JP2017055794A - High pressure trauma therapy device - Google Patents

Abstract

A high-pressure trauma treatment apparatus that can be used in combination with high-pressure oxygen treatment and high-concentration carbonic acid treatment is provided. One end side is connected to a high-pressure oxygen gas source, an oxygen gas supply pipe that supplies oxygen gas from the high-pressure oxygen gas source, and one end side is connected to a high-pressure carbon dioxide source. Carbon dioxide gas supply pipe L2 for supplying carbon dioxide gas from one end, one end side is connected to the other end side of the oxygen gas supply pipe L1 and the other end side of the carbon dioxide gas supply pipe L2, respectively, and the other end side is the treatment gas supply unit 4 And a switching means for selecting a gas to be supplied to the treatment gas supply unit 4 and a treatment gas supply line L3 for supplying the gas supplied from the oxygen gas supply line L1 or the carbon dioxide supply line L2 to the treatment gas supply unit 4 The high-pressure trauma treatment apparatus 1 is selected. [Selection] Figure 1

Description

  The present invention relates to a high-pressure trauma treatment apparatus.

  High-pressure oxygen treatment and high-concentration carbonic acid treatment are known as methods for treating trauma and damage to the skin and mucous membrane using high-pressure gas.

  Hyperbaric oxygen therapy is a treatment that uses high-pressure oxygen gas to treat skin damage such as trauma, burns, and pressure sores. For example, Patent Document 1 discloses a high-pressure oxygen treatment apparatus for performing high-pressure oxygen treatment.

  The amount of oxygen dissolved in blood (dissolved oxygen) can be increased by the high-pressure oxygen treatment apparatus. Therefore, oxygen transport and oxygen diffusion in the tissue increase, and the tissue can be oxygenated. As a result, it is possible to improve the oxygen state of a tissue that has fallen into an ischemic / hypoxic state. Furthermore, by improving the oxygen state of the tissue, secondary effects such as wound healing promotion effect, tissue regeneration promotion (tissue oxygenation), surrounding tissue oxygenation, fibroblast proliferation (angiogenesis), etc. Can be obtained. Moreover, bacteria in the atmosphere can be prevented from approaching the affected area, and the risk of infection can be reduced.

  On the other hand, high-concentration carbonic acid treatment is a treatment method for treating trauma using high-concentration carbon dioxide gas. For example, Patent Document 2 discloses a high-concentration carbonic acid treatment device for performing high-concentration carbonic acid treatment.

  By absorbing carbon dioxide through the skin through high-concentration carbonic acid treatment, it is possible to obtain an effect of recovery / enhancement of muscle strength and an effect of trauma treatment by vasodilatory action. Moreover, the risk of infectious diseases can be reduced similarly to hyperbaric oxygen treatment.

  By the way, depending on the symptom of the patient, there are cases where it is desired to treat both the trauma treatment effect by the improvement of ischemia and hypoxia by the high pressure oxygen gas and the treatment effect by the high concentration carbon dioxide gas. That is, there is a case where both high pressure oxygen treatment and high concentration carbonic acid treatment are desired.

JP 2013-230385 A JP 2007-181720 A

  However, when performing both high pressure oxygen treatment and high concentration carbonic acid treatment, it is necessary to prepare both a high pressure oxygen treatment device and a high concentration carbonic acid treatment device. For this reason, there are problems that it is difficult to secure the installation location of the apparatus and that the cost for preparing the apparatus is high.

  This invention is made | formed in view of the said situation, Comprising: It makes it a subject to provide the high pressure trauma treatment apparatus which can be used together with a high pressure oxygen treatment and a high concentration carbonic acid treatment.

In order to solve the above problem, the invention according to claim 1
One end side is connected to a high-pressure oxygen gas source, an oxygen gas supply pipe for supplying oxygen gas from the high-pressure oxygen gas source,
One end side is connected to a high-pressure carbon dioxide gas source, a carbon dioxide gas supply pipe for supplying carbon dioxide gas from the high-pressure carbon dioxide gas source,
One end side is connected to the other end side of the oxygen gas supply pipe and the other end side of the carbon dioxide supply pipe, respectively, and the other end side is connected to a treatment gas supply unit, and the oxygen gas supply pipe or the carbon dioxide supply A treatment gas supply pipe for supplying the gas supplied from the pipe to the treatment gas supply unit;
And a switching means for selecting a gas to be supplied to the treatment gas supply unit.

The invention according to claim 2
The high-pressure trauma treatment apparatus according to claim 1, further comprising an exhaust pipe provided by branching at least one of the oxygen gas supply pipe, the carbon dioxide supply pipe, and the treatment gas supply pipe. is there.

The invention according to claim 3
3. The high-pressure trauma treatment apparatus according to claim 1, further comprising a detection unit that detects a concentration of at least one of oxygen and carbonic acid in an external atmosphere of the apparatus.

The invention according to claim 4
4. The apparatus according to claim 1, further comprising a supply pipe for supplying another gas from a supply source provided outside the apparatus, to at least one of the oxygen gas supply pipe and the carbon dioxide supply pipe. The high-pressure trauma treatment device described.

The invention according to claim 5
The high-pressure trauma treatment device according to any one of claims 1 to 4, further comprising a control device that controls the switching means.

  The high-pressure trauma treatment apparatus of the present invention has one end connected to a high-pressure oxygen gas source, an oxygen gas supply pipe for supplying oxygen gas from the high-pressure oxygen gas source, and one end connected to a high-pressure carbon dioxide gas source. Carbon dioxide gas supply pipe for supplying carbon dioxide gas, and one end side is connected to the other end side of the oxygen gas supply pipe and the other end side of the carbon dioxide gas supply pipe, respectively, and the other end side is connected to the treatment gas supply unit, Since it has a treatment gas supply pipe for supplying the gas supplied from the oxygen gas supply pipe or the carbon dioxide supply pipe to the treatment gas supply section and a switching means for selecting the gas to be supplied to the treatment gas supply section, It can be used in combination with high-concentration carbonic acid treatment.

It is a systematic diagram showing a configuration of a high-pressure trauma treatment apparatus that is an embodiment to which the present invention is applied.

  Hereinafter, a high-pressure trauma treatment apparatus according to an embodiment to which the present invention is applied will be described in detail. In addition, in the drawings used in the following description, in order to make the features easy to understand, there are cases where the portions that become the features are enlarged for the sake of convenience, and the dimensional ratios of the respective components are not always the same as the actual ones. Absent.

<High-pressure trauma treatment device>
First, the configuration of a high-pressure trauma treatment apparatus that is an embodiment to which the present invention is applied will be described. FIG. 1 is a system diagram showing a configuration of a high-pressure trauma treatment apparatus 1 that is an embodiment to which the present invention is applied. As shown in FIG. 1, a high-pressure trauma treatment apparatus 1 according to this embodiment includes a high-pressure oxygen gas source 2, a high-pressure carbon dioxide gas source 3, an oxygen gas supply pipe L1, a carbon dioxide supply pipe L2, and a treatment gas supply pipe. L3, treatment gas supply hose L4, treatment gas supply part 4, purge piping (exhaust piping) L5, decompression line L6, case 5, and control device 6 are roughly constituted. .

  In the high-pressure trauma treatment apparatus 1 of the present embodiment, the high-pressure oxygen gas source 2, the high-pressure carbon dioxide source 3, the oxygen gas supply pipe L1, the carbon dioxide supply pipe L2, the treatment gas supply pipe L3, and the purge pipe L5 A part and the control device 6 are provided inside the housing 5.

  The high-pressure trauma treatment apparatus 1 of this embodiment is a therapeutic apparatus for using both high-pressure oxygen treatment and high-concentration carbonic acid treatment.

The high-pressure oxygen gas source 2 is connected to one end side of the oxygen gas supply pipe L1. Thereby, oxygen gas can be supplied from the high-pressure oxygen gas source 2 into the oxygen gas supply pipe L1.
Specifically, as the high-pressure oxygen gas source 2, for example, a compressed oxygen gas filled in a container made of a known material such as FRP (Fiber Reinforced Plastics), steel, or aluminum can be used.

  Moreover, it does not specifically limit as an internal volume of the container used for the high pressure oxygen gas source 2, For example, a 100 mL-1000 mL, Preferably a 300 mL-700 mL small container etc. can be used. By using a small container of 100 mL to 1000 mL, preferably 300 mL to 700 mL, the entire apparatus can be downsized.

The high-pressure carbon dioxide source 3 is connected to one end side of the carbon dioxide supply pipe L2. As a result, carbon dioxide can be supplied from the high-pressure carbon dioxide source 3 into the carbon dioxide supply pipe L2.
Specifically, as the high-pressure carbon dioxide gas source 3, for example, compressed carbon dioxide gas filled in a container made of a known material such as FRP, steel, or aluminum can be used.

  Moreover, it does not specifically limit as an internal volume of the container used for the high pressure carbon dioxide gas source 3, For example, a 100 mL-1000 mL, Preferably a 300 mL-700 mL small container etc. can be used. By using a small container of 100 mL to 1000 mL, preferably 300 mL to 700 mL, the entire apparatus can be downsized.

  One end of the oxygen gas supply pipe L1 is connected to the high-pressure oxygen gas source 2. The oxygen gas supplied from the high-pressure oxygen gas source 2 circulates inside the oxygen gas supply pipe L1. The other end of the oxygen gas supply pipe L1 is connected to the carbon dioxide supply pipe L2 and the treatment gas supply pipe L3 via, for example, a three-way valve. Thereby, oxygen gas can be supplied to the treatment gas supply pipe L3 via the oxygen gas supply pipe L1.

An oxygen pressure sensor 7 is provided in the oxygen gas supply pipe L1. The pressure of the gas inside the oxygen gas supply pipe L1 can be measured by the oxygen pressure sensor 7.
The oxygen pressure sensor 7 is electrically connected to the control device 6 via a signal line C1. The pressure value measured by the oxygen pressure sensor 7 is transmitted to the control device 6 via the signal line C1.

An oxygen flow meter 8 is provided on the secondary side of the oxygen pressure sensor 7 in the oxygen gas supply pipe L1. The flow rate of the gas inside the oxygen gas supply pipe L1 can be measured by the oxygen flow meter 8.
The oxygen flow meter 8 is electrically connected to the control device 6 through a signal line C2. The flow rate value measured by the oxygen flow meter 8 is transmitted to the control device 6 via the signal line C2.

  An oxygen sterilization filter 9 is provided on the secondary side of the oxygen flow meter 8 in the oxygen gas supply pipe L1. The oxygen sterilization filter 9 can sterilize the oxygen gas flowing through the oxygen gas supply pipe L1.

An oxygen supply valve 10 is provided on the secondary side of the oxygen sterilization filter 9 in the oxygen gas supply pipe L1. By controlling the opening and closing of the oxygen supply valve 10, the supply of oxygen gas from the oxygen gas supply pipe L1 to the treatment gas supply pipe L3 can be controlled.
The oxygen supply valve 10 is electrically connected to the control device 6 through a signal line C3. The controller 6 can control the opening / closing of the oxygen supply valve 10 via the signal line C3.

  One end side of the carbon dioxide supply pipe L2 is connected to the high-pressure carbon dioxide source 3. Carbon dioxide gas supplied from the high-pressure carbon dioxide source 3 circulates inside the carbon dioxide supply pipe L2. In addition, the other end of the carbon dioxide supply pipe L2 is connected to the oxygen gas supply pipe L1 and the treatment gas supply pipe L3 via, for example, a three-way valve. Thereby, carbon dioxide gas can be supplied to the treatment gas supply pipe L3 via the carbon dioxide supply pipe L2.

A carbonic acid pressure sensor 11 is provided in the carbon dioxide gas supply pipe L2. The pressure of the gas inside the carbon dioxide supply pipe L2 can be measured by the carbon dioxide pressure sensor 11.
The carbonic acid pressure sensor 11 is electrically connected to the control device 6 via a signal line C4. The pressure value measured by the carbonic acid pressure sensor 11 is transmitted to the control device 6 via the signal line C4.

A carbonic acid flow meter 12 is provided on the secondary side of the carbonic acid pressure sensor 11 in the carbonic acid gas supply pipe L2. The flow rate of the gas inside the carbon dioxide supply pipe L2 can be measured by the carbon dioxide flow meter 12.
The carbonic acid flow meter 12 is electrically connected to the control device 6 through a signal line C5. The flow rate value measured by the carbonic acid flow meter 12 is transmitted to the control device 6 via the signal line C5.

  A carbonic acid sterilization filter 13 is provided on the secondary side of the carbonic acid flow meter 12 in the carbonic acid gas supply pipe L2. The carbon dioxide sterilization filter 13 can sterilize the carbon dioxide flowing through the carbon dioxide supply pipe L2.

A carbon dioxide supply valve 14 is provided on the secondary side of the carbonic acid sterilization filter 13 in the carbon dioxide supply pipe L2. By controlling the opening and closing of the carbon dioxide supply valve 14, the supply of carbon dioxide from the carbon dioxide supply pipe L2 to the treatment gas supply pipe L3 can be controlled.
The carbonic acid supply valve 14 is electrically connected to the control device 6 through a signal line C6. The controller 6 can control the opening and closing of the carbonic acid supply valve 14 via the signal line C6.

  In the high-pressure trauma treatment apparatus 1 of the present embodiment, the oxygen supply valve 10 and the carbonic acid supply valve 14 described above are used as switching means, so that the gas supplied to the treatment gas supply pipe L3 is supplied from the oxygen gas supply pipe L1. Oxygen gas or carbon dioxide supplied from the carbon dioxide supply pipe L2 can be selected. As a result, oxygen gas or carbon dioxide gas can be selected as a gas to be supplied to the treatment gas supply unit 4, so that high pressure oxygen treatment and high concentration carbon dioxide treatment can be performed by the high pressure trauma treatment apparatus 1.

  The treatment gas supply pipe L3 has one end connected to the oxygen gas supply pipe L1 and the carbon dioxide supply pipe L2, and the other end connected to the treatment gas supply hose L4 via a joint 15 provided in the housing 5. . Therefore, by controlling the opening and closing of the oxygen supply valve 10 and the carbon dioxide supply valve 14, the oxygen gas supplied from the oxygen gas supply pipe L1 or the carbon dioxide supply pipe L2 is supplied via the treatment gas supply pipe L3. Carbon dioxide gas can be selected and supplied to the treatment gas supply hose L4.

A therapeutic gas supply valve 16 is provided in the therapeutic gas supply pipe L3. By controlling the opening / closing degree of the treatment gas supply valve 16, the supply amount of oxygen gas or carbon dioxide gas from the treatment gas supply pipe L3 to the treatment gas supply hose L4 can be controlled.
The therapeutic gas supply valve 16 is electrically connected to the control device 6 via a signal line C7. The control device 6 can control the degree of opening and closing of the treatment gas supply valve 16 via the signal line C7.

  The treatment gas supply hose L4 has one end connected to the treatment gas supply pipe L3 via the joint 15 and the other end connected to the treatment gas supply unit 4. Oxygen gas or carbon dioxide gas supplied from the treatment gas supply pipe L3 can be supplied to the treatment gas supply unit 4 by the treatment gas supply hose L4.

  The therapeutic gas supply unit 4 is connected to a therapeutic gas supply hose L4. The treatment gas supply unit 4 can supply oxygen gas or carbon dioxide supplied from the treatment gas supply hose L4 to the affected part of the patient.

  The shape of the treatment gas supply unit 4 is not particularly limited as long as it surrounds the surface including the affected part and can be a pressure higher than the atmospheric pressure. Specifically, for example, when an affected part is present on a patient's limb, it is preferable to use a cylindrical bag having a diameter of 10 to 15 cm that wraps around the limb. In this case, the material is preferably a resin film such as a polypropylene film or a polyethylene film that is transparent so that the inside can be visually observed and is excellent in waterproofness and pressure resistance. When the treatment gas supply unit 4 is in a bag shape, high pressure can be maintained by sealing the affected part with a bag and then sealing the opening with the adhesive tape or the like.

  For example, when the affected part is a trunk such as pressure ulcer, the shape of the treatment gas supply unit 4 may be a cup shape having an opening large enough to cover the affected part. In this case, it is preferable to use a rigid material such as resin or metal as the material. The treatment gas supply unit 4 may be replaceable. In other words, a plurality of treatment gas supply units 4 having a shape and a material corresponding to the affected part may be prepared and appropriately selected and used.

  One end side of the purge pipe L5 is connected to the treatment gas supply pipe L3 on the primary side of the treatment gas supply valve 16, and the other end side is provided so that a purge pump (not shown) can be connected. The purge pipe L5 can purge the gas inside the oxygen gas supply pipe L1, the carbon dioxide supply pipe L2, and the treatment gas supply pipe L3. Thereby, it can suppress that gas other than the gas used for a treatment is supplied to an affected part via the treatment gas supply part 4. FIG.

A purge valve 17 is provided in the purge pipe L5. By controlling the opening and closing of the purge valve 17, the purge of the gas in the pipe can be controlled.
The purge valve 17 is electrically connected to the control device 6 through a signal line C8. The controller 6 can control the opening and closing of the purge valve 17 via the signal line C8.

The decompression line L6 has one end connected to the treatment gas supply hose L4 and the other end open to the outside. A pressure reducing valve 18 is provided in the pressure reducing line L6. The pressure inside the treatment gas supply unit 4 can be appropriately adjusted by exhausting the gas inside the treatment gas supply unit 4 to the outside via the pressure reduction line L6 as necessary by the pressure reducing valve 18. Thereby, the flow volume of the gas supplied to the treatment gas supply part 4 can be adjusted appropriately.
The pressure reducing valve 18 is electrically connected to the control device 6 through a signal line C9. The controller 6 can control the opening and closing of the pressure reducing valve 18 via the signal line C9.

  A high-pressure oxygen gas source 2 and a high-pressure carbon dioxide gas source 3 are provided inside the housing 5. The high-pressure trauma treatment apparatus 1 of the present embodiment can be freely carried and moved by providing the high-pressure oxygen gas source 2 and the high-pressure carbon dioxide gas source 3 in the housing 5. In addition, since it is not necessary to prepare a gas source separately, the gas source can be used not only in a medical facility equipped with medical gas pipes and the like but also in, for example, a general household or a care facility.

On the side surface of the housing 5, an oxygen gas detector 19, which is a detecting means for detecting the oxygen concentration, is provided so that the detection portion is located outside the housing 5. The oxygen gas detector 19 can measure the oxygen concentration outside the housing 5.
The oxygen gas detector 19 is electrically connected to the control device 6 through a signal line C10. The value of the oxygen concentration measured by the oxygen gas detector 19 is transmitted to the control device 6 via the signal line C10.

On the side surface of the housing 5, a carbon dioxide gas detector 20, which is a detecting means for detecting the carbon dioxide concentration, is provided so that the detection portion is located outside the housing 5. With the carbon dioxide gas detector 20, the carbon dioxide concentration outside the housing 5 can be measured.
The carbon dioxide detector 20 is electrically connected to the control device 6 through a signal line C11. The value of the carbon dioxide concentration measured by the carbon dioxide gas detector 20 is transmitted to the control device 6 through the signal line C11.

  The control device 6 is connected to the oxygen pressure sensor 7, the oxygen flow meter 8, the oxygen supply valve 10, the carbonic acid pressure sensor 11, the carbonic acid flow meter 12, the carbonic acid supply valve 14, and the treatment gas via the signal lines C 1 to C 11. The supply valve 16, the purge valve 17, the pressure reducing valve 18, the oxygen gas detector 19 and the carbon dioxide gas detector 20 are electrically connected to each other.

  The control device 6 controls the open / close state of the oxygen supply valve 10, the carbon dioxide supply valve 14, the treatment gas supply valve 16, and the purge valve 17, thereby switching between oxygen gas and carbon dioxide gas, sequence control of gas supply and purge, etc. It can be controlled by the method.

  The control device 6 is supplied to the treatment gas supply unit 4 by controlling the pressure reducing valve 18 based on the pressure value measured by the pressure sensors 7 and 11 and the flow value measured by the flow meters 8 and 12. It is possible to appropriately adjust the flow rate of the gas.

  When the control device 6 detects that the pressure value measured by the pressure sensors 7 and 11 and the flow value measured by the flow meters 8 and 12 are out of the setting range, an alarm or the like may be issued. . Thereby, it is possible to notify the user of gas leakage, cylinder replacement time, and maintenance time.

  When the control device 6 detects that the oxygen concentration measured by the oxygen gas detector 19 or the carbon dioxide concentration measured by the carbon dioxide detector 20 exceeds the set value, the oxygen supply valve 10, the carbon dioxide supply valve 14, the treatment gas By automatically closing the supply valve 16 as necessary, it is possible to prevent the environment around the apparatus from becoming an oxygen-deficient state or an oxygen-enriched state.

<How to use the high-pressure trauma treatment device>
Next, a method of using the above-described high-pressure trauma treatment apparatus 1 will be described in detail with reference to FIG.
Here, a case where high-pressure oxygen treatment is performed using the above-described high-pressure trauma treatment apparatus 1 and then switched to high-concentration carbonic acid treatment will be described as an example. In the high-pressure trauma treatment apparatus 1 before use, the oxygen supply valve 10, the carbon dioxide supply valve 14, the treatment gas supply valve 16, the purge valve 17, and the pressure reducing valve 18 are all closed.

  When starting the high-pressure oxygen treatment, first, the control device 6 opens the purge valve 17 to purge the gas in the treatment gas supply pipe L3. Thereby, it can suppress that gas other than oxygen gas is supplied to the treatment gas supply part 4. FIG. After the gas has been sufficiently purged, the purge valve 17 is returned to the closed state.

  Next, the control device 6 opens the oxygen supply valve 10 and the treatment gas supply valve 16 to supply oxygen gas from the high-pressure oxygen gas source 2 to the treatment gas supply unit 4. During the supply of oxygen gas, the control device 6 controls the pressure reducing valve 18 based on the pressure value measured by the oxygen pressure sensor 7 and the flow value measured by the oxygen flow meter 8, thereby supplying the treatment gas. The flow rate of the oxygen gas supplied to the unit 4 is adjusted appropriately. As a result, high pressure oxygen treatment can be performed by supplying oxygen gas to the affected area of the patient inside the treatment gas supply unit 4.

  When the high-pressure oxygen treatment is completed, the control device 6 returns the oxygen supply valve 10 and the treatment gas supply valve 16 to the closed state, thereby stopping the supply of oxygen gas from the high-pressure oxygen gas source 2 to the treatment gas supply unit 4.

  Next, in order to switch from high-pressure oxygen treatment to high-concentration carbonic acid treatment, the control device 6 opens the purge valve 17 to purge oxygen gas remaining in the treatment gas supply pipe L3. Thereby, it can suppress that gas other than a carbon dioxide gas is supplied to the treatment gas supply part 4. FIG. After the gas has been sufficiently purged, the purge valve 17 is returned to the closed state.

  Next, the control device 6 opens the carbon dioxide supply valve 14 and the therapeutic gas supply valve 16 to supply carbon dioxide from the high-pressure carbon dioxide source 3 to the therapeutic gas supply unit 4. During the supply of the carbon dioxide gas, the control device 6 controls the pressure reducing valve 18 based on the pressure value measured by the carbon dioxide pressure sensor 11 and the flow value measured by the carbon dioxide flow meter 12, thereby supplying the treatment gas. The flow rate of the carbon dioxide gas supplied to the unit 4 is adjusted appropriately. As a result, high-concentration carbonic acid treatment can be performed by supplying carbon dioxide gas to the affected area of the patient inside the therapeutic gas supply unit 4.

When the high-concentration carbonic acid treatment is completed, the control device 6 returns the carbonic acid supply valve 14 and the therapeutic gas supply valve 16 to the closed state, thereby stopping the supply of carbon dioxide from the high-pressure carbon dioxide source 3 to the therapeutic gas supply unit 4. .
By the above operation, it is possible to perform high-pressure oxygen treatment using the above-described high-pressure trauma treatment apparatus 1 and then switch to high-concentration carbonic acid treatment.

  As described above, according to the high-pressure trauma treatment apparatus 1 of the present embodiment, one end side is connected to the high-pressure oxygen gas source 2, the oxygen gas supply pipe L1 that supplies oxygen gas from the high-pressure oxygen gas source 2, and one end The carbon dioxide gas supply line L2 is connected to the high-pressure carbon dioxide gas source 3 to supply the carbon dioxide gas from the high-pressure carbon dioxide gas source 3, and one end side is the other end side of the oxygen gas supply pipe L1 and the other end side of the carbon dioxide gas supply pipe L2. And a treatment gas supply line L3 for supplying the gas supplied from the oxygen gas supply line L1 or the carbon dioxide supply line L2 to the treatment gas supply part 4 Since it has the oxygen supply valve 10 and the carbonic acid supply valve 14 for selecting the gas to be supplied to the treatment gas supply unit 4, it can be used together with the high pressure oxygen treatment and the high concentration carbonic acid treatment. Thereby, there are advantages such as shortening of the treatment time and saving of space for installing the treatment apparatus.

  Further, according to the high-pressure trauma treatment apparatus 1 of the present embodiment, a purge pipe L5 provided by branching at least one of the oxygen gas supply pipe L1, the carbon dioxide supply pipe L2, and the treatment gas supply pipe L3. Therefore, it is possible to suppress the supply of gas other than the gas used for treatment to the affected area via the treatment gas supply unit 4.

  In addition, according to the high-pressure trauma treatment apparatus 1 of the present embodiment, since the oxygen gas detector 19 and the carbon dioxide gas detector 20 are further provided, when it is detected that the oxygen concentration or the carbon dioxide concentration has deviated from the set value, oxygen supply is performed. By closing the valve 10, the carbonic acid supply valve 14, and the treatment gas supply valve 16 as necessary, it is possible to prevent the surrounding environment of the high-pressure trauma treatment apparatus 1 from becoming an oxygen-deficient state or an oxygen-enriched state. Can do.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes designs and the like that do not depart from the gist of the present invention.

  In the high-pressure trauma treatment apparatus 1 described above, the example using the gas supplied from the high-pressure oxygen gas source 2 and the high-pressure carbon dioxide gas source 3 has been described, but the present invention is not limited to this form. For example, at least one of the oxygen gas supply pipe L1 and the carbon dioxide supply pipe L2 may further include a supply pipe for supplying other gas from a supply source provided outside the high-pressure trauma treatment apparatus 1. Thereby, not only the gas source in the apparatus but also a gas source outside the apparatus can be arbitrarily selected.

  In the above-described high-pressure trauma treatment apparatus 1, the example in which the high-pressure oxygen gas source 2 and the high-pressure carbon dioxide gas source 3 are provided inside the housing 5 has been described. However, the present invention is not limited to this configuration. For example, either one or both of the high-pressure oxygen gas source 2 and the high-pressure carbon dioxide gas source 3 may be provided outside the housing 5.

  Further, in the above-described high-pressure trauma treatment apparatus 1, the example in which the oxygen gas detector 19 and the carbon dioxide gas detector 20 are provided on the side surface of the housing 5 has been described. You may install in the place. For example, the oxygen gas detector 19 and the carbon dioxide gas detector 20 may be provided in the treatment gas supply unit 4 or in the vicinity thereof. As a result, the oxygen concentration and the carbonic acid concentration around the patient can be detected, which is more effective in preventing an oxygen deficient state and an oxygen enriched state.

  Moreover, the treatment gas supply part 4 of the high-pressure trauma treatment apparatus 1 described above may include a device for keeping the affected part warm or cooled as necessary.

  Further, the oxygen gas supply pipe L1 and the carbon dioxide supply pipe L2 of the high-pressure trauma treatment apparatus 1 described above include a check valve for preventing a back flow of gas and a pressure reducing valve for reducing the pressure in the pipe. There may be.

  Moreover, the housing | casing 5 of the high pressure trauma treatment apparatus 1 mentioned above may be provided with the caster for moving an apparatus to the bottom part, side surface, etc. of a housing | casing.

  The high-pressure trauma treatment apparatus of the present invention has applicability as a treatment apparatus for treating trauma / damage such as skin and mucous membrane.

DESCRIPTION OF SYMBOLS 1 ... High pressure trauma treatment apparatus, 2 ... High pressure oxygen gas source, 3 ... High pressure carbon dioxide gas source,
4 ... treatment gas supply unit, 5 ... housing, 6 ... control device, 7 ... pressure sensor for oxygen,
8 ... Oxygen flow meter, 9 ... Oxygen sterilization filter, 10 ... Oxygen supply valve,
11 ... Pressure sensor for carbonic acid, 12 ... Flow meter for carbonic acid, 13 ... Sterilization filter for carbonic acid,
14 ... Carbonate supply valve, 15 ... Fitting, 16 ... Treatment gas supply valve, 17 ... Purge valve,
18 ... Pressure reducing valve, 19 ... Oxygen gas detector, 20 ... Carbon dioxide gas detector,
L1 ... oxygen gas supply pipe, L2 ... carbon dioxide gas supply pipe, L3 ... treatment gas supply pipe,
L4 ... treatment gas supply hose, L5 ... purge pipe (exhaust pipe), L6 ... decompression line,
C1, C2, C3, C4, C5, C6, C7, C8, C9, C10, C11... Signal line

Claims (5)

One end side is connected to a high-pressure oxygen gas source, an oxygen gas supply pipe for supplying oxygen gas from the high-pressure oxygen gas source,
One end side is connected to a high-pressure carbon dioxide gas source, a carbon dioxide gas supply pipe for supplying carbon dioxide gas from the high-pressure carbon dioxide gas source,
One end side is connected to the other end side of the oxygen gas supply pipe and the other end side of the carbon dioxide supply pipe, respectively, and the other end side is connected to a treatment gas supply unit, and the oxygen gas supply pipe or the carbon dioxide supply A treatment gas supply pipe for supplying the gas supplied from the pipe to the treatment gas supply unit;
A high-pressure trauma treatment apparatus, comprising: a switching unit that selects a gas to be supplied to the treatment gas supply unit.   The high-pressure trauma treatment apparatus according to claim 1, further comprising an exhaust pipe provided by branching at least one of the oxygen gas supply pipe, the carbon dioxide gas supply pipe, and the treatment gas supply pipe.   The high-pressure trauma treatment apparatus according to claim 1, further comprising a detection unit that detects a concentration of at least one of oxygen and carbonic acid in an external atmosphere of the apparatus.   4. The apparatus according to claim 1, further comprising a supply pipe for supplying another gas from a supply source provided outside the apparatus, to at least one of the oxygen gas supply pipe and the carbon dioxide supply pipe. The high-pressure trauma treatment device described.   The high-pressure trauma treatment apparatus according to any one of claims 1 to 4, further comprising a control device that controls the switching unit.

Images