JP3860331B2 - Ventilator - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is a ventilator ventilator for a patient with respiratory disease, which is frequently injected into the lungs of a patient as inspiratory air, oxygen or a mixed gas of air and oxygen having an impact property, By fluidizing the secretions that block the bronchi, opening the gas flow path, promoting sputum, and then spraying water or drugs sprayed by a nebulizer (erosol generator) on this shocking inspiration The present invention relates to a new respiratory assistance device that makes it possible to spread throughout the lungs and enhance the therapeutic effect.
[0002]
[Prior art and problems to be solved by the invention]
The number of patients with chronic respiratory illnesses is increasing in Japan, and the number is increasing with aging. Also, not only for patients with such chronic respiratory diseases, for example, lung fistula after undergoing surgical operation may cause complications if it is somewhat insufficient, resulting in serious consequences, sometimes It often happens that clinicians experience life-threatening situations.
[0003]
Furthermore, in the case of patients with chronic obstructive pulmonary disease (COPD), the lungs are actually covered with secretions that are also the source of sputum, and no matter how high the concentration of oxygen, respiratory assistance is possible. The exchange of gas does not work well due to the sequestration of the secretion film and cannot improve the patient's symptoms.
[0004]
In addition, there are few effective methods for this improvement in the current medical situation. It is also known that secretions present in the lung have various adverse effects. For example, a bronchus or peripheral bronchiole that introduces air into various parts of the lung is often covered with the presence of viscous secretions and the gas passage is completely blocked. A patient with weak physical strength cannot hesitate on his own, causing so-called dyspnea.
[0005]
In conventional treatment methods, high concentrations of oxygen are introduced into the patient's lungs to ensure that breathing is enabled as little as possible, or devices that precisely control high concentrations of oxygen are used to increase the frequency of lungs. Although attempts have been made to introduce it into the body, some results have been obtained, but there has been no respiratory aid that provides a treatment method that actively removes secretions covering the bronchi and alveoli.
[0006]
Up to now, the jet flow utilizing the Venturi effect has been used, and treatment with this jet-like inspiratory gas has been tried, but the jet flow produced by the Venturi tube has a weak force and fluidization of secretions in the lungs It is far from removing the secretions that block the bronchi, and there are problems such as the intermittent increase of the pulmonary pressure due to the intermittent jet flow supplied to the patient and the risk of rupture of the alveoli due to the increased pulmonary pressure The emergence of a revolutionary new ventilator was awaited.
[0007]
In order to introduce respiratory inspiration through the bronchus into the patient's lungs throughout the inventor, the present inventor repeatedly considered based on a completely new idea to achieve an effective auxiliary effect that was not possible with conventional inspiratory force. As a result of earnest research toward the realization, the present invention has been achieved. The present invention utilizes the air hammer effect by impact introduction of intrapulmonary inspiration, that is, “percussion”. In other words, the present invention is called intrapulmonary percussion (impact) ventilation therapy (IPV). It opens the way for the introduction of new lung disease treatments.
[0008]
Its basic idea and its effect is to give a favorable impact to the inhalation introduced into the lungs. By introducing inhalation with a shock wave, obstructive secretions that obstruct bronchial or peripheral bronchial gas passage are fluidized and removed by the percussion effect, ensuring a gas flow path that was previously covered with secretions, It has become possible to contribute to the effective exchange of oxygen-carbon dioxide gas.
[0009]
That is, the first effect of the present invention resides in the opening by percussion of the bronchial obstruction.
[0010]
Also, if the alveolar gas exchange field is covered with viscous secretions (the one that is excreted is sputum) and the oxygen-carbon dioxide gas exchange is substantially hindered, the shock wave air hammer effect By fluidizing this, enabling sputum as a sputum, and effectively removing the secretory film, it is possible to remove the elements that have hindered gas exchange so far and realize effective respiratory assistance. .
[0011]
That is, the second effect of the present invention resides in fluidization of secretions in the lung.
[0012]
A third effect brought about by the present invention is a gas stirring and mixing diffusion effect by percussion after gas exchange in the lung is performed. In other words, the place where the gas is exchanged is covered with carbon dioxide gas that has been absorbed and released by oxygen, and if this carbon dioxide gas is efficiently removed and replacement with oxygen is not effective, effective oxygen will be removed. It is obvious that the supply cannot be made.
[0013]
That is, percussion remarkably promotes the diffusion effect due to the mixing and stirring of the gas, and the replacement effect of oxygen-carbon dioxide gas.
[0014]
Further, as a fourth effect, the nebulized mist-like drug can reach every corner of the lungs by percussion, improving the drug efficacy and improving the therapeutic properties.
[0015]
That is, the effects of the present invention are as follows: (1) an effect of securing a passageway to remove bronchial obstruction caused by percussion, (2) fluidization and sputum promoting effect due to percussion of secretions in the lung, There are four points: diffusion effect by effective mixing and stirring of gas and improvement of gas exchange efficiency associated therewith, and (4) effective diffusion effect of drug by percussion.
[0016]
The present invention provides means for realizing the above four effects.
[0017]
Looking at the current state of treatment for pulmonary diseases, patients with respiratory disorders breathe high oxygen concentrations through the nose, etc., and in more severe patients, countermeasures such as supporting breathing with 100 percent oxygen are taken. ing. However, no matter how high the concentration of oxygen is introduced into the patient's lungs, it cannot be achieved if the bronchus, which is a conduit for oxygen to the human body, is blocked. Naturally, if the field is covered with secretions and obstructing gas exchange, the therapeutic efficiency will not increase.
[0018]
The present inventor has focused on the following points in order to solve such problems. That is, (1) Inhalation introduced into the lung is made into percussion. (2) Percussion is frequently performed, and percussion air is introduced a plurality of times (for example, several times to 30 times) within one intake period. (3) The frequency of percussion is set to about 10 to 600 times / minute to achieve its effectiveness. (4) Provide a break during the percussion period to allow the secretions that fall off due to fluidization to be trapped. (5) The wedge pressure in the lung, that is, the lung airway pressure is ideally 15 to 45 cm · H ₂ O.
[0019]
Furthermore, the present inventor has (6) reduced weight (easy to carry), (7) reduced size (can be carried anywhere), and (8) gas pressure without using electricity. (9) Simplify operation, (10) Make it safe as much as possible, from the standpoint of adding practical and therapeutic diversity. The present invention has been completed as a result of continuing research toward its realization.
[0020]
As described above, the ventilator of the present invention can be used anywhere as long as there is a pressurized gas source (a supply pipe from a gas tank, a gas cylinder, etc.), but there is no pressurized gas source. Also, it can be used for treatment by incorporating a compressor so that it can be used while traveling, or by using an external compressor together and preparing pressurized air gas from the atmosphere to drive this ventilator .
[0021]
The present invention utilizes a shock wave generator (Patent Publication (B2) 2-16149) provided with a special function in order to inject shocking intake air. In other words, the present invention generates this shock wave. Provide a new ventilator system that makes full use of the device's functions and injects inspiration into the patient's lungs with a percussion air hammer effect, creating an unprecedented intrapulmonary shock ventilation treatment It was completed with the advice and cooperation of Dr. Forest Bird, the inventor of the shock wave generator.
[0022]
In other words, the present invention makes full use of the functions of the shock wave generating device, applies it to a ventilator, solves many problems so far, and provides a practical artificial respiration that exhibits great effects. The present invention provides a ventilator system that does not use any electrical control mechanism and completes a drooping ventilator driven by pressurized gas.
[0023]
The difference between the effect of the shock wave generator and the effect of the jet flow by the conventional Venturi tube will be briefly compared to explain the difference.
[0024]
In the conventional jet flow method, as shown in FIG. 8, when gas is injected from a high-pressure gas source through a thin tube, the high-speed jet flow applies the principle that the surrounding gas is drawn by the venturi effect, and a short intake air is applied. A large amount of gas can be sent into the patient's airway in time, and switching between inspiration and expiration is performed by injecting or stopping the jet flow by a conventionally known rotary ball bearing, fluid element system, electromagnetic valve, etc. Is done by that.
[0025]
In this case, the jet flow is intermittently supplied to the patient's respiratory tract, but considerable pressure is maintained when switching to exhalation.
[0026]
On the other hand, the shock wave generator used in the present invention has a sliding venturi built in, and its structure is shown in FIG. More specifically, the shock wave generator 16 used in the present invention is a cylindrical body containing a sliding venturi 39, and the sliding venturi is generated by intermittent positive pressure gas obtained by using a pressurized gas driven oscillator 6. 39 is repeatedly moved back and forth, and the leading end of the sliding venturi 39 opens and closes to the atmosphere. When the intermittent gas flows in, the block 39 is momentarily blocked, and a large amount of positive pressure gas is jetted in a shocking manner by the venturi effect. In addition, when the intermittent gas is stopped, it has a function of releasing instantaneously, releasing the gas in the shock wave generator 16 to the atmosphere, and extinguishing the pressure load, and is accelerated and supplied by this functional venturi effect. The intermittent jet flow is converted into intermittent shock waves and supplied to the patient's airway, and when the shock wave stops, the patient's airway pressure is instantaneously reduced to atmospheric pressure. To facilitate breathing.
[0027]
This will be specifically described with reference to FIG.
[0028]
FIG. 4 shows a cross section of the shock wave generator 16 used in the present invention. When inhaling, the diaphragm 47 in the shock wave generating device 16 bulges to the right, moves the sliding venturi 39 to the right, and forms a route to the mouthpiece 17 (which leads to the patient's airway) in a sealed tubular body. (See FIG. 4B), effectively supplying the patient with a jet stream. On the other hand, when the gas supply to the intermittent gas supply port 37 on the left is cut off, that is, stopped, the sliding venturi 39 instantaneously returns to the left by the action of the spring 45 and creates a void in the sealed tubular body ( (See FIG. 4 (A)) The gas is released to the atmosphere and instantaneously becomes atmospheric pressure. Due to this repetition, the rising and disappearing of the jet flow is performed drastically. Therefore, the ventilator of the present invention to which the shock wave generating device 16 is applied can give a percussion suitable for inspiration supplied to a patient, and the conventional jet flow has a high frequency. This is essentially different from the ventilator. This is an epoch-making ventilator that provides the medical community with a new treatment that should be called intrapulmonary shock ventilation. It also solves the problem of gradual increase in the patient's intrapulmonary pressure, which was a problem with conventional high-frequency jet flow ventilators.
[0029]
[Means for Solving the Problems]
The features of the present invention are enumerated as follows.
[0030]
One of the features of the present invention is that the ventilator is driven very precisely by a pressurized gas without using electricity.
[0031]
A further feature of the present invention is that it provides a patient with a shocking inspiratory gas and provides a new treatment that can be referred to as intrapulmonary shock ventilation.
[0032]
Furthermore, one of the features of the present invention is that it has been made smaller, lighter, and portable. For this purpose, a housing corresponding to the drive unit and an assembly (accessories) connected to the case are provided. It is possible to separate and disassemble these as desired. Furthermore, in making portable, it is possible to easily carry out operations to control each function with one hand of a person.
[0033]
Further, one of the features of the present invention is that the housing, the coupling assembly, and each part of the assembly can be easily detached, disassembled and assembled by means such as simple insertion and fitting.
[0034]
Furthermore, one of the features of the present invention is that, when portable, the assembly of the nebulizer and shock wave generator that make up the coupling assembly is regulated to a size that can be held by one person's hand, and each function is controlled with one hand. It is in the point that it miniaturized until the operation to do can be easily performed with a fingertip.
[0035]
As will be described in detail later, for example, a patient holds the nebulizer part with one hand, and the operation of this ventilator is proposed by the present invention with a simple operation of pushing the push button with the thumb of the hand holding the nebulizer. Treatment of pulmonary shock ventilation can be easily performed. For this reason, the nebulizer container of the present invention has a maximum diameter (outer diameter in the case of a cylindrical shape) of 80 mm or less, 20 mm or more, preferably 60 mm or less, 30 mm or more, more preferably 50 mm or less and 40 mm or more. preferable. The most preferred diameter is around 45 mm. If this diameter is larger than 80 mm, it is difficult to hold it in one hand, and if it is 20 mm or less, it is difficult to hold it, and it is difficult to push the button. Further, the shortest distance between the center of the push button for the subsequent breathing operation for starting the intrapulmonary shock ventilation and the lid on the upper part of the nebulizer is 40 mm or less, more preferably 30 mm or less, more preferably 25 mm or less. It is necessary.
[0036]
This is because if the distance between the nebulizer lid and the button exceeds a certain distance, it becomes impossible to hold the nebulizer and operate the push button with one hand.
[0037]
The nebulizer container has a lower limit size because it is desirable to have a capacity suitable for introducing a medicine necessary for one treatment.
[0038]
Furthermore, one of the features of the present invention is that the disassembly of the coupling assembly is very easy and reliable. In other words, since the housing, the coupling assembly, and each part of the assembly can be easily disassembled into an affordable size, handling of each part is not complicated and disinfection can be easily performed down to the details.
[0039]
In addition, one of the features of the present invention is that a single pressurized gas source is used to precisely function as a ventilator, and the circuit in the housing is skillfully arranged to balance the gas flow. It is in that point.
[0040]
Further, one of the features of the present invention is that the patient is considered to be safe, and a switch is provided so that the ventilator can be operated only while the patient or medical staff is pressing the push button switch. .
[0041]
DETAILED DESCRIPTION OF THE INVENTION The present invention will be described in detail. An artificial respirator that is driven by a pressurized gas and performs intrapulmonary shock ventilation treatment using a shock wave generated by the action of a shock wave generator as an inspiration, and an inhalation gas introduced from a respiratory gas source A part of the gas is introduced into the nebulizer to become a humidified spray gas, and another part of the introduced intake gas is converted into an intermittent flow, and then introduced into the shock wave generator to give an impact. A system for administering to a patient by merging with a spray gas containing water or a drug.
[0042]
More specifically, it is a ventilator that is driven by a pressurized gas and performs intrapulmonary shock ventilation treatment using the shock wave generated by the action of the shock wave generator as an inspiration, and the ventilator is connected to the housing and the shock wave generator. The casing is provided with a gas inlet for introducing gas, and part of the gas introduced into the gas inlet is guided to the nebulizer as a continuous flow and introduced into the casing. Another continuous flow branched from the generated gas is converted into an intermittent flow by the oscillator cartridge and guided to the shock wave generator outside the housing, and the spray gas flow from the nebulizer joins the shock wave generator and is intermittent It is a ventilator characterized by being converted to a shocking respiratory gas.
[0043]
Furthermore, the present invention is a ventilator that is driven by a pressurized gas and performs intrapulmonary shock ventilation treatment using the shock wave generated by the action of the shock wave generator as an inspiration, and the ventilator includes a housing and a shock wave generator. The casing is provided with a gas inlet for introducing gas, and a part of the gas introduced into the gas inlet is led to the nebulizer as a continuous flow and introduced into the casing. Another continuous flow branched from the gas is converted into an intermittent flow by the oscillator cartridge and guided to the shock wave generator outside the housing, and the spray gas flow from the nebulizer merges with the shock wave generator and is interrupted by the shock wave generator. A ventilator that is converted into a typical shock breathing gas, wherein a remote switch is disposed on a tubular body connecting the nebulizer and the shock wave generator, and the switch A ventilator intermittent air flow from the oscillator cartridge, characterized in that the flow in the shock wave generating device by the action.
[0044]
Furthermore, the present invention is a ventilator that is driven by pressurized gas and performs intrapulmonary shock ventilation treatment using shock waves generated by the action of the shock wave generator as an inspiration, and the whole is housed in a housing. The assembly includes a gas inlet for introducing gas, and at least two sockets that can be attached to and detached from the tube. The continuous flow of the introduced gas is intermittently flowed in the housing. Oscillator cartridge that converts to a gas, and a nebulizer and shock wave generator as a coupling assembly on the outside of the housing. The first socket connects the continuous flow connected to the gas inlet inside the housing to the nebulizer outside the housing with a tube. The second socket is characterized in that the gas flow converted into an intermittent flow by the oscillator cartridge inside the housing is connected to a shock wave generator outside the housing by a tube. Is an artificial respirator to be.
[0045]
Another feature of the present invention is that it provides a respiratory device that embodies deep consideration for preventing infection by the patient's device. Generally speaking, patients who need a ventilator often have a variety of infectious bacteria. Therefore, it is natural that the respiratory system used by patients is often contaminated by these infectious bacteria. From the viewpoint of patient safety, disinfection and sterilization of the respiratory system, and particularly the instruments related to the breathing circuit in which the patient breathes, is of course not particularly important. However, the reality is that there are no respiratory organs that take these into consideration.
[0046]
The present inventor has deeply thought about this point, and considering how to disinfect and sterilize easily by patients and medical workers without any resistance in nature. The device can be divided into the housing of the drive unit and accessories that come into direct contact with the patient, and this attachment assembly can be easily disassembled and divided by means such as insertion / removal and fitting, facilitating disinfection and sterilization. In addition, the respiratory organ that can be surely executed to the details is completed.
[0047]
Furthermore, the present invention can be connected to each part of the assembly including the case main body, the nebulizer outside the case, and the shock wave generating device via the sockets respectively provided on the case and the connection assembly, and can be detached at both ends thereof. It is characterized by being connected by a simple tube.
[0048]
By making the tube detachable at both ends in this way, the tube can be easily cleaned and disinfected, and it has a great effect in preventing the adverse effects of various infectious diseases often seen in patients with lung diseases and the risk of infection. I can do it.
[0049]
Furthermore, the present invention can be connected to each part of the assembly including the casing main body, the nebulizer outside the casing, and the shock wave generating device at both ends via sockets respectively provided in the casing and the connecting assembly. In a ventilator that functions by being connected with a simple tube, each connected socket and tube is distinguished by a connection line, and is colored in different colors.
[0050]
By attaching the same color tube to the same color socket, it is possible to automatically set the connection line according to the function, so it can be easily assembled for those who use the respiratory system for the first time. It can be easily and definitely set when reused after disinfection, and udder mistakes can be avoided.
[0051]
Furthermore, the present invention is a ventilator for performing intrapulmonary shock ventilation therapy driven only by gas pressure, and the whole is composed of a main body housed in a housing and an assembly connected thereto, It is equipped with a gas inlet for introducing gas, a tube and four removable sockets, and an oscillator cartridge that converts the continuous flow of the introduced gas into an intermittent flow and a marking meter that indicates the pressure in the lung airway are arranged in the housing. In addition, a nebulizer and a shock wave generator are arranged in the connection assembly outside the housing, a remote switch is provided in the tube connecting the shock wave generator and the nebulizer, and a tube for monitoring the lung airway pressure is provided at the tip of the shock wave generator. The first socket is connected to the nebulizer outside the casing with a continuous flow connected to the gas inlet in the casing, and is connected to the second socket. The gas flow converted into an intermittent flow by the oscillator cartridge inside the housing is connected to a shock wave generator outside the housing by a tube, and the third socket has an indicator meter for indicating the lung airway pressure in the housing. A tube is connected to a tube insertion port for monitoring the lung airway pressure at the tip of the shock wave generator, and a fourth socket is connected to a drive gas control circuit inside the housing by a tube. It is a ventilator.
[0052]
Furthermore, the present invention is a ventilator that is driven by a pressurized gas and performs intrapulmonary shock ventilation treatment using the shock wave generated by the action of the shock wave generator as an inspiration, and the entire respirator is housed in a housing. A casing having a gas inlet for introducing gas, an oscillator cartridge for converting a continuous flow of gas into an intermittent flow inside the casing, and outside the casing, A nebulizer that supplies mist-like water or medicine in communication with the shock wave generator, and a sign meter that is inside the housing and that communicates with an outlet of the shock wave generator to indicate pulmonary airway pressure, the nebulizer and the A tubular body connecting the shock wave generator and a remote switch installed in the tubular body are constituent components, and a part of the gas introduced into the gas inlet of the casing is continuously flowed outside the casing. Another part of the gas introduced into the housing through the socket through the socket and converted into an intermittent flow through the oscillator cartridge is passed through the socket installed on the outer surface of the housing. The tube is guided to the shock wave generator, and forms a shock flow with percussion, and on the outer surface of the housing, a gas introduction path to a nebulizer, an oscillator cartridge to a shock wave generator, a sign meter to a shock wave generator, Sockets for connecting the drive gas control circuit of the oscillator cartridge to the remote switch are provided, and the connection from these sockets to the nebulizer, shock wave generator, remote switch, and shock wave generator to the lung airway pressure monitor port is removable. Characterized by possible flexible tube Is an artificial respirator to be.
[0053]
Furthermore, the present invention is a ventilator characterized in that the shock wave generator and the nebulizer constituting the connection assembly are assembled by fitting and can be disassembled.
[0054]
Further, according to the present invention, the lid of the nebulizer constituting the nebulizer may be integrally formed with a tubular body connecting the shock wave generating device and the nebulizer, and one end of the tubular body is fitted into the shock wave generating device. The other end may be opened to the atmosphere and air may be introduced into the shock wave generator, or the atmosphere may be introduced into the shock wave generator through an atmosphere having a controlled oxygen concentration. . Here, the tubular body may be T-shaped, L-shaped, or Y-shaped. In short, the shock wave generating device and the nebulizer may be assembled airtightly by fitting. .
[0055]
Furthermore, the present invention skillfully utilizes the mechanical properties of the gas fluid in order to make the whole function in a well-balanced manner using a single pressurized gas source as a drive source. You can see its features in that it achieves this goal.
[0056]
Further, the present invention will be described in detail. A sliding venturi is built in a cylindrical container, and the sliding venturi repeatedly reciprocates back and forth by an intermittent gas. As a result, the tip of the venturi tube opens and closes to the atmosphere. When the intermittent gas flows in, the gas is instantaneously closed, and the positive pressure gas is jetted in shock, and when the intermittent gas is stopped, the gas is instantaneously opened to release the gas in the tube to the atmosphere. Using a shock wave generator that converts intermittent gas flow into intermittent shock waves by the Venturi effect, which has the function of extinguishing the pressure load, and using the pressurized gas as a drive source, the intermittent generated by the action of the shock wave generator This is a respirator that assists breathing by using a characteristic shock wave as an inspiration. The whole is composed of a main body housed in a housing and an attached assembly connected to the body, and a gas inlet is provided in the housing. The introduced continuous flow gas is converted from a continuous flow to an intermittent flow by an oscillator cartridge installed in the housing, and then reaches the shock wave generating device. The ventilator is characterized in that at least one orifice is arranged in a gas flow path including the driving gas control circuit, and a function control function is given by a gas flow rate balance.
[0057]
That is, the present invention relates to sockets (hereinafter collectively referred to as service sockets) disposed in the casing, that is, an aerosol socket connected to a nebulizer, a percussion socket connected to a shock wave generator, and a gauge socket connected to a lung airway. An artificial respiration characterized in that at least one orifice is provided in each gas flow path in the casing leading to the remote socket connected to the remote switch, and the amount of gas flowing to each service socket is adjusted by the action of this orifice. It is a vessel.
[0058]
More specifically, a sliding venturi is built in a cylindrical container, and the sliding venturi reciprocates back and forth by an intermittent gas. As a result, the tip of the venturi tube opens and closes to the atmosphere, and the intermittent gas When the gas flows in, the gas is closed instantaneously and positive pressure gas is jetted in shock, and when the intermittent gas is stopped, the gas is released instantaneously and the gas in the tube is released to the atmosphere to pressure load. Using a shock wave generator that converts an intermittent gas flow into an intermittent shock wave by the Venturi effect having the function of extinguishing the gas, and using the pressurized gas as a driving source, the intermittent shock wave generated by the action of the shock wave generator Is a respirator that performs intrapulmonary shock ventilation treatment with inhalation as a whole, and is composed of a main body housed in a housing and an attached assembly connected to the body, and gas is contained in the housing. There are four sockets that can be connected to the gas inlet and the tube. The oscillator cartridge that converts the continuous flow of the introduced gas into an intermittent flow, and the indicator meter that indicates the pulmonary airway pressure are arranged in the housing. A nebulizer and a shock wave generator are arranged outside the body, and the shock wave generator and the nebulizer are connected by a connecting pipe. The remote switch that activates an oscillator cartridge to generate an intermittent flow in the connecting pipe, the shock wave generating apparatus The distal end is provided with a tube insertion port for monitoring the lung airway pressure, and the gas flow introduced into the casing is divided into two flow paths in the casing, and a part of the first flow remains in the continuous flow. Connected to the nebulizer outside the housing through the socket, another part branched off is led to the oscillator cartridge and becomes intermittent flow, and the housing through the second socket The third socket is connected to the lung airway pressure indicator meter and the lung airway pressure monitor insertion port at the tip of the shock wave generator, and the fourth socket is used to drive the oscillator cartridge. A gas control circuit and a remote switch are connected, and an orifice is provided in at least one of each gas flow path in the housing connected to the nebulizer outside the housing, shock wave generator, insertion port for lung airway monitoring, and the remote switch. The ventilator is characterized in that the amount of gas flowing through each socket is adjusted by the action of.
[0059]
The percussion frequency of the present invention is preferably 10 to 600 times per minute, preferably 20 to 400 times, more preferably 40 to 300 times, and the operating gas pressure is 15 psi to 85 psi ( ^{1.0kg / cm 2 ~6.0kg / cm 2} ), preferably ^{20~80psi (1.4kg / cm 2 ~5.6kg /} cm 2), more preferably 25~65psi (2.0kg / cm ² ~ 4.5 kg / cm ² ), and it should be treated.
[0060]
This adjustment is preferably performed so that the patient's pulmonary airway pressure (wedge pressure) is 15 to 45 cmH ₂ O for safe treatment.
[0061]
[Action]
As described above, the present invention has established a system that makes the most of the effects of the shock wave generator and established a lung impact ventilation treatment method that is a new feature as a ventilator, which has been difficult in the past. It was successful in fluidizing the secretions in the lungs and opening the bronchial obstruction, and succeeded in improving the patient's treatment efficiency.
[0062]
DETAILED DESCRIPTION OF THE INVENTION
The invention is further illustrated by the following examples.
[0063]
[Example 1]
The first embodiment of the present invention will be described in detail with reference to the circuit diagram of FIG.
[0064]
In the first embodiment, the portion surrounded by the dotted line on the left side of the circuit diagram is housed in the housing 53. The right part of the circuit diagram is a connection assembly 55, which is outside the housing 53 and is connected to the tip of the nebulizer 14, the shock wave generator 16, the remote switch 15, and the shock wave generator 16 by connection tubes 71, 72, 73, 74, respectively. It is connected.
[0065]
First, in the housing, the breathing gas introduced from the breathing gas inlet 1 is removed by the filter 2 and then an aerosol socket that is partially connected to the nebulizer 14 via the orifice 64 via the master switch 5. 10, it is guided to the nebulizer 14 through the detachable tube 71, and the mist containing the water or the medicine atomized here is guided to the shock wave generator 16.
[0066]
A part of the continuous flow from the master switch 5 is adjusted to a desired pressure by the pressure reducing valve 3 installed in the line and guided to the oscillator cartridge 6. The set pressure is displayed on the external display 4 via the orifice 61. The gas flow changed to the intermittent flow by the oscillator cartridge 6 reaches the percussion socket 11 through the orifice 62 of the intermittent flow circuit (A), and is connected to the shock wave generator 16 by the tube 72 from here. In the shock wave generator 16, the spray gas from the nebulizer 14 merges, and by the action of the sliding venturi 39, the shock wave generator 16 becomes a shock wave and reaches the mouthpiece 17 connected to the patient's mouth.
[0067]
On the other hand, from the port 41 in front of the mouse piece 17, the tube 74 is passed through the gauge socket 13 to the inside of the housing, and the airway pressure gauge 9 installed in the housing through the orifice 66 displays the lung airway pressure on the monitor. The
[0068]
On the other hand, the remote switch 15 reaches the remote socket 12 via the tube 73, is connected to the drive gas control circuit (B) via the adjustment orifice 65, and when the remote switch 15 is pressed, the remote switch 15 is opened to the atmosphere. The opening opens, the drive gas control circuit (B) is depressurized, the oscillator cartridge 6 is started, and the intermittently drawn intake gas is supplied from the intermittent flow circuit (A) to the shock wave generator 16 where it is generated. The shock wave is supplied to the patient from the mouse piece 17. When the remote switch 15 is released, the atmosphere release port in the remote switch 15 is closed, the drive gas control circuit (B) is boosted, the oscillator cartridge 6 is stopped, and the intermittent intake gas is also stopped. That is, the shock flow is provided to the patient only while the remote switch 17 is being pressed, so that it functions extremely safely.
[0069]
In this example, a bypass circuit 18 is formed to connect the continuous flow circuit from the pressure reducing valve 3 to the oscillator cartridge 6 and the intermittent flow circuit (A) of the intake gas from the oscillator cartridge 6 to the shock wave generator 16. A manual button 8 (a circuit is opened by pressing and a continuous flow flows through the shock wave generator 16) is provided, and a continuous jet flow or a manual intermittent flow can be used as necessary.
[0070]
In this example, the pressure is set by the in-line pressure reducing valve 3 and the frequency of the oscillator cartridge 6 is adjusted by the frequency adjusting meter 7 of the driving gas control circuit (B), so that the shock gas having a desired frequency is supplied from the shock wave generator 16. Can be introduced into the patient's lungs, and water or drugs nebulized by the nebulizer 14 can be introduced into the patient's lungs on a shock wave to rescue patients with respiratory failure.
[0071]
[Example 2]
The second embodiment of the present invention will be described in detail with reference to the circuit diagram of FIG.
[0072]
In the second embodiment, the portion surrounded by the dotted line on the left side of this circuit diagram is housed in the casing 53. The part to the right of the dotted line is a connection assembly 55 that is outside the housing 53 and is connected to the tip of the nebulizer 14, shock wave generator 16, remote switch 15 and shock wave generator 16 by connection tubes 71, 72, 73, 74, respectively. It is connected.
[0073]
First, in the housing, after the impurities are removed from the breathing gas introduced from the breathing gas inlet 1 by the filter 2, a part of the breathing gas is adjusted to a desired continuous flow rate by the aerosol generation adjusting orifice 22, and the aerosol is discharged. It reaches the socket 10 and passes through the removable tube 71 to the nebulizer 14, where the atomized water or medicine is guided to the shock wave generator 16.
[0074]
A part of the continuous flow introduced from the breathing gas inlet 1 is adjusted to a desired pressure by the pressure reducing valve 2 installed in the line, and the set pressure is displayed on the external display 4 via the orifice 61. . The continuous flow adjusted to a constant pressure is guided to the oscillator cartridge 6 via the master switch 5. The continuous flow introduced into the oscillator cartridge 6 is converted into a desired intermittent flow by setting of the driving gas control circuit (B), that is, the time check valve 27, the balance orifice 62, the breathing time adjuster 19 and the frequency adjusting meter 7. The flow rate is adjusted by the respiratory flow regulator 20 of the intermittent flow circuit (A) to reach the percussion socket 11, and the shock wave generator 16 is connected by the tube 72 from here. In the shock wave generator 16, the spray gas from the nebulizer 14 merges, and by the action of the sliding venturi, it reaches the mouthpiece 17 that becomes a shock wave and connects to the patient's mouth.
[0075]
On the other hand, the port 41 in front of the mouse piece 17 reaches the gauge socket 13 through the tube 74, and the airway pressure in the lungs is displayed on the airway pressure gauge 9 installed in the housing 53 through the orifice 64.
[0076]
On the other hand, the remote switch 15 reaches the remote socket 12 through the tube 73, is connected to the drive gas control circuit (B) through the adjustment orifice 65, and when the remote switch 15 is pressed, the remote switch 15 is opened to the atmosphere. Is opened, the oscillator cartridge 6 is operated, and the inhaled inspiratory gas is supplied from the intermittent flow circuit (A) to the shock wave generator 16 where it becomes a shock wave and is supplied from the mouthpiece 17 to the patient. When the remote switch 15 is released, the atmosphere release port in the remote switch 15 is closed, the drive gas control circuit (B) is boosted, the oscillator cartridge 6 is stopped, and the intermittent intake gas is also stopped. That is, the shock flow is provided to the patient only while the remote switch 15 is being pressed, so that it functions extremely safely.
[0077]
In this example, a bypass circuit 18 is formed to connect the continuous flow circuit from the pressure reducing valve 3 to the oscillator cartridge 6 and the intermittent flow circuit (A) of the intake gas from the oscillator cartridge 6 to the shock wave generator 16. A manual button 8 (a circuit is opened by pressing and a continuous flow flows through the shock wave generator 16) is provided, and a continuous jet flow or a manual intermittent flow can be generated as necessary.
[0078]
In this example, a bypass circuit 23 is formed between the continuous flow circuit extending from the pressure reducing valve 3 and the intermittent flow circuit (A) of the intake gas from the oscillator cartridge 6 to the shock wave generator 16, and CPAP (sustained) is formed in this circuit. (Positive airway pressure) regulator 21 is provided, and a circuit extending to the airway pressure gauge 9 is connected to the pressure detection part of the CPAP regulator 21 to provide a function capable of continuously and constantly regulating the positive airway pressure. .
[0079]
[Example 3]
The third embodiment is essentially equivalent to the first embodiment, but is included in the housing of the first embodiment in order to improve convenience and achieve weight reduction, portability, and miniaturization. A part of the configuration is included on the coupling assembly side.
[0080]
A third embodiment will be described with reference to the circuit diagram of FIG. In the drawing, a portion surrounded by a dotted frame is outside the casing 53 as a connecting assembly 55.
[0081]
In this example, the manual button 8 and the master switch 5 of the first example are omitted, and the example is essentially the same as the example except that the pressure reducing valve 3 and the external gas pressure indicator 4 are arranged outside the casing 53. Is equivalent to 1.
[0082]
FIG. 5 specifically illustrates an example of the coupling assembly 55 in the circuit diagram of the first embodiment. In this example, an assembly 55 connected to a housing (not shown) by connecting tubes 71, 72, 73, 74 is shown, and the shock wave generator 16 and the nebulizer 14 are integrated with the T-shaped connecting tube 33. The assembled aspect is shown.
[0083]
The remote switch 15 is provided at the lower left portion of a T-shaped connecting pipe 33 interposed between the shock wave generator 16 and the nebulizer 14. The switch 15 is normally a spring and the circuit is closed to the atmosphere. The switch 15 is opened to the atmosphere only when it is pressed, and the circuit leading to the pressure is reduced in pressure within the housing (not shown; circuit diagram of the first embodiment) This is the type that the oscillator of (see) starts. When the remote switch 15 is released, the circuit is instantaneously closed to the atmosphere by the force of the spring, and the operation of the oscillator is stopped.
[0084]
FIG. 6 illustrates the disassembled state of the assembly 55. In this example, the T-shaped connecting pipe 33 is formed integrally with the lid of the nebulizer 14. These can be easily and airtightly assembled by fitting as shown in FIG.
[0085]
What is important here is that the assembly is held in one hand, and the remote switch 15 is packed into a small size that can be pushed with the thumb of the hand. The maximum diameter of the container of the nebulizer 14 is 47 mm so that the size of the embodiment of the present invention is entered in FIG. In this embodiment, the shortest distance from the lid of the nebulizer 14 to the remote switch 15 is 8 mm, and the shortest distance from the lid of the nebulizer 14 to the center of the remote switch 15 is 16 mm. The distance to the remote switch 15 can be pushed in this way using the thumb of the hand holding the nebulizer 14. Such a small assembly allows a user, for example, a patient, to perform a breathing operation with one hand.
[0086]
FIG. 7 is essentially the same as that shown in FIG. 6 except for the manner of connection shown below.
[0087]
That is, FIG. 7 shows an exploded state (the drawing is slightly exaggerated for ease of understanding), but the T-shaped connecting pipe 33 is integrally formed with the lid of the nebulizer 14. The T-shaped connecting pipe 33 is independent with the remote switch 15, and the shock wave generator 16, the T-shaped connecting pipe 33, the lid of the nebulizer 14, and the independent bodies of the nebulizer 14 are fitted together. It can be assembled easily and airtight as shown in FIG. In the present embodiment, as shown in FIG. 7, the size of the assembly is 50 mm in the maximum diameter of the container of the nebulizer 14, and from the lid of the nebulizer 14 after fitting assembly. The distance to the center of the remote switch 15 is 20 mm. By determining the size in this way, a user, for example, a patient, can perform a breathing operation with one hand.
[0088]
In the following, the circuit diagram of the first embodiment shown in FIG. 1 will be described in more detail.
[0089]
The connection assembly 55 is outside the housing 33, and the nebulizer 14, the shock wave generator 16, the remote switch 15, and the shock wave generator 16 are connected to each other by connection tubes 71, 72, 73, and 74, respectively.
[0090]
First, in the casing 53, the breathing gas introduced from the breathing gas inlet 1 is filtered out by the filter 2, and a part of the breathing gas is connected to the nebulizer 14 via the orifice 64 via the master switch 5. It reaches the socket 10 and is guided to the nebulizer 14 through the detachable tube 71, and the mist containing water or the medicine atomized here is guided to the shock wave generator 16.
[0091]
A part of the continuous flow from the master switch 5 is adjusted to a desired pressure by the pressure reducing valve 3 installed in the line and guided to the oscillator cartridge 6. The set pressure is displayed on the external display 4 via the orifice 61. The gas flow changed to an intermittent flow by the oscillator cartridge 6 reaches the percussion socket 11 through the orifice 62, and is connected to the shock wave generator 16 by the tube 72 from here. In the shock wave generating device 16, the sliding venturi 39 acts as a shock wave and reaches the mouthpiece 17 connected to the patient's mouth.
[0092]
On the other hand, from the port 41 in front of the mouse piece 17, the tube 74 is passed through the gauge socket 13 to the inside of the housing, and the airway pressure gauge 9 installed in the housing through the orifice 66 displays the lung airway pressure on the monitor. The
[0093]
On the other hand, the remote switch 15 reaches the remote socket 12 through the tube 73, is connected to the drive gas control circuit (B) through the adjustment orifice 65, and presses the remote switch 15 to release the atmosphere in the remote switch 15. The mouth is opened, the driving gas control circuit (B) is appropriately depressurized, and this is used as a trigger to drive the oscillator cartridge 6 so that intermittent shock waves are supplied from the mouthpiece 17 to the patient. When the remote switch 15 is released, the atmosphere release port in the remote switch 15 is closed, the drive gas control circuit (B) is boosted, the operation of the oscillator cartridge 6 is stopped, and the intermittent intake gas is also stopped. That is, since the intermittent shock flow is provided to the patient only while the remote switch 17 is being pressed, it functions extremely safely. In this example, a bypass circuit 18 is formed to connect the continuous flow circuit from the pressure reducing valve 3 to the oscillator cartridge 6 and the intermittent flow circuit (A) of the intake gas from the oscillator cartridge 6 to the shock wave generator 16. A manual button 8 (a circuit is opened by pressing and a continuous flow flows through the shock wave generator 16) is provided, and a continuous jet flow or a manual intermittent flow can be used as necessary.
[0094]
In this example, the pressure is set by the in-line pressure reducing valve 3 and the frequency of the oscillator cartridge 6 is adjusted by the frequency adjusting meter 7 of the driving gas control circuit (B), so that the shock gas having a desired frequency is supplied from the shock wave generator 16. Can be introduced into the patient's lungs, and water or medicine nebulized by the nebulizer 14 is introduced into the patient's lungs on a shock wave.
[0095]
In the present embodiment, a large number of orifices are arranged in the circuit in the casing 53 as described above, and the flow rate balance is skillfully maintained. The orifice 61 (0.013 orifice) is arranged in front of the external display 4 so as to protect the external display 4 and accurately monitor the supply pressure. The intermittent flow circuit (A) connecting the oscillator cartridge 6 and the percussion socket 11 is provided with a load orifice 62 (0.060 orifice) to prevent excessive intermittent flow, and the driving gas connecting the oscillator cartridge 6 and the frequency adjustment meter 7. The control circuit (B) is provided with a balance orifice 63 (0.018 orifice) having a diameter smaller than that of the load orifice 62 so as to balance supply of gas necessary for controlling the function of the oscillator cartridge 6. Yes.
[0096]
An orifice 64 (0.024 orifice) is inserted into the circuit from the in-line pressure reducing valve 3 to the aerosol socket 10 so as to supply a continuous flow gas necessary for nebulizer 14 spraying. By setting the diameter of the orifice in this way, a preferable balance between the amount of spray generated from the nebulizer 14 and the intermittent flow from the oscillator cartridge 6 is achieved, and the shock wave generator 16 is supplied and mixed. An orifice 65 of a variable adjustment type of the orifice diameter is arranged between the remote socket 13 connected to the remote switch (15: thumb button) and the driving gas control circuit (B), and this orifice diameter pushes or releases the remote switch 15. In this case, the function of driving or stopping the oscillator cartridge 6 is set to work effectively.
[0097]
In addition, an orifice 66 (0.013 orifice) is disposed between the lung airway pressure gauge 9 and the gauge socket 13 so as to protect the lung airway pressure gauge 9 so that an accurate display can be made. Is possible. As illustrated in this example, the ventilator functions precisely by using a single high-pressure gas source as a driving source by arranging an orifice in a circuit in the housing and balancing the flow rate of the whole.
[0098]
The mechanism of shock wave generation when the remote switch 15 is pressed will be described. By pressing the remote switch 15, the drive gas control circuit (B) is depressurized, and the on-off valve connected to the diaphragm in the oscillator cartridge 6 is opened. Gas spouts out. Most of the ejected gas reaches the shock wave generator 16 through the intermittent flow circuit (A) through the orifice 62 (0.06 orifice) having a large diameter. The drive gas control circuit (B) has a balance orifice 63 (0.018 orifice) having a diameter smaller than that of the load orifice 62 and a variable adjustment type orifice 65, so that a small amount of jet gas flows and pressure is instantaneously applied. As a result, the on-off valve connected to the diaphragm in the oscillator cartridge 6 closes, and gas ejection stops. The time check valve closes in a short time, the gas in the drive gas control circuit (B) is released to the atmosphere and decompressed again, and after a time corresponding to the setting of the frequency adjustment meter 7, the valve in the oscillator cartridge 6 opens. Gas spouts out. Thereafter, the intermittent flow is supplied to the shock wave generator 16 by repeating this process, and an intermittent shock wave having a desired frequency is generated. That is, it is understood that the flow rate is skillfully balanced by the action of the orifice group of the gas circuit system including the driving gas control circuit (B), and that precise control is possible despite a single gas source. Let's do it.
[0099]
Further, the circuit diagram of the second embodiment shown in FIG. 2 will be described in more detail.
[0100]
The connection assembly 55 is outside the housing 53, and the nebulizer 14, the shock wave generator 16, the remote switch 15, and the shock wave generator 16 are connected to each other by connection tubes 71, 72, 73, and 74, respectively.
[0101]
First, after removing impurities from the breathing gas introduced from the breathing gas inlet 1 into the casing 53 by the filter 2, a part of the breathing gas is adjusted to a desired continuous flow rate by the aerosol generation variable adjustment orifice 22. Then, it reaches the aerosol socket 10 and passes through the removable tube 71 to the nebulizer 14, where the atomized water or medicine is guided to the shock wave generator 16.
[0102]
A part of the continuous flow introduced from the breathing gas inlet 1 is adjusted to a desired pressure by a pressure reducing valve 3 installed in the line, and the set pressure is externally displayed via an orifice 61 (0.013 orifice). 4 is displayed. The continuous flow adjusted to a constant pressure is guided to the oscillator cartridge 6 via the master switch 5. The continuous flow introduced into the oscillator cartridge 6 is set in accordance with the settings of the driving gas control circuit (B), that is, the time check valve, the balance orifice 62 (0.024 orifice), the breathing time adjuster 19 and the frequency adjusting meter 7. The flow is adjusted by the respiratory flow regulator 20 through the load orifice 63 (0.060 orifice) that is converted into intermittent flow and regulates the flow rate, and reaches the percussion socket 11. The diameter of the orifice 63 is set so that the flow rate to the driving gas control circuit (B) is within a range necessary for the function control of the oscillator cartridge 6. The intermittent flow is connected from the percussion socket 11 to the shock wave generator 16 via the tube 72. In the shock wave generating device 16, the sliding venturi 39 acts as a shock wave and reaches the mouthpiece 17 connected to the patient's mouth.
[0103]
On the other hand, a gauge socket 13 connected to the port 41 in front of the mouse piece 17 and a tube 74 is installed in the casing 53, and an orifice 64 (0) for protecting the gauge is provided in a circuit between the socket 13 and the airway pressure gauge 9. .013 orifice), and the lung airway pressure is displayed on the monitor.
[0104]
On the other hand, the remote switch 15 reaches the remote socket 12 through the tube 73, is connected to the drive gas control circuit (B) through the adjustment orifice 65 (0.018 orifice), and when the remote switch 15 is pressed, the opening is opened. When opened, the oscillator cartridge 6 is operated, and the inhaled inspiratory gas is supplied to the shock wave generator 16, where it becomes a shock wave and is supplied from the mouthpiece 17 to the patient. When the remote switch 15 is released, the atmosphere release port in the remote switch 15 is closed, the drive gas control circuit (B) is boosted, the oscillator cartridge 6 is stopped, and the intermittent intake gas is also stopped. That is, the shock flow is provided to the patient only while the remote switch 15 is being pressed, so that it functions extremely safely. It will be understood that the mechanism by which the shock wave is generated by pressing the remote switch 15 is the same as described above, and the ventilator functions by the flow rate balance of the orifice.
[0105]
In this example, a bypass circuit 18 is formed to connect a continuous flow circuit from the pressure reducing valve 3 to the oscillator cartridge 6 and an intermittent flow circuit (A) of the intake gas from the oscillator cartridge 6 to the shock wave generator 16, and a manual circuit is formed in this circuit. A button 8 (a circuit is opened by pressing to cause a continuous flow to flow through the shock wave generator 16) is provided, and a continuous jet flow or a manual intermittent flow can be used as necessary. A restriction orifice 66 (0.040 orifice) is inserted into the circuit 18 so that a large amount of gas does not flow more than necessary.
[0106]
In this example, a bypass circuit 23 is formed between the continuous flow circuit extending from the pressure reducing valve 3 and the intermittent flow circuit (A) of the intake gas from the oscillator cartridge 6 to the shock wave generator 16, and CPAP (sustained) is formed in this circuit. (Positive airway pressure) regulator 21 is provided, and a circuit extending to the airway pressure gauge 9 is connected to the pressure detection part of the CPAP regulator 21 to provide a function capable of continuously and constantly regulating the positive airway pressure. .
[0107]
As explained in detail above, various orifices are arranged in the circuit in the housing to balance the flow rate, and the entire function including the function of the remote switch 15 is made to function organically, and a single pressurized gas source is used for precision. We have provided a ventilator that can operate smoothly.
[0108]
A more effective embodiment of the present invention will be described in detail with reference to the circuit diagram of the first embodiment shown in FIG. 1 and FIG.
[0109]
In this embodiment, each socket and each desorption tube in Example 1 are colored in different colors, and are color-coded for each system of connection lines, so that they can be handled easily and without error during disassembly and assembly. Specifically, the erosol socket 10 of the erosol line, the connection tube 71 and the socket portion of the nebulizer 14 are “yellow”, and the percussion socket 11, the connection tube 72, and the shock wave generator 16 inlet socket portion which is an intermittent flow percussion line are “White”, remote socket 12 and connection tube 73 of remote line and socket mounting portion of remote switch 15 are “green”, gauge socket 13 and connection tube 74 and mouthpiece 17 port 41 of the lung airway pressure monitor line are “ Colored `` red '' for use and And the convenience of time.
[0110]
【The invention's effect】
The present invention makes full use of the shock wave generator previously devised, applies it to a ventilator, succeeds in fluidizing secretions in the lungs using the air hammer effect of percussion, It is the creation of a breakthrough treatment that should be called internal shock ventilation (IPV), and it brings great gospel to patients.
[Brief description of the drawings]
FIG. 1 is an overall circuit diagram of a ventilator according to a first embodiment of the present invention.
FIG. 2 is an overall circuit diagram of a ventilator according to a second embodiment of the present invention.
FIG. 3 is an overall circuit diagram of a ventilator according to a third embodiment of the present invention.
FIG. 4 is a structural diagram of a shock wave generator used for a ventilator according to the present invention;
(A) is sectional drawing which shows the state before an action | operation.
(B) is sectional drawing which shows the state after an action | operation.
FIG. 5 is an assembly diagram showing an example of a connection assembly (shock wave generator, nebulizer, T-shaped connection tube, connection tube, etc.) used in the ventilator of the present invention.
FIG. 6 is an exploded view of the coupling assembly shown in FIG.
FIG. 7 is an exploded view showing an example of a connection assembly (shock wave generator, nebulizer, T-shaped connection tube, connection tube, etc.) used in the ventilator of the present invention.
FIG. 8 is a schematic view showing an outline of a jet flow generation mechanism.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Breathing gas inlet 6 Oscillator cartridge 9 Airway pressure gauge 10 Service socket 11 Service socket 12 Service socket 13 Service socket 14 Nebulizer 15 Remote switch 16 Shock wave generator 33 Connecting pipe (T-shaped connecting pipe)
39 Sliding Venturi 53 Housing 55 Connection Assembly 61 Orifice 62 Orifice 63 Orifice 64 Orifice 65 Orifice 66 Orifice 67 Orifice 68 Orifice 71 Tube 72 Tube 73 Tube 74 Tube

Claims (2)

A shock wave generator is built in which a sliding venturi is built in a cylindrical container, and the sliding venturi is repeatedly reciprocated back and forth by intermittent gas,
The shock wave generating device opens and closes the tip of the sliding venturi to the atmosphere with repeated reciprocation of the sliding venturi back and forth, and when the intermittent gas flows in, the shock wave generator is instantaneously closed, and positive pressure gas is released. When the intermittent gas is stopped and the intermittent gas is stopped, the gas is released instantaneously, and the gas in the sliding venturi is released to the atmosphere, and the pressure load disappears. Is configured to convert to
In the ventilator configured to drive the shock wave generator with intermittent gas and perform intrapulmonary shock ventilation treatment using the intermittent shock wave generated by the shock wave generator as inspiration,
The ventilator as a whole is composed of a ventilator body housed in a housing, and an attached assembly that includes the shock wave generator and the nebulizer, respectively, and is connected to the ventilator body.
The housing includes a gas inlet for introducing gas, and four sockets to which tubes can be connected,
The casing is provided with an oscillator that converts a continuous flow of gas introduced into the casing from the gas inlet into an intermittent flow, and an indicator meter for indicating lung airway pressure,
The attached assembly including the shock wave generating device and the nebulizer is arranged outside the housing,
The shock wave generator and the nebulizer are integrally connected by a T-shaped connecting pipe,
The shock wave generating device, the T-shaped connecting tube and the nebulizer are assembled by fitting the shock wave generating device and the T-shaped connecting tube and fitting the T-shaped connecting tube and the nebulizer. And separable,
The T-shaped connecting pipe is provided with a remote switch that activates the oscillator to generate an intermittent gas flow,
The continuous flow of gas introduced into the casing from the gas inlet is configured to branch into two flow paths in the casing,
One of the two flow paths is configured such that the gas is led as a continuous flow through the first socket to the nebulizer via the tube,
The other of the two flow paths is configured such that a continuous flow is converted into an intermittent flow by the oscillator and then guided to the shock wave generating device through a tube through a second socket,
The third socket is used to connect the indicator meter and the shock wave generator,
The fourth socket is used to connect the driving gas control circuit of the oscillator and the remote switch,
When the remote switch is pressed, an opening to the atmosphere in the remote switch is opened, so that the driving gas control circuit is depressurized and the oscillator is started.
The artificial gas characterized in that an intermittent shock breathing gas is formed when the erupted gas from the nebulizer is guided to the shock wave generator and merges with the intermittent shock wave. Respiratory organ. The ventilator of claim 1,
A ventilator characterized in that the outer diameter of the cylindrical part of the nebulizer is between 20 mm and 80 mm.

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