JP4409817B2 - Integrated breathing gas supply device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention provides a container filled with a high-pressure breathing gas, a decompression means for decompressing the high-pressure breathing gas supplied from the container, and a flow rate of the breathing gas decompressed by the decompression means is set to a predetermined flow rate. Related to an integrated breathing gas supply device that integrally incorporates a demand regulator that detects the user's breathing cycle and supplies the breathing gas required by the user in synchronism with inspiration It is.
[0002]
[Prior art]
One of the most effective treatments for respiratory diseases such as emphysema and chronic bronchitis is oxygen inhalation therapy. In recent years, oxygen enrichment that supplies oxygen cylinders or concentrated oxygen in the air for this therapy. A chemical air supply apparatus has come to be used. In such a device, when performing oxygen inhalation therapy at a hospital or at home, a large-capacity fixed oxygen cylinder or an oxygen-enriched air supply device is used, but when a patient goes out of the hospital or at home. A portable oxygen cylinder is mainly used.
[0003]
Such a portable oxygen cylinder is reduced in size and weight so that it can be carried by a patient with a respiratory disease who does not have physical strength. With such a reduction in size and weight, the amount of oxygen gas that can be filled is increased as much as possible. And is filled with high-pressure oxygen gas. Furthermore, in order to save as much oxygen as possible to the wasteful atmosphere, supply the necessary oxygen only when the patient inhales oxygen so that the oxygen is not wasted. It has been attempted to further extend the usable time. For this purpose, a means using a so-called demand regulator that incorporates a respiration sensor and an automatic opening / closing valve in an oxygen cylinder to supply oxygen only during the inspiratory time of the patient and stops supplying oxygen during the expiratory time is used.
[0004]
However, if it is intended to give the above function to a portable oxygen cylinder, oxygen gas filled at a high pressure such as 20 MPa cannot be supplied to the patient as it is, and thus a decompression means such as a decompression valve is required. . Further, in order to supply the oxygen flow rate prescribed by the doctor to the patient, a flow rate setting means for adjusting the supplied oxygen flow rate is required. Furthermore, in order to save the consumed oxygen, the demand regulator that supplies oxygen synchronously during breathing is required.
[0005]
Such pressure reducing means, flow rate setting means, or demand regulator, etc. are individually attached to the oxygen cylinder. When a patient using the oxygen cylinder goes out, the flow rate setting device attached to the upper part of the cylinder is a protrusion. In addition to being a hindrance to storage and carrying, there are many cases where it hits an object during walking or breaks, or a cylinder is overturned and damaged. Therefore, a breathing gas saver unit in which the flow rate setting means, the demand regulator means and the control means are integrated is attached to the upper part of the cylinder. However, since many of the attachment methods of the breathing gas saver unit are screw-type, it is required to turn the T-type handle or round handle to attach the unit to the oxygen cylinder, and the breathing gas is required. Many of these patients are elderly, and their physical strength is weak, so it is not easy to turn the handle while supporting the oxygen cylinder.
[0006]
For this reason, Japanese Patent Application Laid-Open No. 2001-276221 discloses a gas supply for breathing in which the installation and handling of the saver unit is simple, the occurrence of operational errors can be reduced, and there are no projections. A device has been proposed. In this conventional apparatus, a structure has been proposed in which the oxygen cylinder and the breathing gas saver unit can be integrally attached by pushing the saver unit into the neck of a container filled with oxygen.
[0007]
However, many patients who use a breathing gas supply device or caregivers who accompany such patients are often elderly or women. For this reason, it is required that a method for attaching the oxygen cylinder and the saver unit as one body is as simple as possible and that the operation method is simple for those who are physically handicapped. Moreover, as a device used for medical purposes, it is of course required that it is difficult to cause an erroneous operation. Furthermore, if the entire device is lifted via the breathing gas saver unit, the breathing gas saver unit may be removed from the oxygen cylinder, or the entire weight of the device may be hung on a joint for integration. It is necessary to prevent the portion from being deformed or damaged. However, such a point is hardly considered in the technique proposed in Japanese Patent Laid-Open No. 2001-276221.
[0008]
[Patent Document 1]
JP 2001-276221 A
[0009]
[Problems to be solved by the invention]
In view of the problems of the conventional technology described above, the problems to be solved by the present invention are as follows.
[0010]
That is, for example, an oxygen cylinder and the breathing gas saver unit can be attached very easily to a patient having physical fitness such as a patient having a respiratory disease or an elderly female caregiver. In addition, the operation method is extremely simple, and further, an integrated breathing gas supply device that is unlikely to cause an erroneous operation is provided, and even if the breathing gas saver unit is lifted, the breathing gas saver is also provided. It is an object of the present invention to provide a breathing gas supply device capable of preventing deformation and breakage of an integrated connecting portion even when a unit portion is detached from an oxygen cylinder or the entire weight of the device is hung.
[0011]
[Means for Solving the Problems]
Here, as the present invention for achieving the above object, according to claim 1 " A container filled with a high-pressure breathing gas, a decompression means for decompressing the high-pressure breathing gas supplied from the container, and a flow rate for setting the flow rate of the breathing gas decompressed by the decompression means to a predetermined flow rate A container unit having at least setting means, and a demand regulator that detects the user's breathing cycle and supplies the breathing gas required by the user in synchronism with inhalation to prevent waste of breathing gas In a breathing gas supply device comprising at least a saver unit portion provided, and further capable of separating or combining the saver unit portion and the container unit portion,
At least a gripping member that is provided in the saver unit portion and grips a part of the container unit portion, and the separated saver unit portion and the container unit portion are gripped by the gripping member to each other. Coalescing means for coalescing,
In order to release the uniting of the saver unit part and the container unit part, the saver unit part includes at least a release member provided in the saver unit part, and the release member releases the gripping state of the grip member. And a release means for separating the container unit portion,
By pushing The uniting operation is performed on the uniting means. It is a mounting operation part to be performed Coalescence inducing means, and
By pushing Said Cancel Release action of coalescing means It is a removal operation part to be performed Release triggering means
An integrated breathing gas supply device characterized in that, even in this case, even people who are physically handicapped can minimize the possibility of erroneous operation with a simple operation. Thus, the saver unit part and the saver unit part can be combined or released.
[0012]
Further, as in the present invention according to claim 2, in the integrated breathing gas supply device according to claim 1, if the coalescence inducing means and the release inducing means are attached to the saver unit part, the saver unit part When the unit is combined with or released from the saver unit, the handling becomes easy.
[0013]
Further, as in the present invention according to claim 3, in the integrated breathing gas supply device according to claim 1, a connection joint for allowing the breathing gas to flow freely between the saver unit portion and the container unit portion; Connected joints are provided in the saver unit part and the container unit part, respectively, the connection joints and the connected joints can be connected with the operation of the coalescence inducing means, and the operation of the release inducing means By adopting a configuration that can separate the connecting joint and the connected joint, the operation of integrating the device and the connecting operation of the pipe for allowing the breathing gas to flow between the two units can be performed almost simultaneously. It is possible to expect further improvement in operability.
[0014]
Further, as in the present invention according to claim 4, in the integrated breathing gas supply device according to claim 3, the direction in which the connecting joint and the connected joint are separated, the saver unit portion, and the container If the unit and the direction in which the unit is released are different, the connection between the connecting joint and the connected joint is disconnected due to an unexpected situation during use of the apparatus, and the supply of the breathing gas is stopped. Such a situation can be avoided.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in more detail with reference to the drawings.
[0017]
First, FIG. 1 shows a preferred embodiment of a container unit 1 which is a supply source for supplying a breathing gas used in the present invention. Form It is explanatory drawing (perspective view) typically illustrated in order to demonstrate.
[0018]
In FIG. 1, the container unit 1 includes a container body 10 filled with a high-pressure breathing gas, a main plug 11, a decompression means 12, a filling port 13, one connection joint 14a of a pair of connection joints, and a base 15. It consists of The main plug 11, the pressure reducing means 12, the filling port 13, the connection joint 14a, the base 15 and the like are integrated, and the component parts constituting the integrated container unit 1 are the neck 10a of the container body 10. With a known connection method such as a screw connection method, a flange connection method, or a high pressure coupler connection method, the breathing gas in the container 10 filled with high pressure is fixed so as not to leak outside.
[0019]
In the embodiment example of the container unit 1 described above, after the pressure of the breathing gas filled in the container body 10 at a high pressure is once reduced via the pressure reducing means 12, the pressure reducing breathing gas is provided downstream from the connection joint 14a. One of the features is that it is supplied to a saver unit (described later). Thus, in the present invention, by adopting a structure that can supply low-pressure breathing gas to the saver unit, the breathing gas to be handled is not high-pressure gas but low-pressure gas. A special pressure-resistant structure is not required, and the device structure and mechanism relating to the sealing property and connection method of the connection joint 14 can be simplified, and the feature that it can be configured by inexpensive parts is generated. In addition, even if the patient operates it by mistake, it can be avoided from the danger of being directly exposed to high pressure.
[0020]
In this way, a saver unit is attached to the container unit 1, and this saver unit detects the user's breathing cycle and synchronizes the breathing gas required by the user with the time of inhalation. At least a supply demand regulator is provided. Hereinafter, the saver unit will be described in detail with reference to FIG. 2 which is an explanatory view (perspective view) schematically illustrated to describe the embodiment.
[0021]
In FIG. 2, reference numeral 2 denotes the saver unit, and a switch 21 that combines opening and closing of the main plug and power ON / OFF is provided via a cover 20 on the external side where the user of the saver unit 2 can operate. Flow rate setting knob 22a for adjusting the flow rate of the breathing gas, intermittent supply changeover switch 22b tuned to continuous supply / respiration of breathing gas, synchronized supply control means (not shown) for breathing gas, mounting operation section 24, a removal operation unit 25, a cannula connection nozzle (cannula supply port) 26, a portable handle 30 and the like are attached. The portable handle 30 is used when lifting or transporting the saver unit 2 integrated in the container unit 1.
[0022]
However, the mounting operation part 24 forms a coalescence inducing means for performing an operation for combining the container unit 1 and the saver unit 2 by pushing in, and the removal operation part 25 A release inducing means for performing an operation for releasing the combination of the container unit 1 and the saver unit 2 is formed. In FIG. 2, the attachment operation unit 24 and the removal operation unit 25 are both shown as a push operation unit structure, but any of a pulling knob structure, a rotating knob structure, a lever structure, a rotating handle structure, or a combination thereof can be used. You may comprise.
[0023]
At that time, the switch 21 is interlocked with the main plug 11 for supplying the breathing gas. When the main plug 11 is opened, the saver unit is turned on when the main plug 11 is opened. The power of the saver unit is turned off when the main plug 11 is closed. In addition, the flow rate setting knob 22a is turned by turning the knob 22a so that the flow rate of the breathing gas decompressed through the decompression means 12 shown in FIG. In this case, it can be adjusted to an appropriate amount.
[0024]
In addition, the changeover switch 22b supplies the breathing gas to the user continuously as necessary, or synchronizes with the breathing cycle of the user, and intermittently supplies the breathing gas only during the user's inspiration. It is for switching to select whether to supply. Further, the tuned supply control means (not shown) detects a user's respiration and performs control for supplying a breathing gas in synchronization with the user's inspiration. Finally, the nozzle 26 for connecting the cannula serves to connect to a flexible conduit (not shown), and the other end of the flexible conduit is used to supply a breathing gas into the user's mouth and nasal cavity. A cannula or mask is connected.
[0025]
In the saver unit 2 of the present invention configured as described above, the main feature of the present invention is that the saver unit 2 part and the container unit 1 part which are separated from each other are combined, and the saver A release means for releasing the unit part and the container unit part from each other; a coalescence inducing means for causing the coalescing means to perform a coalescing operation; and a release inducing means for causing the releasing means to perform a coalescing release operation. It is in.
[0026]
Therefore, the interrelationship of the coalescing means, the releasing means, the coalescence inducing means 24, and the releasing inducing means 25, which are characteristic structures of the present invention, will be described in detail below with reference to FIG. To do. 3 illustrates the internal structure of the saver unit 2 in which the cover 20, the switch 21, the flow rate setting knob 22a, the changeover switch 22b, etc. are removed from the main body of the saver unit 2 in FIG. It is a figure (perspective view), Comprising: The figure (a) and (b) is the schematic diagram (perspective view) which looked at the same saver unit 2 from each different angle.
[0027]
In the embodiment illustrated in FIG. 3, reference numeral 27 denotes a frame that forms the skeleton of the saver unit 2, and this frame 27 is sufficient for lifting and transporting the container unit 1 to which the saver unit 2 is mounted. High mechanical strength and gripping force can be ensured. Therefore, as a matter of course, the handle 30 for lifting and transporting the container unit 1 to which the saver unit 2 is attached is pivotally supported by the mounting shaft 31 as shown in the frame 27 portion, Further, the mounting shaft 31 is fixed to the frame 27.
[0028]
Further, in this example, a one-touch type gripping means 28 whose reference numerals are omitted in the drawing is provided, and this one-touch type gripping means 28 is a uniting means for combining the saver unit 2 and the container unit 1 with each other. Part of it. Here, the configuration of the one-touch type gripping means 28 will be described. The one-touch type gripping means 28 includes two gripping members 281 and 281, a first rotating member 282, a second rotating member 283, and a first rotating shaft. 284, and a second rotating shaft 285. At this time, a gripping member 281 is provided at one end of the first rotating member 282, the other end engages with one end of the second rotating member 283, and the other end of the second rotating member 283 is gripped. A member 281 is provided. At this time, a concave portion and a convex portion are formed at the front end portions where the first rotating member 282 and the second rotating member 283 are engaged with each other, and the concave portion and the convex portion are engaged with each other, so that the first The rotating member 282 and the second rotating member 283 are interlocked with each other. Further, the first rotating member 282 and the second rotating member 283 have a both-end supported structure as shown in the first rotating shaft 284 and the second rotating shaft 285 fixed to the frame 27, and Each is pivotally supported.
[0029]
Therefore, when the coalescence inducing means (attachment operation portion) 24 is pushed in, the coalescence inducing means 24 comes into contact with the lower end of the first rotation member 282, and the first rotation member 282 is also pushed in. By such an operation, the gripping members 281 and 281 are finally operated, and the gripping members 281 and 281 hold and hold the container unit 1. The details of such a holding mechanism will be described later.
[0030]
Reference numeral 29 is a release member constituting a part of release means for releasing the uniting of the saver unit 2 and the container unit 1, and this release member 29 is the release-inducing member (removal operation part). 25 and the lower end of the first rotating member 282 are rotatably held. Note that, when the coalescence-inducing means (attachment operation portion) 24 is pushed in once, the pushed-in state is maintained as will be described later. In order to cancel the state, the release member 29 is provided. Reference numeral 286 denotes an urging means such as a coil spring, which provides a tension for urging the first rotating member 282 in the anti-pushing direction against the pushing force of the mounting operation unit 24.
[0031]
A mechanism in which the one-touch type gripping means 28 constituting a part of the coalescing means configured as described above holds and holds the container unit 1 will be described below with reference to FIG. 4A illustrates a state before the one-touch type gripping means 28 holds the container unit 1, and FIG. 4B illustrates a state when the one-touch type gripping means 28 holds the container unit 1. It is a model explanatory drawing for this.
[0032]
In FIG. Trigger Since the means 24 is not pushed in, the biasing means 286 causes the first rotating member 282 to be opened outward (on the opposite side) as shown. In addition, since the 2nd rotation member 283 is engaged with the 1st rotation member 282 in the front-end | tip part, this is also in the state opened outside. Therefore, the container unit 1 can be attached to the saver unit 2 as shown in the figure. At this time, the main stopper 11 attached to the container unit 1 engages with the switch 21. Further, the connection joint 14a provided in the container unit 1 forms a pair of connection joints together with the connection joint 14b provided in the coalescence inducing means 24 on the saver unit 2 side, and can be engaged with each other as shown in the figure. Placed in position.
[0033]
In such a state, when the coalescence inducing means 24 is pushed as shown in FIG. 4B, the lower end of the first rotating member 282 is brought into contact with the rear front edge surface of the coalescence inducing means 24 together with the release member 29. Then, the first rotating member 282 is pushed in the direction of the arrow in the figure. At this time, the first rotation member 282 rotates about the first rotation shaft 284 fixed to the frame 27, and is provided at the tip of the first rotation member 282 as the first rotation member 282 rotates. Further, the concave portion and the convex portion are engaged with each other, and the second rotating member 283 is simultaneously rotated about the second rotating shaft 285 as an axis. Then, the neck 10a of the container main body 10 can be held by the holding members 281 and 281 provided at the distal ends of the first rotating member 282 and the second rotating member 283, respectively. Since the pedestal 15 is provided on the neck 10a of the container body 10, the pedestal 15 serves as a stopper, so that the gripping members 281 and 281 are positioned and firmly fixed without sliding upward. The
[0034]
At this time, the connection joint 14b provided on the saver unit 2 side facing the connection joint 14a provided in the container unit 1 also moves in the direction of the arrow in the drawing and engages with the connection joint 14a. . At that time, as already described, since the connecting joint 14a and the connecting joint 14b can be connected at a low pressure, a commercially available inexpensive joint such as a male and female coupler joint can be used, and its mounting method is also used. It goes without saying that it will be very easy. Thus, by providing the connection joint 14b to be engaged with the connection joint 14a in the mounting operation portion 24, by interlocking with the one-touch gripping means 28, the respiratory gas supply device of the present invention is an elderly person, Even a patient with a respiratory disease whose physical strength is weak can be operated easily.
[0035]
Next, a side cross-sectional view schematically illustrating a state in which the pair of connection joints 14a and 14b are connected or disconnected by the release member 29 constituting a part of the release means. This will be described in detail below with reference to FIG. As already described with reference to FIG. 4, one of the pair of connection joints 14a and 14b is provided on the container unit 1 side. The other connecting joint 14b is attached to the coalescence-inducing means 24 provided on the saver unit 2 side. However, in FIG. 5, only a pair of connection joints 14a and 14b is shown so that the structure can be clearly understood. The connection unit 14 is provided in the container unit 1 and the saver unit 2 and is connected to the pair of connection joints 14a and 14b. The other parts to be combined are not shown. Further, in FIG. 5, FIG. 5 (a) shows a state where the pair of connection joints 14a and 14b are separated from each other, and FIG. 5 (b) shows a state where the pair of connection joints 14a and 14b are engaged with each other. .
[0036]
In FIG. 5, a connection joint 14a is a female joint, and includes a main body 140a, a lock member 141a, a lock ball 142a, a valve member 143a, a seal member 144a, biasing members 145a and 146a, and the like. At this time, the main body 140a is provided with a mooring hole H1a for mooring the lock ball 142a as shown, and the lock ball 142a is always present in the mooring hole H1a. The valve member 143a is formed with a flow hole group H2a through which the breathing gas supplied from the container unit 1 flows at the illustrated position. Further, the valve member 143a is movable in the left-right direction in the drawing, and a seal member 144a made of an O-ring in this example is provided on the outer peripheral portion thereof as shown in the figure. At this time, the valve member 143a is pressed to the opposite side by the biasing means 146a such as the compression coil spring. The connection joint 14b is a male joint and is inserted into and engaged with the connection joint 14a which is a female joint. In order to maintain the inserted engagement state at this time, the connection joint 14b is a male joint. Is provided with a lock groove Gb into which the lock ball 142a is inserted.
[0037]
In the pair of connecting joints 14a and 14b configured as described above, as shown in FIG. 5 (a), when the unillustrated coalescence-inducing means 24 is pushed in, the connecting joint attached to the union-inducing means 24 is provided. 14b moves in the direction of the white arrow, and the distal end portion 141b of the connection joint 14b is inserted into the connection joint 14a while moving the valve member 144a of the connection joint 14a to the left in the drawing. Then, the lock ball 142a restrained in the mooring hole H1a is pushed down by the lock claw Ra formed in the unlocking member 141a, falls into the lock groove Gb engraved in the connection joint 14b, and restrained here, This state is locked. At this time, the seal member 144a made of an O-ring that has been in contact with the inner peripheral surface of the right end cylinder of the main body 140a of the connection joint 14a to prevent the flow of the breathing gas is not in contact with the inner peripheral surface. The seal mechanism that prevented the free flow of the working gas is released. As a result, the breathing gas introduced from the introduction hole H0a can flow to the outlet hole H0b through the flow hole H2a.
[0038]
Therefore, in the case of FIG. 5 (a), the breathing gas supplied from the introduction hole H0a is sealed by the seal member 144a. The structure does not flow out. Therefore, even if the connecting joints 14a and 14b are disconnected, the breathing gas does not leak from the connecting joint 14a. However, even if for some reason, for example, the seal member 144a is damaged, the breathing gas supplied to the connection joint 14a is decompressed to a low pressure by the decompression means 12 illustrated in FIG. For this reason, since only low-pressure gas with little danger leaks out, safety is ensured more reliably.
[0039]
In this way, in order to change the paired connection joints 14a and 14b from the combined and engaged state to the disconnected state, the release inducing means (removal operation unit) already described with reference to FIG. It is necessary to actuate the release member 29 that constitutes part of the release means by pushing in 25. Therefore, this operation will be briefly described with reference to FIG. 4 described above. In FIG. 4, when it is desired to remove the saver unit 2 from the container unit 1, the removal operation is performed in the state shown in FIG. Push in part 25. If it does in this way, the release raising means 25 will contact the upper end of the release member 29, and will push the upper end of the release member 25 in the arrow direction of a figure.
[0040]
At this time, since the lower end of the release member 29 is pivotally attached to the lower end of the first rotation member 282, this attachment portion serves as a fulcrum when the release member 29 is considered as a lever. Since the first rotation member 282 is fixed by the uniting member 24, when the release member 25 is pushed, the release member 29 is turned in the pushing direction around the fulcrum. Then, the front edge of the release member 29 pushes the front surface Fb (see FIG. 5B) of the connection joint 14a, and the lock member 141a moves. For this reason, the lock claw Ra holding the lock ball 142a is released, and the lock ball 142a is in an operating state. Then, the valve member 141a is pushed back by the urging means 146a, and at the same time, the connection joint 14b is pushed out, and the lock ball 142a that has fallen into the lock groove Gb moves up from the lock groove Gb, and the lock is released. When the lock is released, the first rotating member 282 and the second rotating member 283 are opened to the outside by the biasing means 286. At this time, as already described, since the connection joint 14b is connected to and interlocked with the coalescence-inducing means 24, the gripping member 281 described in FIG. The saver unit 2 can be removed from the container unit 1 by returning to the release state in which 281 is opened outward.
[0041]
Here, one of the important features in the present invention is that the pair of connection joints 14a and 14b are separated from each other, and the direction in which the combination of the saver unit 2 and the container unit 1 is released. Is different. By doing so, the connection joints 14a and 14b are firmly connected to each other even if a force to release the combination of the saver unit 2 and the container unit 1 works for some reason. Unless the lock between the joints 14a and 14b is released, the saver unit 2 and the container unit 1 cannot be detached. In addition, since the direction in which the force is applied is different, it is possible to avoid a situation in which the saver unit 2 and the container unit 1 are unexpectedly disconnected even if some unexpected situation occurs.
[0042]
Various embodiments other than the example shown in FIG. 3 can be considered for the embodiment in which the container unit 1 described above is combined by the combining means provided in the saver unit 2. Therefore, such an embodiment will be briefly described below with reference to FIG. In addition, the part shown with the broken line in FIG. 6 shows the container unit 1, and the thick solid line shows the holding member or a part of the holding means including the holding member.
[0043]
First, in the embodiment shown in FIG. 6 (a), the wedge-shaped gripping member shown by a thick solid line is pushed in the direction of the arrow in conjunction with the pushing operation of the mounting operation portion 24, and the saver unit 2 is moved by the neck portion of the container unit 1. This is a gripping method. Further, in the embodiment shown in FIG. 6B, the gripping member shown by a thick solid line is inserted into the neck of the container unit 1 and is rotated halfway at this position, so that the saver unit 2 is placed at the neck of the container unit 1. This is a gripping method. In the embodiment shown in FIG. 6 (c), the two gripping members indicated by thick solid lines are rotated downward from above to move to the lower end of the valve seat of the main plug 11 and the lower end of the base 15, respectively. In this manner, the saver unit 2 is gripped by the container unit 1 at these portions. Further, in the embodiment shown in FIG. 6D, the gripping member indicated by the thick solid line is not rotated from the upper side to the lower side as shown in FIG. The valve unit is moved to the lower end of the valve seat and the lower end of the pedestal 15, respectively, and the saver unit 2 is gripped by the container unit 1 at these portions.
[0044]
Further, in the embodiment shown in FIG. 6 (e), a part of the gripping member is built in the container unit 1, and the gripping member indicated by a thick line is pushed from the saver unit 2, and the front part of the container unit 1 is moved. This is a method in which the gripping member that is pushed out grips the rear portion of the container unit 1 by pushing out the gripping member that is built in at the same time. Finally, in the embodiment of FIG. 6 (f), the saver unit 2 is provided with a gripping member having a square hole indicated by a thick line, and the gripping member is rotated so that the square hole is formed. This is a method of gripping the lower part of the main valve 11 of the container unit 1 at the side portion.
[0045]
As described above, various modes can be considered as the one-touch type grasping means. However, the important thing is that the present invention is applicable even to a patient suffering from a respiratory disease that is elderly and exhausted. It can be operated easily like this.
[0046]
As described above, the present invention is a container unit in which the container unit 1 and the saver unit 2 are merged by the coalescence inducing means (attachment operation portion) 24 and the container unit 1 is merged by the release inducing means (detachment operation portion) 25. The main feature is that 1 and the saver unit 2 are separated. This is because the functions of “merging” and “separation” are clearly divided in this way, and as shown in FIG. 2, the coalescence inducing means (attachment operation part) 24 and the release inducing means (detachment operation part) 25 By displaying the function on the Misoperation It has become possible to prevent this. In addition, even a user who has a physical handicap can easily perform merging or merging by a simple mechanism of merging inducing means (attachment operation part) 24 and release inducing means (detachment operation part) 25. In addition, an integrated breathing gas supply device that can be easily operated can be provided.
[0047]
Finally, a state where the saver unit 2 is mounted on the container unit 1 will be briefly described with reference to FIG.
[0048]
Usually, the breathing gas supply device includes a container unit 1 that supplies breathing gas made of oxygen gas filled in an oxygen cylinder or oxygen-enriched air having an oxygen concentration of 90% or more, a sensor that senses a breathing cycle, and Three configurations of a saver unit 2 having at least a demand regulator having a valve means for turning on / off oxygen supply in synchronization with the oxygen supply means (not shown) such as a nasal cannula for supplying oxygen to a patient It consists of parts. The saver unit 2 is connected to oxygen supply means (not shown) such as the nasal cannula through a nozzle 26 for connecting the cannula. Although the description is omitted, the connection joint 14b illustrated in FIG. 4 and the nozzle 26 are also connected by piping, and the breathing gas decompressed to near atmospheric pressure is connected to the nose cannula or the like through the connection joint 14b. Needless to say, the oxygen is supplied to oxygen supply means (not shown).
[0049]
【The invention's effect】
As described above, according to the present invention, for example, a patient unit and a saver unit are extremely simple for a patient having a respiratory disease or an elderly female caregiver who has physical disabilities. In addition, the operation method is extremely simple, and in addition, there is a remarkable effect that it is possible to provide an integrated breathing gas supply device that is unlikely to cause an erroneous operation.
[0050]
Furthermore, even if the saver unit is lifted, the saver unit is removed from the container unit, or even if the entire weight of the breathing gas supply device integrated with the saver unit is suspended, It is possible to prevent the connecting portion from being deformed or damaged. In addition, it is possible to reduce the situation where the saver unit unit and the container unit unit combined due to an unexpected situation are separated as much as possible, even if the connection joint is separated for some reason or the gas seal mechanism is broken, it leaks out. Since the gas is not at high pressure, it has a particularly remarkable effect that it can provide a breathing gas supply device that is safer for the user.
[Brief description of the drawings]
FIG. 1 is an explanatory view (perspective view) schematically illustrating a preferred embodiment of a container unit 1 used in the present invention.
FIG. 2 is an explanatory view (perspective view) schematically exemplified for explaining an embodiment of a saver unit including at least a demand regulator.
FIG. 3 is an explanatory diagram of the inside of the saver unit in the embodiment of the saver unit according to the present invention, in which a cover or the like is removed and the inside thereof is exposed.
FIG. 4 is a schematic explanatory diagram for explaining a mechanism in which the one-touch type gripping means of the present invention holds and holds the container unit.
FIG. 5 is a schematic explanatory view (side sectional view) schematically illustrating an embodiment of a connection joint according to the present invention.
FIG. 6 is a schematic explanatory view schematically illustrating various embodiments in which a container unit is gripped by one-touch gripping means provided in a saver unit.
FIG. 7 is a schematic explanatory diagram for schematically explaining a state in which the saver unit is mounted on the container unit.
[Explanation of symbols]
1 Container unit
2 Saver unit
10 Container body
10a Container neck
11 Main plug
12 Pressure reducing means
13 Filling port
14 Connection joint
15 pedestal
20 Cover
21 switch
22a Flow rate setting knob
22b selector switch
24 Mounting operation part
25 Removal operation part
26 Nozzle for connecting cannula
27 frames
281 Holding member
282 First rotating member
283 Second rotating member
284 First rotation axis
285 Second rotation axis
286 Biasing means (coil spring)
29 Release member
30 Handle
31 Mounting shaft

Claims (4)

A container filled with a high-pressure breathing gas, a decompression means for decompressing the high-pressure breathing gas supplied from the container, and a flow rate for setting the flow rate of the breathing gas decompressed by the decompression means to a predetermined flow rate A container unit having at least setting means, and a demand regulator that detects the user's breathing cycle and supplies the breathing gas required by the user in synchronism with inhalation to prevent waste of breathing gas In a breathing gas supply device comprising at least a saver unit portion provided, and further capable of separating or combining the saver unit portion and the container unit portion,
At least a gripping member that is provided in the saver unit portion and grips a part of the container unit portion, and the separated saver unit portion and the container unit portion are gripped by the gripping member to each other. Coalescing means for coalescing,
In order to release the uniting of the saver unit part and the container unit part, the saver unit part includes at least a release member provided in the saver unit part, and the release member releases the gripping state of the grip member. And a release means for separating the container unit portion,
A coalescence-inducing means that is an attachment operation unit that causes the coalescence means to perform a coalescence operation by pushing , and
Integrated breathing gas supply apparatus characterized by comprising a release elicited means a detachment operation portion to perform the coalescence of releasing operation the releasing means by pushing.   The integrated breathing gas supply device according to claim 1, wherein the uniting inducing means and the release inducing means are attached to the saver unit.   A pair of connection joints for allowing the breathing gas to flow freely between the saver unit portion and the container unit portion are provided in the saver unit portion and the container unit portion, respectively, and the pair of connection joints are operated in accordance with the operation of the coalescence inducing means. The integrated breathing gas supply device according to claim 1, wherein the connection joint can be connected to each other, and the pair of connection joints can be separated from each other in accordance with the operation of the release-inducing means.   When separating and releasing the united container unit and the saver unit, a direction in which the engagement of the pair of connection joints is separated and separated from each other, and the saver unit and the container unit The integrated breathing gas supply device according to claim 3, wherein a direction in which the unity is released and removed is different.

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