JP2010207351A - Compressor and oxygen concentrator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a compressor and an oxygen concentrator which are capable of reducing noise without leaking the noise to the outside directly when sucking raw material air and generating compressed air. <P>SOLUTION: The compressor 10 includes: a case part 23; a driving motor 11 provided in the case part 23 and having an output shaft 15; head parts 21 and 22 operated by the rotation of the output shaft 15 of the driving motor 11, for sucking and compressing the raw material air 70 and generating the compressed air 71; and a raw material air capturing part 90 provided on the output shaft 15, for fetching the raw material air 70 and supplying the raw material air to the side of the head parts 21 and 22 by the rotation of the output shaft 15. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a compressor and an oxygen concentrating device including the compressor, and more particularly, to a medical compressor and an oxygen concentrating device capable of supplying oxygen by compressing captured raw material air and supplying the compressed air to an adsorbent. Is.

The oxygen concentrator obtains oxygen by using a pressure swing adsorption method that generates oxygen by using, for example, zeolite or the like as an adsorbent that selectively adsorbs nitrogen by permeating oxygen in the raw material air. Has been.
According to this type of oxygen concentrator, the raw material air taken in is compressed by a compressor as a compression means to generate compressed air, and this compressed air is supplied to an adsorption cylinder containing an adsorbent. Nitrogen is adsorbed on the adsorbent to generate oxygen. The generated oxygen is stored in a tank, and the patient can inhale oxygen using a device such as a nasal cannula by enabling the supply of a predetermined flow rate of oxygen from the tank via a pressure reducing valve or a flow rate setting device. Can do.

If this oxygen concentrator is installed in a place where an AC power supply (commercial AC power supply) can be used, for example, a home oxygen therapy patient with reduced lung function will be able to safely take oxygen even while sleeping. it can.
In particular, when the home oxygen therapy patient is used while sleeping, it is preferable that the oxygen concentrator generates very little noise. For example, it is desirable that the noise of the oxygen concentrator is less than or equal to the noise level generated from indoor air conditioning equipment.

In addition, oxygen concentrators used for long-term oxygen inhalation therapy, which is effective as a treatment for patients with respiratory diseases such as chronic bronchitis, are generally not portable, so that patients can take them outside. Not configured.
Therefore, when the patient inevitably goes out, for example, while pushing a cart equipped with an oxygen cylinder filled with oxygen in a predetermined container, concentrated oxygen is sucked from the oxygen cylinder. This oxygen cylinder must be filled with oxygen in a dedicated facility.
Therefore, portable and mobile oxygen concentrators have been proposed, and portable and mobile oxygen concentrators include a compressing means that takes in raw air and generates compressed air, and a decompressing means that generates decompressed air. It is equipped with a compressor that can be driven by a battery (see Patent Document 1).

JP 2002-45424 A

In the conventional oxygen concentrator described above, the crank chamber of the piston has an intake hole for sucking the raw air. By rotating the motor output shaft of the compressor, the piston is operated, and the raw material air, which is the outside air, is directly sucked into the piston side from the intake hole to generate compressed air. However, when the compressor is operated, noise sometimes leaks directly from the inside of the crank chamber of the piston through the intake hole. For this reason, it is desired that noise can be prevented from leaking directly to the outside through the intake hole, and compressed air can be generated by reliably sucking the raw material air into the piston side with low noise.
Accordingly, an object of the present invention is to provide a compressor and an oxygen concentrator that can reduce noise without generating noise directly when the raw material air is sucked to generate compressed air.

The compressor of the present invention is a compressor that generates compressed air by compressing raw air, and the compressor includes a case portion, a drive motor provided in the case portion and having an output shaft, and the drive motor. A head portion that operates by the rotation of the output shaft and sucks and compresses the raw material air to generate the compressed air; and the raw material air is provided in the case portion by the rotation of the output shaft provided in the output shaft. And a raw material air intake part for supplying the raw material air to the head part side.
According to the above configuration. In the compressor of the present invention, noise can be reduced without directly leaking noise when the raw air is sucked to generate compressed air.

In the compressor of the present invention, the raw material air intake portion of the output shaft includes a screw that guides the raw material air in an axial direction of the output shaft at an end portion of the output shaft, and the raw material air by rotating the screw. And a cylindrical bearing member for taking in the case.
According to the said structure, raw material air can be gently taken in in a case part, preventing a noise leaking as much as possible directly from a compressor.

In the compressor according to the present invention, the driving motor is provided on the first side surface portion of the case portion, and the raw material of the output shaft is provided on the second side surface portion opposite to the first side surface portion of the case portion. An air intake section is provided.
According to the above configuration, since the drive motor and the raw material air intake portion of the output shaft can be separately arranged on the second side surface side opposite to the first side surface portion of the case portion, the size of the compressor can be reduced.

In the compressor of the present invention, the case portion is provided with a covering member for covering the raw material air intake portion of the output shaft.
According to the above configuration, the covering member can function as a noise prevention member for preventing noise when the raw material air intake portion of the output shaft takes in the raw material air and noise of the drive motor itself.

In the compressor according to the present invention, the covering member has an opening for introducing the raw material air into the raw material air intake part of the output shaft, and the raw material air introduced into the raw material air intake part of the output shaft. And a filter for removing impurities.
According to the above configuration, the raw air introduced into the raw air intake section through the opening necessarily passes through this filter, and can be taken in with impurities such as dust in the raw air removed.

In the compressor of the present invention, the compressor includes a first head portion provided on the first end side of the case portion, and a second head portion provided on the second end portion side of the case portion. The driving motor is housed in a region formed by the outer shape portion of the first head portion and the outer shape portion of the second head portion in the first side surface portion of the case portion, and the covering member The raw material air intake portion of the output shaft is within a region formed by the outer shape portion of the first head portion and the outer shape portion of the second head portion in the second side surface portion of the case portion. It is characterized by.
According to the above configuration, the compressor can be reduced in size, weight, and thickness.

The oxygen concentrator of the present invention is an oxygen concentrator comprising a compressor that compresses raw material air to generate compressed air, and an adsorbing member that contains an adsorbent that adsorbs nitrogen from the compressed air. A case portion; a drive motor provided in the case portion and having an output shaft; and operating by rotation of the output shaft of the drive motor to suck and compress the raw material air to generate the compressed air And a raw material air intake portion that is provided on the output shaft and takes in the raw material air by rotation of the output shaft and supplies the raw material air to the head portion side.
According to the above configuration, in the oxygen concentrator provided with the compressor of the present invention, when the raw material air is sucked to generate compressed air, noise can be reduced without leaking directly to the outside. An oxygen concentrator can be provided.

  The present invention can provide a compressor and an oxygen concentrator capable of reducing noise without generating noise directly when the raw material air is sucked to generate compressed air.

The block diagram which shows preferable embodiment of an oxygen concentrator provided with the compressor of this invention. The perspective view which looked at the compressor from the front. The perspective view which looked at the compressor shown in FIG. 2 from the U direction. The perspective view which looked at the compressor of Drawing 2 from the G direction. FIG. 3 is a perspective view showing an internal structure by cutting away a part of the compressor of FIG. 2 as viewed obliquely from above. The perspective view which decomposes | disassembles and shows the 1st head part of the compressor of FIG. Sectional drawing along the V direction in the PP line of the compressor 10 of FIG. The disassembled perspective view which shows a covering member. The figure which shows the external shape of a compressor with a dashed-two dotted line, and shows the introduction path | route and discharge path | route of the raw material air in this compressor with an arrow.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a block diagram showing a preferred embodiment of an oxygen concentrator equipped with a compressor of the present invention.
An oxygen concentrator 1 shown in FIG. 1 is a portable (also referred to as portable or mobile) oxygen concentrator as a preferred embodiment. The oxygen concentrator 1 shown in FIG. 1 uses, for example, a compressed aerodynamic fluctuation adsorption method (PSA: positive pressure fluctuation adsorption method) using compressed air as an oxygen generation principle.
In the positive pressure fluctuation adsorption method using only compressed air, only compressed air is sent into the adsorption cylinder to adsorb nitrogen. The positive pressure fluctuation adsorption method has an advantage that the compressor can be made smaller and lighter than the positive and negative pressure fluctuation adsorption method (VPSA) using compressed air and reduced pressure air.

A double line shown in FIG. 1 indicates a pipe serving as a flow path for raw material air, oxygen, and nitrogen gas. A thin solid line indicates power supply or electric signal wiring. The main casing 2 of the oxygen concentrator 1 shown in FIG. 1 is indicated by a broken line, and the main casing 2 is a sealed container that seals elements disposed inside. The main housing 2 is an injection-molded resin product, for example, and is made of a thermoplastic resin having impact resistance.
The main housing 2 shown in FIG. 1 has an intake port 2c for introducing raw material air, which is outside air, and an exhaust port 2b for exhausting. A filter 3 for removing impurities such as dust in the air is disposed at the intake port 2c. When the compressor 10 is operated, the raw material air passes through the filter 3 of the intake port 2c along the F direction. Is introduced into the compressor 10 through the pipe 4.

  The source air is introduced into the compressor 10 via the pipe 4 and compressed to become compressed air, but heat is generated when the source air is compressed. For this reason, the compressed air discharged from the compressor 10 is cooled by the rotation of the blower fan 5. By cooling the compressed air in this way, the temperature rise of the zeolite, which is an adsorbent that declines in function at high temperatures, can be suppressed, so that it functions sufficiently as an adsorbent for generating oxygen by adsorption of nitrogen. As a result, oxygen can be concentrated to about 90% or more.

  The first adsorption cylinder 108a and the second adsorption cylinder 108b are examples of adsorption members, and are arranged in parallel in the vertical direction. Three-way switching valves 109a and 109b as switching valves are connected to the first adsorption cylinder body 108a and the second adsorption cylinder body 108b, respectively. Of these switching valves, one end of the three-way switching valve 109 a is connected to the pipe 6. Further, the three-way switching valve 109 a and the three-way switching valve 109 b are connected to each other, and one end of the three-way switching valve 109 b is connected to the pipe 7.

  The pipe 7 and the pipe 6 are connected to each other. The pipe 7 is connected to the pipe 6 in order to perform a purification process for desorbing unnecessary gas in the first adsorption cylinder body 108a and the second adsorption cylinder body 108b. The three-way switching valves 109a and 109b are connected to the first adsorption cylinder 108a and the second adsorption cylinder 108b, respectively. The compressed air generated from the compressor 10 is alternately supplied to the first adsorption cylinder body 108a and the second adsorption cylinder body 108b via the pipe 6 and the three-way switching valves 109a and 109b.

Zeolite as a catalyst adsorbent is stored in the first adsorption cylinder 108a and the second adsorption cylinder 108b, respectively. This zeolite is, for example, an X-type zeolite having a Si ₂ O ₃ / Al ₂ O ₃ ratio of 2.0 to 3.0, and at least 88% or more of this Al ₂ O ₃ tetrahedral unit is composed of lithium cations. By using the bonded one, the adsorption amount of nitrogen per unit weight can be increased. This zeolite preferably has a granule measurement value of less than 1 mm, and at least 88% of tetrahedral units are fused with lithium cations. By using zeolite, it becomes possible to reduce the amount of raw material air used for generating oxygen compared to the case of using other adsorbents. As a result, the compressor 10 for generating compressed air can be further reduced in size and weight, and the noise of the compressor 10 can be reduced.

  As shown in FIG. 1, an equal pressure valve 107 including a check valve, a throttle valve, and an on-off valve is connected to the outlet side of the first adsorption cylinder body 108a and the second adsorption cylinder body 108b. A pipe 8 to be joined is connected to the downstream side of the equal pressure valve 107, and a product tank 111 is connected to the pipe 8. The product tank 111 is a container for storing oxygen having a concentration of about 90% or more generated by separation in the first adsorption cylinder 108a and the second adsorption cylinder 108b.

  As shown in FIG. 1, a pressure regulator 112 is connected to the downstream side of the product tank 111, and the pressure regulator 112 is a regulator that automatically adjusts the oxygen pressure on the outlet side of the product tank 111 to a constant level. . A zirconia-type or ultrasonic-type oxygen concentration sensor 114 is connected to the downstream side of the pressure regulator 112, and the oxygen concentration sensor 114 detects the oxygen concentration intermittently (every 10 to 30 minutes) or It is designed to be performed continuously.

As shown in FIG. 1, a proportional opening degree valve 115 is connected to the oxygen concentration sensor 114. This proportional opening valve 115 opens and closes in response to a setting button operation of the oxygen flow rate setting button 308 in accordance with a signal from the flow rate control unit 202 according to a command from the central control unit 200. An oxygen flow rate sensor 116 is connected to the proportional opening valve 115. A demand valve 117 is connected to the oxygen flow sensor 116 via a reduced pressure air circuit board for breathing synchronization control. The demand valve 117 is connected to the oxygen outlet 9 of the oxygen concentrator 1 through a sterilization filter 119. ing.
The adapter 313 of the nasal cannula 314 is detachably connected to the oxygen outlet 9. Adapter 313 is connected to nasal cannula 314 via tube 315. The patient can inhale oxygen concentrated to about 90% or more through the nasal cannula 314, for example, at a maximum flow rate of 1 L / min. By controlling the demand valve 117 and performing respiratory synchronization control, generally considering that the IE ratio (ratio of inspiratory time (seconds) to expiratory time (seconds)) is 1: 2, by respiratory synchronous control, This is equivalent to the effect of supplying oxygen concentrated to 90% or more at a maximum of 3 L / min to the patient.

Next, the power supply system shown in FIG. 1 will be described.
A connector 430 of an AC (commercial AC) power source shown in FIG. 1 is electrically connected to a switching regulator type AC adapter 419, and the AC adapter 419 rectifies the AC voltage of the commercial AC power source into a predetermined DC voltage. The built-in battery 228 is built in, for example, the bottom of the main housing 2. The external battery 227 is detachably provided via the connector 431. The power supply control circuit 226 is electrically connected to the connectors 430 and 431.
The built-in battery 228 and the external battery 227 are rechargeable secondary batteries, and the built-in battery 228 can be charged by receiving power from the power supply control circuit 226. The external battery 227 can be charged by receiving power supply from the power supply control circuit 226. However, normally, the external battery 227 is repeatedly charged using a separately prepared battery charger.

  1 controls the power supply control circuit 226, the power supply control circuit 226 receives the power supply from the AC adapter 419, and the built-in battery 228. Automatically in one of a total of three power supply states: a second power supply state that operates by receiving power supply from the battery, and a third power supply state that operates by receiving power supply from the external battery 227 Can be used by switching. The built-in battery 228 and the external battery 227 are preferably lithium ion or lithium hydrogen ion secondary batteries that have little memory effect during charging and can be fully charged even during recharging, but may be conventional nickel cadmium batteries or nickel metal hydride batteries. Further, in preparation for an emergency, the external battery 227 may be configured as a box of, for example, an AA battery that can be obtained anywhere.

  The central control unit 200 in FIG. 1 is electrically connected to a motor control unit 201 and a fan motor control unit 203. The central control unit 200 stores a program for switching to an optimal operation mode according to the amount of oxygen to be generated. The motor control unit 201 and the fan motor control unit 203 automatically drive the compressor 1 and the blower fan 5 at a high speed when generating a large amount of oxygen according to a command from the central control unit 200. Control is performed to rotationally drive the compressor 1 and the blower fan 5 at a low speed.

  The central control unit 200 incorporates a ROM (read-only memo) that stores a predetermined operation program. The central control unit 200 includes an external storage device 210, a volatile memory, a temporary storage device 208, and a real-time clock. The circuit 207 is electrically connected. The central control unit 200 can access the stored contents by connecting to the communication line 444 or the like via the external connector 433.

  Further, the three-way switching valves 109a and 109b and the equal pressure valve 107 shown in FIG. 1 are controlled to be turned on and off so that unnecessary gas in the first adsorption cylinder 108a and the second adsorption cylinder 108b is desorbed. A control circuit (not shown), the flow rate control unit 202, and the oxygen concentration sensor 114 are electrically connected to the central control unit 200. The flow control unit 202 drives and controls the proportional opening valve 115, the flow sensor 116, and the demand valve 117. In addition, an oxygen flow rate setting button 308, a display unit 128, and a power switch 306 are electrically connected to the central control unit 200 shown in FIG.

The oxygen flow rate setting button 308 can set the oxygen flow rate every time the oxygen concentrated to, for example, about 90% or more is operated in a step of 0.01 L from 0.25 L (liter) per minute to 1 L at the maximum. In order to supply 90% or higher concentration of oxygen to the patient at substantially 3 L / min by respiratory synchronization control, a synchronization mode selection switch (not shown) that can be operated by the patient is preferably provided. As the display unit 128, for example, a display device such as a liquid crystal display is used. The display unit 128 can display display items such as an operation lamp, an oxygen lamp, a synchronization mode, a charge lamp, a remaining battery level, an integration time, an oxygen flow rate, and the like. When the respiration synchronization control is operating, the “synchronization mode” display is lit in green, for example.

Next, a preferred structural example of the compressor 10 shown in FIG. 1 will be described with reference to FIGS.
2 is a perspective view of the compressor 10 as seen from the front, and FIG. 3 is a perspective view of the compressor 10 shown in FIG. 2 as seen from the U direction. FIG. 4 is a perspective view of the compressor 10 of FIG. 2 as viewed from the G direction. FIG. 5 is a perspective view showing the internal structure of the compressor 10 shown in FIG. FIG. 6 is an exploded perspective view showing the first head portion of the compressor 10 of FIG.

The compressor 10 shown in FIGS. 2 and 3 generates compressed air by the positive pressure fluctuation adsorption method (PSA) by generating only compressed air as described above, and the first adsorption cylinder 108a and the second adsorption cylinder 108a shown in FIG. Nitrogen in the compressed air is adsorbed by the adsorbent in the first adsorption cylinder 108a and the second adsorption cylinder 108b.
The compressor 10 shown in FIGS. 2 and 3 is a two-head compressor having a drive motor 11, a first head part 21, a second head part 22, and a case part 23. The overall weight is reduced to about 300 to 900 g depending on the configuration. The drive motor 11 is, for example, a 1L class electric motor, but may be, for example, a single-phase AC induction motor or a single-phase four-pole AC synchronous motor.

The first head portion 21, the second head portion 22, and the case portion 23 shown in FIG. 2 are made of aluminum, which is a lightweight metal material, for example, for weight reduction, but may be made of engineering plastic instead of metal. it can.
2 is provided at the first end (upper end) 23A of the case 23, and the second head 22 is provided at the second end (lower end) 23B of the case 23. It has been. The first head portion 21 and the second head portion 22 are reciprocating drive pump heads driven by one output shaft 15 of the drive motor 11. The first head portion 21 and the second head portion 22 are formed in a substantially vertical symmetrical shape about the rotation center axis CL of the output shaft 15.

As the drive motor 11 shown in FIG. 2, for example, if a synchronous motor is used, the rotation speed of the output shaft 15 can be kept constant even if the power supply voltage fluctuates. The piston of the first head portion 21 and the second head portion 22 Can be driven reciprocally along the V direction. Since the driving motor 11 that is a synchronous motor can rotate at the synchronous rotational speed, power consumption can be reduced as compared with the induction motor.
The first head portion 21 and the second head portion 22 shown in FIG. 1 can stably supply compressed air to the first adsorption cylinder body 108a and the second adsorption cylinder body 108b, and the first adsorption cylinder body 108a and the second adsorption cylinder body 108b. The adsorption cylinder 108b can stably supply oxygen concentrated to 90% or more at a set oxygen flow rate.

First, the structure of the case portion 23 of the compressor 10 will be described with reference to FIGS.
As shown in FIGS. 2 and 3, the case portion 23 is also called a crankcase, and is arranged along the V direction. This V direction is a direction orthogonal to the rotation center axis CL.
As shown in FIGS. 2 and 3, the case portion 23 has a main body portion 24, a first end portion 23 </ b> A, and a second end portion 23 </ b> B. The first end portion 23A is a portion to which the first head portion 21 is attached, and the second end portion 23B is a portion to which the second head portion 22 is attached.

  As shown in FIG. 2, the thickness W of the case portion 23 is set to be considerably smaller than the thickness W1 of the first end portion 23A and the second end portion 23B. Further, as shown in FIG. 3, another lateral width W2 of the case portion 23 is set to be slightly smaller than another lateral width W3 of the first end portion 23A and the second end portion 23B. The thickness W of the case portion 23 shown in FIG. 2 is set to be considerably smaller than another lateral width W2 of the case portion 23 shown in FIG. As a result, the case portion 23 is made smaller and thinner than the first head portion 21 and the second head portion 22.

  As shown in FIGS. 2 and 3, the drive motor 11 is fixed to the first side portion 31 of the case portion 23 so as to be replaceable by a plurality of bolts 11 </ b> M. As shown in FIG. 4, a circular opening 33 is formed in the second side portion 32 of the case portion 23. The output shaft 15 of the drive motor 11 projects from the opening 33 in the T direction along the center of the opening 33, that is, the rotation center axis CL.

  As shown by the broken lines in FIGS. 3 and 4, the case portion 23 has a first communication passage 41 and a second communication passage 42. The first communication passage 41 and the second communication passage 42 are formed in parallel to the V direction. The first communication passage 41 is formed in the first side portion 23 </ b> R of the case portion 23. The first communication passage 41 is provided to supply raw material air to the first head portion 21 and the second head portion 22.

  On the other hand, the second communication passage 42 shown in FIGS. 3 and 4 is formed in the second side portion 23 </ b> T of the case portion 23. The second communication passage 42 discharges compressed air generated by compressing raw material air in the first head portion 21 and the second head portion 22 to the outside of the case portion 23 through a compressed air discharge port 37. Is provided. The other opening 38 is closed by a cap 38P as shown in FIG.

Reference is now made to FIG. FIG. 5 shows a partial internal structure of the compressor 10.
The first head portion 21 has an upper head cover 51 and a first piston 61. The head cover 51 is fixed to the first end portion 23A of the case portion 23 with a uniform force using a plurality of screws 51N. The first piston 61 is attached to the connecting rod 61C. The connecting rod 61C is attached to the output shaft 15 using a bearing member.

  As shown in FIG. 5, since the plurality of screws 51N are fixed so as to give the head cover 51 and the like to the first end portion 23A with an equal fastening force, air leaks out from the first head portion 21. Can be prevented. In addition, as shown in FIG. 5, the head cover 51 has a plurality of heat-dissipating recesses 51S, so that the effect of dissipating heat when generating compressed air can be improved. That is, heat is generated when the first piston 61 moves linearly along the V direction from the bottom dead center to the top dead center in the first head portion 21 to compress the raw material air to generate compressed air. The generated heat can be efficiently discharged to the outside by providing the heat sink area 51S to increase the heat radiation area.

  Similarly, the second head portion 22 shown in FIG. 5 has a lower head cover 52 and a second piston 62. The lower head cover 52 has the same shape as the upper head cover 52. The lower head cover 52 is fixed to the second end portion 23B of the case portion 23 with a uniform force using a plurality of screws 52N. The second piston 62 is attached to the connecting rod 62C. The connecting rod 62C is attached to the output shaft 15 using a bearing member. In addition, the head cover 51 of the 1st head part 21 and the head cover 52 of the 2nd head part 22 have a rhombus shape in the example of illustration.

  As shown in FIG. 5, since the plurality of screws 52N are fixed so as to give the head cover 52 and the like to the second end portion 23B with equal fastening force, air leaks out from the second head portion 22. Can be prevented. In addition, since the head cover 52 is also provided with a plurality of heat-dissipating recesses (not shown), the effect of dissipating heat when generating compressed air can be improved. That is, heat is generated when the second piston 62 moves linearly along the V direction from the bottom dead center to the top dead center in the second head portion 22 to compress the raw material air to generate compressed air. The generated heat can be efficiently released to the outside by providing a heat radiating recess to increase the heat radiating area.

Next, a structural example of the first head portion 21 will be described with reference to FIG.
FIG. 6 is an exploded perspective view showing the first head unit 21. However, the first head portion 21 and the second head portion 22 have the same stacked structure except that the vertical positional relationship is opposite. Therefore, the structure of the first head unit 21 will be described as a representative.

  FIG. 6 shows a head cover 51 of the first head portion 21, upper and lower gaskets 191 and 192, an upper member 193, a reed valve member 194, and a lower member 195, and these members are used for the head assembly. It is composed. The head cover 51 is formed by a plurality of bolts 51N with the gaskets 191, 192, the upper member 193, the reed valve member 194, and the lower member 195 sandwiched in the illustrated order with respect to the first end 23A of the case portion 23. Can be fixed evenly. The gaskets 191 and 192 are provided so as not to leak to the outside when the raw material air is compressed. The gasket 191 has an opening 199, and the gasket 192 has a circular opening 199B. The reed valve member 194 has two reed valves 194A and 194B. The upper member 193 has openings 193A and 193B, and the lower member 195 has openings 195A and 195B.

  As shown in FIG. 6, the raw material air 70 indicated by the solid line arrow is taken in by the continuous rotation of the raw material air feeding portion 90 for feeding the raw material air of the output shaft 15, passes through the first communication passage 41, and reaches the gasket 192. Through the hole 192H, the hole 195H of the lower member 195, the hole 194H of the reed valve member 194, the hole 193H of the upper member 193, and the opening 199 of the gasket 191, further the opening 193A of the upper member 193 and the reed valve of the reed valve member 194 194A, the opening 195A of the lower member 195, and the opening 199B of the gasket 192 are supplied to the first piston 61.

On the other hand, when the first piston 61 moves from the bottom dead center to the top dead center and the raw material air 70 is compressed, compressed air 71 is generated. The compressed air 71 indicated by the broken-line arrow passes through the opening 199B of the gasket 192, the opening 195B of the lower member 195, the reed valve 194B of the reed valve member 194, the opening 193B of the upper member 193, and the opening 199 of the gasket 191. Further, the hole 193L of the upper member 193, the hole 194L of the reed valve member 194, the hole 195L of the lower member 195, and the hole 192L of the gasket 192 can be discharged from the discharge port 37 to the outside of the case portion 23 through the second communication passage 42. It is like that.
The path of the raw material air 70 and the compressed air 71 described above is the same in the second head portion 22.

Reference is now made to FIG. FIG. 7 is a cross-sectional view showing a cross-sectional structure along the V direction in the PP line of the compressor 10 shown in FIG. However, the external appearance of the driving motor 11 is shown without showing a cross section.
In FIG. 7, the first head portion 21 and the second head portion 22 have a substantially vertically symmetric structure about the rotation center axis CL, and the first piston 61 and the second head portion 22 of the first head portion 21. The second piston 62 is a horizontally opposed piston that reciprocates in the opposite direction along the V direction.

In the example of FIG. 7, when the first head portion 21 performs the suction process of sucking the raw material air into the first cylinder 61S, the second head portion 22 also sucks the raw material air into the second cylinder 62S at the same time. When performing the compression step of compressing the air sucked by the first head portion 21 and generating the compressed air in the first cylinder 61S, the second head portion 22 also compresses the sucked air at the same time. A compression process for generating compressed air in the second cylinder 62S is performed. That is, when the first piston 61 is located at the bottom dead center in the first cylinder 61S, the second piston 62 is also located at the bottom dead center in the second cylinder 62S, and the first piston 61 is located above the first cylinder 61S. When located at the dead point, the second piston 62 is also located at the top dead center in the second cylinder 62S.
Therefore, the first piston 61 and the second piston 62 reciprocate with an equal stroke length of about 1 mm to 10 mm in synchronization with the opposite directions. When the stroke length is shorter than 1 mm, the amount of raw material air to be compressed becomes small, and when the stroke length is longer than 10 mm, the compressor 10 becomes longer. Thus, as illustrated in FIG. 7, when the first piston 61 and the second piston 62 are located at the top dead center, the raw air in the cylinders 61S and 62S is compressed. On the contrary, when the first piston 61 and the second piston 62 are located at the bottom dead center, the raw material air is sucked into the cylinders 61S and 62S. The inner diameter of the cylinder 61S and the inner diameter of the cylinder 62S are equal and are formed to be about 20 mm to 60 mm. When the inner diameter of the cylinder 61S and the inner diameter of the cylinder 62S are smaller than 20 mm, the amount of raw material air to be compressed becomes smaller. When the inner diameter of the cylinder 61S and the inner diameter of the cylinder 62S is larger than 20 mm, it is difficult to reduce the size and weight of the compressor 10. .

Next, the structure of the drive motor 11 and the output shaft 15 of the drive motor 11 will be described with reference to FIGS. 7, 5, and 3.
As shown in FIG. 3, the drive motor 11 is fixed to the first side surface portion 31 side of the case portion 23 with bolts 11 </ b> M. As shown in FIG. 7, the drive motor 11 is a substantially cylindrical motor that is thinly formed along the rotation center axis CL. The drive motor 11 is preferably accommodated in a space 11S between the first head portion 21 and the second head portion 22. That is, the drive motor 11 is arranged so as to be accommodated in the space 11S so as not to protrude from the first head portion 21 and the second head portion 22 in the direction of the rotation center axis CL. In other words, the drive motor 11 is preferably within a region formed by the outer shape portion of the first head portion 21 and the outer shape portion of the second head portion 22 in the first side surface portion 31 of the case portion 23. . As a result, the drive motor 11 is accommodated without protruding outward from the outer portion of the compressor 10, so that the compressor 10 can be reduced in size, weight, and thickness.

As shown in FIG. 7, the output shaft 15 passes through the bearing portion 61N of the connecting rod 61C and the bearing portion 62N of the connecting rod 62C, and opens on the second side surface portion 32 side of the case portion 23 along the rotation center axis CL. Protruding from. A raw material air intake portion 90 for taking in the raw material air is formed at the protruding end of the output shaft 15.
The end of the output shaft 15 has a screw 90S that can take in the raw material air along the arrow M direction into the case portion 23 by continuously rotating around the rotation center axis CL. That is, a spiral groove is formed at the end of the output shaft 15 so as to surround the outer periphery thereof. The raw air intake section 90 includes the screw 90S and a cylindrical bearing member 91D. The screw 90S has a groove depth of about 1 mm to 10 mm and a pitch of about 3 mm to 20 mm. When the groove depth is less than 1 mm, the amount of raw material air taken in decreases, and when the groove depth exceeds 10 mm, the strength of the screw 90S decreases. When the pitch is larger than 20 mm, the length of the screw 90S becomes long, and it becomes difficult to reduce the size of the compressor 10.

As shown in FIG. 7, the output shaft holding member 91 is fixed to the second side surface portion 32 of the case portion 23. The output shaft holding member 91 is fixed so as to close the opening 33 of the case portion 23. The output shaft holding member 91 fixes a cylindrical bearing member 91D. A screw 90S of the raw material air intake section 90 of the output shaft 15 is inserted into the bearing member 91D. The screw 90S of the raw air intake section 90 of the output shaft 15 is rotatably supported in a cylindrical bearing member 91D.
Thereby, when the output shaft 15 of the drive motor 11 continuously rotates and reciprocates the first piston 61 and the second piston 62, the raw material air intake section 90 simultaneously guides the raw material air into the spiral groove. , And can be taken into the case portion 23 in the direction of the arrow M. For this reason, it is not necessary to separately provide a raw material air suction device for taking the raw material air into the case portion 23, and the compressor can be reduced in size, weight, thickness, and structure.

  In addition, the screw 90S of the raw material air intake section 90 rotates on the inner peripheral surface of the cylindrical bearing member 91D, so that the raw material air is guided while being guided in the axial direction 15 of the output shaft. The end of the output shaft 15 is formed in a screw shape so that the case 23 can be smoothly taken in the direction of the arrow M. For this reason, since the raw material air can be gently taken into the case portion 23 while preventing the noise from leaking directly from the compressor 10, the noise can be reduced. As the output shaft 15 rotates continuously, the screw 90S of the raw material air intake section 90 of the output shaft 15 reliably feeds the raw material air into the case portion 23 along the arrow M direction on the inner peripheral surface of the cylindrical bearing member 91D. Can be imported.

The raw material air intake part 90 of the output shaft 15 is preferably accommodated in a space 11P between the first head part 21 and the second head part 22. The raw material air intake portion 90 of the output shaft 15 is disposed so as to be accommodated in the space 11P so as not to protrude from the first head portion 21 and the second head portion 22 in the direction of the rotation center axis CL. That is, the raw material air intake portion 90 of the output shaft 15 is preferably in a region formed by the outer shape portion of the first head portion 21 and the outer shape portion of the second head portion 22 in the second side surface portion 32 of the case portion 23. It is settled.
That is, the compressor of this embodiment is provided on the first end portion side of the case portion 23, and the first head portion 21 having a size capable of accommodating the first piston 61 and the second end portion side of the case portion 23. And a second head portion 22 having a size capable of accommodating the second piston.
Then, as shown in FIG. 7, between the first head portion 21 and the second head portion 22 and inside the virtual extension lines G1 and G1 of the outer edges of the head portions 21 and 22, The motor 11 and the raw material air intake portion 90 driven by the driving motor are accommodated.
More specifically, in the region inside the virtual extension lines G1 and G1 of the outer edges of the head portions 21 and 22, on one side of the connecting rods 61C and 62C that drive the first and second pistons described above. The drive motor 11 is disposed on a certain first side surface portion, and the raw material air intake portion 90 having the output shaft 15 and the cover portion 92 is disposed on the second side surface portion on the other side.
Thereby, since the raw material air intake part 90 of the drive motor 11 is accommodated without protruding from the outer shape of the compressor 10, the compressor 10 can be reduced in size and thickness.
In addition, since the drive motor and the raw material air intake portion of the output shaft can be separately arranged on the second side surface portion opposite to the first side surface portion of the case portion, the size and weight of the compressor can be reduced.

Next, the covering member 92 will be described with reference to FIGS.
FIG. 8 is an exploded perspective view showing the covering member 92. As shown in FIG. 7, the covering member 92 is disposed in the space 11P between the first head portion 21 and the second head portion 22, and preferably with respect to the second side surface portion 23P side of the case portion 23. It is detachably fixed by a mechanical meshing structure or a screwed structure. If a mechanical meshing structure is employed, the covering member 92 can be removed from the case portion 23 with a single touch or attached in reverse.
As shown in FIG. 7, the covering member 92 covers the raw material air intake portion 90 of the output shaft 15. The covering member 92 and the filter 95 are arranged coaxially with respect to the raw air intake portion 90 of the output shaft 15 with the rotation center axis CL as the center.

  As shown in FIG. 8, the covering member 92 includes a circular covering case 93, a ring-shaped cover member 94, and a ring-shaped filter 95. The cover case 93 and the cover member 94 are made of a light metal such as plastic or aluminum. The cover case 93 has a large diameter portion 93B and a small diameter portion 93C. The small diameter portion 93C is formed to protrude along the axial direction E with respect to the large diameter portion 93B. A ring-shaped rib portion 93D is formed on the large-diameter portion 93B so as to protrude along the axial direction E. The axial direction E shown in FIG. 8 is coaxial with the rotation center axis CL shown in FIG. The ring-shaped rib portion 93D and the small diameter portion 93C form an accommodation space 93S for accommodating and covering the raw material air intake portion 90 of the output shaft 15 shown in FIG.

  The ring-shaped cover member 94 is fixed to the cover case 93. The ring-shaped cover member 94 and the cover case 93 may be separate bodies or may be formed as a single body. A plurality of source air intake openings 96 are formed in the ring-shaped cover member 94 at the same angular interval. In the example of FIG. 8, four raw material air intake openings 96 are formed every 90 degrees. However, the present invention is not limited to this, and one, two, three, or five or more raw air intake openings 96 are formed. May be. The ring-shaped cover member 94 and the rib portion 93D are formed coaxially about the central axis E.

The ring-shaped filter 95 shown in FIGS. 8 and 7 is replaceably mounted in the cover member 94 in order to remove impurities in the raw material air introduced into the case portion 23. The filter 95 is not particularly limited as long as impurities such as a porous material and a nonwoven fabric can be removed.
The covering member 92 having the above structure is accommodated in the space 11P between the first head portion 21 and the second head portion 22. That is, the covering member 92 is disposed so as to be accommodated in the space 11P so as not to protrude outward from the first head portion 21 and the second head portion 22 in the direction of the rotation center axis CL. Thereby, since the covering member 92 is accommodated without protruding from the outer portion of the compressor 10, the compressor 10 can be reduced in size and thickness.

Next, referring to FIG. 9, examples of the feed air introduction path 59 and the compressed air discharge path 79 after the feed air is compressed in the first head portion 21 and the second head portion 22 of the compressor 10 are described. explain.
In FIG. 9, the outer shape of the compressor 10 is indicated by a two-dot chain line, the raw material air introduction path 59 in the compressor 10 is indicated by a solid line, and the compressed air discharge path 79 is indicated by a broken line.

  5 has a plurality of raw material air intake openings 96, a raw material air intake portion 90 of the output shaft 15, and a first communication passage 41 connected to the raw material air intake portion 90. . The plurality of raw material air intake openings 96 are connected to the filter 3 side of the intake port 2 c via the pipe 4. The first communication passage 41 communicates with the upper first cylinder 61S and the lower second cylinder 62S. Thus, the raw air 70 can be supplied into the upper first cylinder 61S and the lower second cylinder 62S via the raw air introduction path 59 shown by a solid line.

  On the other hand, the compressed air discharge path 79 after the raw material air is compressed has a second communication passage 42 and a discharge port 37, and the first adsorption cylinder 108 a and the second adsorption cylinder via the pipe 6. It is connected to the body 108b side. As a result, the compressed air 80 generated in the upper first cylinder 61S and the lower second cylinder 62S passes through the second communication passage 42 and the pipe 6, and the first adsorption cylinder 108a and the second adsorption cylinder. It can be supplied to the 108b side.

Next, an operation example of the oxygen concentrating device 1 including the compressor 10 as described above will be described.
1 instructs the motor control unit 201, the motor control unit 201 starts the drive motor 11 of the compressor 10, and the output shaft 15 of the drive motor 11 shown in FIGS. It rotates continuously around the rotation center axis CL. For this reason, the first piston 61 of the first head portion 21 and the second piston 62 of the second head portion 22 shown in FIG. 7 stably reciprocate in opposite directions.

In FIG. 7, the first piston 61 is located at the bottom dead center in the first cylinder 61S, and at the same time, the second piston 62 is located at the bottom dead center in the second cylinder 62S, and the first piston 61 is located at the top dead center in the cylinder 61S. At the same time as being located at the dead center, the second piston 62 is also located at the top dead center in the cylinder 62S. As shown in FIG. 7, when the first piston 61 and the second piston 623 are located at the top dead center, the raw air in the cylinder 61S and the second cylinder 62S is compressed.
Conversely, when the first piston 61 and the second piston 623 are located at the bottom dead center, the raw material air is sucked into the first cylinder 61S and the second cylinder 62S.
That is, the first piston 61 and the second piston 62 of the first head portion 21 simultaneously perform the air suction process, and then perform the compression process of compressing and discharging the compressed air at the same time. Repeat the compression process.

When the first head portion 21 and the second head portion 22 of the compressor 10 operate in this way, as shown in FIG. 9, the raw air 70 has a plurality of raw air intake openings in the raw air introduction path 59 shown by a solid line. 96 and the first communication passage 41, and can be sucked into the upper first cylinder 61S and the lower second cylinder 62S.
When the raw material air 70 is inhaled, impurities such as dust contained in the raw material air shown in FIG. 9 can be removed by the filter 3 and further removed by another filter 95 shown in FIG. In addition, by removing the cover member 92 before impurities are accumulated in the filter 95, the filter 95 can be easily cleaned or replaced. For this reason, the maintainability of the filter 95 can be improved.

The screw 90S of the raw material air intake section 90 of the output shaft 15 shown in FIG. 9 continuously rotates around the rotation center axis CL, so that the raw material air is guided between the spiral groove of the screw 90S and the cylindrical bearing member 91D. Then, it can be taken into the first communication passage 41 of the case portion 23. Accordingly, it is not necessary to separately prepare a raw air intake device in order to take the raw air into the case portion 23, so that the compressor can be reduced in size and the structure can be simplified.
Since the raw air intake section 90 is formed in a screw shape so as to take the raw air into the case section 23, the raw air intake section 90 is quiet while preventing noise from leaking directly from the compressor 10. The raw material air can be taken into the case portion 23.

Moreover, the covering member 92 covers the periphery of the raw material air intake portion 90 of the output shaft 15. For this reason, when the output shaft of the driving motor for the compressor rotates, the covering member 92 causes noise directly from the inside of the case portion when the piston is operated to suck in the raw material air and generate compressed air. Can be prevented from leaking. For this reason, compressed air can be generated by reliably sucking the raw material air into the piston side with low noise.
Further, the covering member 92 can serve as a noise leakage preventing member that prevents the noise when the raw material air is taken in and the noise of the driving motor 11 itself from leaking to the outside. For this reason, the raw material air intake part 90 can take the raw material air into the case part 23 more silently while preventing noise from leaking directly from the compressor 10.
On the other hand, in FIG. 9, the compressed air 80 generated in the upper first cylinder 61 </ b> S and the lower second cylinder 62 </ b> S passes through the second communication passage 42, the discharge port 37, and the pipe 6. It can be supplied to the first adsorption cylinder 108a and the second adsorption cylinder 108b.

  In addition, since heat generate | occur | produces when the compressor 10 of FIG. 1 compresses raw material air and generate | occur | produces compressed air, the compressor 10 is cooled by the ventilation fan 5 shown in FIG. Therefore, the compressed air passes through the adsorbent in the first adsorption cylinder 108a and the second adsorption cylinder 108b through the pipe 6 and the three-way switching valves 109a and 109b, and adsorbs nitrogen, thereby separating oxygen. Is generated. The product tank 111 can store oxygen having a concentration of about 90% or more produced by separation.

  The oxygen concentration sensor 114 in FIG. 1 detects the oxygen concentration from the product tank 111. The proportional opening valve 115 opens and closes in conjunction with the oxygen flow rate setting button 308. The oxygen is then supplied to the nasal cannula 314 via the sterilization filter 119 and the oxygen outlet 7 of the oxygen concentrator 1. Thus, the patient can inhale oxygen concentrated to about 90% or more through the nasal cannula 314, for example, at a maximum flow rate of 1 L / min.

In the embodiment of the present invention described above, by using the compressor 10, when the raw material air is sucked to generate compressed air, the compressor 10 can be reduced in noise, and the compressor 10 and the oxygen concentrator 1 can be reduced in size and weight. Can be reduced.
In the positive pressure fluctuation adsorption method (PSA) using only compressed air, only compressed air is sent into the adsorption cylinder and nitrogen is adsorbed. Therefore, the compressor is smaller than the positive and negative pressure fluctuation adsorption method (VPSA) using compressed air and reduced pressure air. There is a merit that simplification of structure and simplification.
If a synchronous motor is preferably used as the drive motor 11, the rotational speed of the output shaft 15 can be made constant even if the power supply voltage fluctuates, and the first head section 21 and the second head section 22 can be stably rotated. Can be driven by.
As described above, in this embodiment, in particular, in a portable oxygen concentrator reduced in size and weight, it is possible to continuously supply oxygen concentrated to 90% or more up to 1 L / min. Can be reduced. Further, when the breath synchronization function is operated, oxygen concentrated to 90% or more can be supplied substantially up to 3 L / min.

By the way, the present invention is not limited to the above-described embodiments, and various modifications and changes can be made to the present invention, and various modifications can be made within the scope described in the claims.
In FIG. 7, the position of the outer surface of the drive motor 11 may be the same in the direction of the rotation center axis CL with respect to the outer portions of the first head portion 21 and the second head portion 22, or the drive motor 11. The position of the outer surface may be lower than the outer shape portions of the first head portion 21 and the second head portion 22.
For example, the oxygen concentrator is not limited to the illustrated portable oxygen concentrator, but may be a stationary oxygen concentrator. The motor for driving the compressor 10 shown in the figure is a synchronous motor of, for example, 1 L class (meaning that oxygen concentrated to 90% or more can be continuously supplied at 1 L / min), but is not limited to this and exceeds 1 L class. Motor having capacity, for example, 3L class (meaning that oxygen concentrated to 90% or more can be continuously supplied at 3L / min), 5L class (oxygen concentrated to 90% or more can be continuously supplied at 5L / min) For example, a motor suitable for the above may be used. Various types of driving motors can be used, and the driving motor may be a single-phase AC induction motor.
The first head portion 21 and the second head portion 22 are horizontally opposed so that the pistons reciprocate in opposite directions, but the present invention is not limited to this, and the two pistons may be arranged in a V shape, for example. .

  DESCRIPTION OF SYMBOLS 1 ... Oxygen concentrator, 2 ... Main housing, 2c ... Intake port, 3 ... Filter, 4 ... Piping, 6 ... Piping, 10 ... Compressor, 11 ... Drive motor, 15 ... output shaft, 21 ... first head, 22 ... second head, 23 ... case, 23A ... first end of the case (upper end) Part), 23B ... second end (lower end) of the case part, 59 ... introduction path of raw material air, 70 ... raw material air, 71 ... compressed air, 79 ... discharge path of compressed air , 90 ... Raw material air intake part of the output shaft, 90S ... Screw, 91D ... Cylindrical bearing member, 92 ... Cover member, 93 ... Cover case, 94 ... Cover member, 95 ... filter, 108a ... first adsorption cylinder (adsorption member), 108b ... second adsorption cylinder (adsorption) Wood)

Claims (7)

A compressor that generates compressed air by compressing raw air,
The compressor includes a case portion, a drive motor provided in the case portion and having an output shaft,
A head unit that operates by rotation of the output shaft of the drive motor, and sucks and compresses the raw air to generate the compressed air;
A compressor, comprising: a raw material air intake unit that is provided on the output shaft and takes in the raw material air into the case portion by rotation of the output shaft and supplies the raw material air to the head portion side.   The raw material air intake portion of the output shaft takes in the raw material air into the case by rotating a screw that guides the raw material air in an axial direction of the output shaft at an end portion of the output shaft. The compressor according to claim 1, further comprising a cylindrical bearing member.   The drive motor is provided on the first side surface portion of the case portion, and the raw material air intake portion of the output shaft is provided on the second side surface portion opposite to the first side surface portion of the case portion. The compressor according to claim 1 or 2, wherein the compressor is provided.   The compressor according to claim 3, wherein the case portion is provided with a covering member for covering the raw material air intake portion of the output shaft.   The cover member has an opening for introducing the raw material air into the raw material air intake portion of the output shaft, and removes impurities of the raw material air introduced into the raw material air intake portion of the output shaft. The compressor according to claim 4, further comprising: The compressor includes a first head portion provided on the first end portion side of the case portion, and a second head portion provided on the second end portion side of the case portion,
The driving motor is housed in a region formed by the outer shape portion of the first head portion and the outer shape portion of the second head portion in the first side surface portion of the case portion, and the covering member and the The raw material air intake portion of the output shaft is within a region formed by the outer shape portion of the first head portion and the outer shape portion of the second head portion in the second side surface portion of the case portion. The compressor according to claim 4 or 5, characterized by the above. An oxygen concentrator comprising a compressor that compresses raw material air to generate compressed air, and an adsorbing member that contains an adsorbent that adsorbs nitrogen from the compressed air,
The compressor includes a case portion, a drive motor provided in the case portion and having an output shaft,
A head unit that operates by rotation of the output shaft of the drive motor, and sucks and compresses the raw air to generate the compressed air;
An oxygen concentrating device, comprising: a raw material air intake unit that is provided on the output shaft and takes in the raw material air by rotation of the output shaft and supplies the raw material air to the head unit side.

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