation promotion device 6 is installed and used in a predetermined facility has been described. However, the present invention is not limited to this case. In FIG. 19, the case where the blood circulation promotion apparatus 6 is installed in a transport vehicle is demonstrated. FIG. 19A is a perspective view of the transport vehicle. FIG. 19B is a diagram illustrating an example of the internal configuration of the transport vehicle.
As shown in FIGS. 19A and 19B, the transport vehicle 200 includes a vehicle body main body 201 provided with a closed storage 207 for storing the blood circulation promotion device 6 described above. A reverse tank 190 is stored in the vehicle body 201.

  The rear door 202 of the vehicle body 201 is configured to be able to open and close in the left-right direction. A slope 203 for introducing the horse into the vehicle body 201 is formed behind the enclosure 150. The vehicle body 201 is provided with a fan 204 that takes outside air into the vehicle body 201 and a fan 205 that discharges the gas in the vehicle body 201 to the outside. In the vehicle body 201, an operation room 206 in which a PC for a user to operate the concentration adjusting device 163 is provided in a room different from the storage 207 in which the blood circulation promotion device 6 is stored. Further, a reverse tank 190 is provided in the vehicle body 201. By applying the blood circulation promoting device 6 to a transport vehicle, the blood circulation promoting device 6 can be easily transported.

  As described above, according to the fifth embodiment, carbon dioxide is filled using an enclosure that is durable against high pressure. Therefore, since the inside of the supply space can be set to a high pressure, carbon dioxide can be further melted in the absorbent material. Therefore, the efficiency of absorbing carbon dioxide into the body through the absorbent material can be improved. In addition, since a concentration adjustment device that automatically adjusts the concentration of carbon dioxide supplied by the supply device has been added, blood circulation promotion according to individual differences can be achieved by adjusting the concentration of carbon dioxide according to body parts or individual differences. The same effect can be brought out.

(Sixth embodiment)
The sixth embodiment is an embodiment having a spraying device for spraying an absorbent material on the percutaneous surface of a horse and an isolation space into which at least a part of the horse can enter.
FIG. 20 is a diagram illustrating an example of the configuration of the blood circulation promotion facility according to the sixth embodiment. FIG. 20A is a diagram illustrating an example of the overall configuration of the blood circulation promotion facility. FIG. 20B is a perspective view of the isolation space. The blood circulation promotion facility 7 according to the sixth embodiment includes a spraying device 311 and an isolation space 312.

The spraying device 311 sprays the absorbent material from above the horse in a shower shape.
The isolation space 312 is a space formed in a concave shape on the floor surface. Slopes 313 are formed at both ends in the longitudinal direction of the isolation space 312 so that the horse can easily enter or leave the isolation space 312. The isolation space 312 is formed to a depth that allows at least the head of the horse to protrude from the upper end of the isolation space 312 when the horse enters the isolation space 312. The isolation space 312 is filled with gaseous carbon dioxide by a carbon dioxide supply device, thereby forming a carbon dioxide pool. Since carbon dioxide has a higher specific gravity than air, it rises from the isolation space 312 and does not float and remains in the isolation space 312. Further, by coloring and mixing a gas having the same specific gravity as that of carbon dioxide, the height of carbon dioxide filled in the isolation space 312 can be easily identified.

Next, a method for absorbing carbon dioxide in the horse's body will be described.
First, the user attaches the absorbent material to the transcutaneous surface of the whole body of the horse by the spraying device 311.
Next, the user enters the horse with the absorbent material attached to the whole body percutaneous surface into the isolated space 312 filled with carbon dioxide. The user places the horse in the isolation space 312 for a predetermined time. At this time, in the isolation space 312, the carbon dioxide filled in the isolation space 312 melts into the absorbent material adhering to the percutaneous surface of the horse, so that the carbon dioxide can be absorbed into the body through the absorbent material. After a predetermined time has elapsed, the user takes out the horse from the isolation space 312. Here, the time for the horse to wait in the isolation space 312 varies depending on the amount of carbon dioxide to be absorbed in the body. For example, when it is desired to absorb a large amount of carbon dioxide, it waits for a long time, and when it is desired to absorb a small amount of carbon dioxide, it waits for a short time.

  In the sixth embodiment described above, only the case where carbon dioxide is supplied to the isolation space has been described. However, the present invention is not limited to this case. For example, carbon dioxide may be generated in the isolated space. For example, as shown in FIG. 21A, dry ice 316 is stored in the bottom of the isolation space 312. By keeping the dry ice 316 at room temperature and normal pressure, it sublimates to produce gaseous carbon dioxide. Therefore, the isolation space 312 can be filled with carbon dioxide. Further, carbon dioxide may be generated by adding normal temperature or high temperature water to the bottom where dry ice is stored. At this time, the isolated space 312 is filled with sublimated carbon dioxide and generated white smoke in the isolated space 312 in a smoke shape.

  Further, the isolation space 312 may have a depth that matches the length of the leg of the horse. As shown in FIG. 21B, the depth of the isolation space 314 is deep enough to hide the leg of the horse. The dry ice 316 stored in the bottom of the isolation space 314 is sublimated by adding normal or high temperature water, and the isolated space 314 is sublimated with carbon dioxide and generated white smoke. The When the horse waits in the isolation space 314, carbon dioxide can be absorbed into the body through the absorbent material. Moreover, since the inside of the isolation space 314 is cooled, there is a cool-down effect.

  Moreover, you may form isolation space continuously. As shown in FIG. 22, a circle-shaped isolation space 315 is formed. The circle-shaped isolation space 315 is filled with gaseous carbon dioxide as described above. By attaching the absorbent material to the horse and moving the isolated space 315, carbon dioxide can be absorbed into the body through the absorbent material during the movement. Therefore, since a plurality of horses can enter the isolation space 315 in succession, the efficiency of absorbing carbon dioxide can be improved.

  Thus, according to the sixth embodiment, the carbon dioxide can be absorbed into the body only by allowing the horse to enter the isolated space supplied to the carbon dioxide, so the efficiency of carbon dioxide is improved.

  As described above, according to the present invention, carbon dioxide can be absorbed into the body, so that cells in the body are activated, and effects such as blood circulation promotion can be brought about. Such effects such as blood circulation promotion can promote metabolism and enhance the healing effect, thereby promoting fatigue recovery, injury prevention, and injury treatment.

In the fourth and fifth embodiments, the case where the gas mixed with carbon dioxide is air has been described. However, the present invention is not limited to this case, and may be nitrogen gas, helium gas, or the like. . The air supply device that supplies air may be a compressor.
In addition, the density adjusting devices according to the fourth and fifth embodiments can be applied to the first to third embodiments and the sixth embodiment described above.
Moreover, when producing carbon dioxide, carbon dioxide may be generated by a chemical reaction between sodium bicarbonate and citric acid. For example, the carbon dioxide filled in the enclosure is pressurized by filling the enclosure of the third embodiment with carbon dioxide generated by a chemical reaction and further causing the chemical reaction to continue.
Moreover, although the 1st-6th embodiment mentioned above demonstrated only the case where a carbon dioxide was absorbed in the body of a horse, animals other than a horse may be sufficient.

It is a figure which shows an example of a structure of the blood circulation promotion apparatus which concerns on 1st Embodiment. It is a figure for demonstrating the method of apply | coating mousse on the percutaneous surface of a horse. It is a figure for demonstrating the effect | action of the bubble-like carbon dioxide contained in a mousse. It is a figure which shows the state which applied mousse to the whole body of a horse. It is a figure which shows an example of a structure of the blood circulation promotion apparatus which concerns on 2nd Embodiment. It is a figure which shows the enclosure of the other form used for 2nd Embodiment. It is a figure which shows the filling part of the enclosure of the other form used for 2nd Embodiment. It is a figure which shows an example of a structure of the blood circulation promotion apparatus which concerns on 3rd Embodiment. It is a figure for demonstrating the method to supply a carbon dioxide to supply space. It is a figure which shows the enclosure of the other form used for 3rd Embodiment. It is a figure which shows the enclosure of the other form used for 3rd Embodiment. It is a figure which shows an example of a structure of the other blood circulation promotion apparatus which concerns on 3rd Embodiment. It is a figure which shows an example of a structure of the blood circulation promotion apparatus which concerns on 4th Embodiment. It is a figure which shows an example of a structure of a density | concentration adjustment apparatus. It is a figure which shows an example of a structure at the time of applying a blood circulation promotion apparatus to a blood circulation promotion facility. It is a figure which shows an example of a structure in the case of installing a blood circulation promotion apparatus in a transport vehicle. It is a figure which shows an example of a structure of the blood circulation promotion apparatus which concerns on 5th Embodiment. It is a figure which shows an example of a structure of a density | concentration adjustment apparatus. It is a figure which shows an example of a structure in the case of installing a blood circulation promotion apparatus in a transport vehicle. It is a figure which shows an example of a structure of the blood circulation promotion facility which concerns on 6th Embodiment. It is a figure which shows the blood circulation promotion facility of another form. It is a figure which shows the blood circulation promotion facility of another form.

Explanation of symbols

DESCRIPTION OF SYMBOLS 2 Blood circulation promoting device 3 Blood circulation promoting device 4 Blood circulation promoting device 5 Blood circulation promoting facility 6 Blood circulation promoting device 7 Blood circulation promoting facility 10 Moose generating device 20 Moose 30 Enclosure 33 Filling portion 41 Filling portion 50 Enclosure 52 Junction portion 60 Supply device 64 Absorption Material 65 Absorber 90 Enclosure 95 Mist generating device 100 Enclosure 110 Supply device 113 Concentration adjustment device 301 Spraying device 135 Hangar 150 Enclosure 160 Supply device 163 Concentration adjustment device 207 Hangar 312 Isolation space 312 Isolation space 314 Isolation space 315 Isolation space 315

Claims (18)

  A horse blood circulation promotion device comprising a supply device for supplying carbon dioxide gas in order to cause the absorbent material attached to the percutaneous surface of the horse to absorb carbon dioxide gas. The absorbent material is a foamy mousse,
2. The horse blood circulation promoting device according to claim 1, wherein the supply device supplies bubbled carbon dioxide gas in the mousse. Further comprising an enclosure surrounding at least a portion of the horse's percutaneous surface;
The equine blood circulation promoting device according to claim 2, wherein a portion of the enclosure facing the percutaneous surface has a filling portion for filling the mousse supplied from the supply device.   4. The horse blood circulation promoting device according to claim 3, wherein the filling portion is a mousse containing portion made of a material capable of transmitting the mousse to the percutaneous surface side. Further comprising an enclosure surrounding at least a portion of the horse's percutaneous surface;
2. The horse blood circulation promoting device according to claim 1, wherein the supply device supplies carbon dioxide gas into the enclosure.   6. The horse blood circulation promotion device according to claim 5, wherein the enclosure has a sealed structure so as not to discharge the supplied carbon dioxide gas to the outside.   The horse blood circulation promoting device according to claim 5 or 6, wherein the supply device supplies the absorbent together with carbon dioxide.   The equine blood circulation promoting device according to any one of claims 5 to 7, further comprising a reverse tank for temporarily storing carbon dioxide gas supplied to the enclosure.   The horse blood circulation promoting device according to any one of claims 5 to 8, further comprising a concentration adjusting device that adjusts the concentration of carbon dioxide gas with respect to the carbon dioxide gas supplied by the supply device. A hangar for storing the enclosure and the horse;
The blood circulation promoting device for horse according to any one of claims 5 to 9, wherein the hangar has a sealed structure.   The horse according to any one of claims 3 to 10, wherein the enclosure surrounds any one of a whole body, a shoulder, a back, a waist, a front leg, and a rear leg among percutaneous surfaces of the horse. Blood circulation promotion device. A spraying device that sprays absorbent material onto the percutaneous surface of the horse;
An equine blood circulation facilitating facility comprising an isolation space filled with carbon dioxide and into which at least a part of a horse part to which the absorbent material is attached enters.   The horse blood circulation promotion facility according to claim 12, wherein the isolation space is formed in a concave shape with respect to the floor surface via a slope. Attaching an absorbent material to the transdermal surface of the horse;
A step of absorbing carbon dioxide in the adhering absorbent material;
A method of promoting blood circulation for horses, comprising the step of absorbing carbon dioxide into the horse's body through the absorbent material having absorbed carbon dioxide. Enclosing the enclosure on the percutaneous surface of the horse;
The horse blood circulation promotion method according to claim 14, further comprising a step of supplying carbon dioxide into the enclosure.   The method for promoting blood circulation for horses according to claim 15, further comprising a step of pressurizing carbon dioxide gas supplied into the enclosure.   The horse blood circulation promotion method according to claim 15 or 16, further comprising a step of adjusting a concentration of carbon dioxide with respect to carbon dioxide supplied into the enclosure. An enclosure surrounding at least a portion of a horse's transcutaneous surface,
It has a supply space for supplying carbon dioxide inside,
An enclosure characterized in that it is made of a material that has adhesiveness at a joint portion that comes into contact with a percutaneous surface and has durability against pressure applied to the carbon dioxide gas supplied to the inside.

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