KR200341014Y1 - Oxygen thickener having triple damper structure - Google Patents

Abstract

Provided is an oxygen concentrator having a triple damper structure having a structure for maximally suppressing transmission of vibration generated in a vacuum pump to a housing using at least two dustproof rubbers. The oxygen concentrator is a gas separation membrane module for concentrating oxygen by selectively permeating only oxygen in the air supplied from the outside and stored in the first container region of the pump case, and the high concentration of the permeated stored in the first container of the pump case. A vacuum pump for discharging oxygen to the outside through a vacuum pressure, anti-vibration rubbers for being located between the vacuum pump and the vacuum pump base positioned below the vacuum pump, and the vacuum pump base and the lower portion thereof It is configured to include a dust-proof rubber for the pump base which is located between the housing base to be fastened.

Description

Oxygen concentrator with triple damper structure {OXYGEN THICKENER HAVING TRIPLE DAMPER STRUCTURE}

The present invention relates to a structure of an oxygen concentrator that discharges concentrated oxygen by selectively permeating only oxygen in the air by using a gas separation membrane module and a vacuum pump, in particular by using at least two vibration-proof rubber The present invention relates to an oxygen concentrator having a triple damper structure having a structure for maximally suppressing transmission of vibration generated by a vacuum pump to a housing.

Recently, the necessity of oxygen generators or oxygen concentrators to supply fresh air with high oxygen concentration is increased due to the increase of air pollution such as automobile smoke and modern diseases due to the decrease of oxygen concentration in the city air. It is becoming. Such oxygen generators or oxygen concentrators are expanding their applications to domestic water purifiers, air conditioners, automotive oxygen generators, indoor ventilation oxygen generators, and the like.

As a method for generating small and medium-sized oxygen, a compression swing adsorption (PSA) method using an adsorbent and a gas separation membrane method using gas diffusion and permeation rate difference are used. The dual gas separation membrane method employs the principle of selective gas permeation for membranes, and separates gas components by using the rate difference at which gas components dissolve and diffuse into the membrane when the gas mixture contacts the membrane surface. Is made possible. The method using such a gas separation membrane module can simplify the configuration of the device and is widely used.

Examples of conventional oxygen generators applying such a gas separation membrane module include Korean Patent Application Laid-Open No. 2000-0063883 (oxygen supply device using gas separation membrane) and patent registration No. 10-0346571 (oxygen supply device). have.

As described above, the oxygen generators using the gas separation membrane module use a vacuum pump or a compression pump to supply high concentration oxygen and an appropriate flow rate to the outside. Oxygen generators using the vacuum pump or the compression pump as described above is inconvenient to use in a quiet indoor space because the noise caused by the operation of the pump is large.

For example, the vacuum pump causes vibration and noise by the reciprocating motion of the flanger constituting the internal pump during the suction delivery of the air, the vibration and noise is transmitted to the appearance of the oxygen generating device to shake the oxygen generating device itself. It has been a cause for increasing noise. In addition, the exhaust noise occurs in the process of discharging the concentrated oxygen by the operation of the gas separation membrane and the vacuum pump to the outside, the noise has been a problem when operating in a quiet room.

Therefore, an object of the present invention is to provide a gas separation membrane module and a vacuum pump to generate a high concentration of oxygen to prevent the transfer to the housing by suppressing the vibration generated by the driving of the vacuum pump to the maximum when discharged to the outside It is to provide a damper structure of the oxygen concentrator.

Another object of the present invention is to combine the vibration-proof rubber (vibration-proof rubber) to each of the housing base, the pump base and the vacuum pump, respectively to suppress the vibration generated by the operation of the vacuum pump to the maximum to transfer a small amount of vibration to the housing It is to provide an oxygen concentrator having a triple damper structure having a structure that prevents it from becoming.

In order to achieve the above object, the present invention includes a gas separation membrane module for concentrating oxygen by selectively permeating only oxygen in air supplied from the outside by being contained in the first container region of the pump case, and being stored in the first container of the pump case. In the oxygen concentrator having a vacuum pump for discharging the high concentration of permeated oxygen to the outside through a vacuum pressure, the anti-vibration rubber for the pump is placed between the vacuum pump and the lower vacuum pump base, and the vacuum And anti-vibration rubber for the pump base, which is placed between and coupled to the pump base and the lower housing base to prevent vibration of the pump case caused by the driving of the vacuum pump from being transmitted to the housing through the housing base. .

It is preferable that the first fastening part for fastening the anti-vibration rubber for pump and the second fastening part for fastening the anti-vibration rubber for pump base have a predetermined step in the vacuum pump base to remove vibration more effectively.

In addition, it is preferable that the lower portion of the vacuum pump base is extended in the horizontal direction to form a leg plate (lag plate) provided with the anti-vibration rubber insert to facilitate the fastening of the anti-vibration rubber for the pump base.

Finally, it is preferable that the vibration of the oxygen concentrator is prevented from going out of the housing by fastening the vibration-proof rubber for the housing at predetermined intervals to the lower portion of the edge of the housing base.

Oxygen concentrator having a triple damper structure of the present invention configured as described above is reduced by primarily damping the vibration generated in the vacuum pump housed in the region of the second container of the pump case to the dust-proof rubbers for fixing the vacuum pump do. The frequencies of the vibrations transmitted to the anti-vibration rubber for the pump are then absorbed in the anti-vibration rubber for the pump and the frequencies of the remaining unabsorbed vibrations are transmitted to the vacuum pump base coupled to the lower portion. The constant frequencies of the vibrations transmitted to the vacuum pump base are absorbed secondarily in the pump base by the specific structure of the vacuum pump base, and the remaining vibration frequencies are transferred to the anti-vibration rubber for the pump base and absorbed again. The remaining vibration frequencies after being absorbed and absorbed by the anti-vibration rubber for the pump base are transmitted to the anti-vibration rubber for the housing coupled to the housing base and the lower part, and then the frequencies of the vibrations which are not finally absorbed are transferred to the support surface of the oxygen concentrator. do. Therefore, vibration caused by the driving of the vacuum pump is sequentially absorbed by the anti-vibration rubber for the pump, the vacuum pump base, the anti-vibration rubber for the pump base, the housing base, the anti-vibration rubber for the housing base, so that vibration is hardly transmitted to the housing itself. Driving in a comfortable state is possible.

1 is an exploded perspective view of an oxygen concentrator according to a preferred embodiment of the present invention.

FIG. 2 shows an enlarged view of a portion of the components lying on top of the housing base of the oxygen concentrator shown in FIG. 1;

3 is a view for explaining the fastening structure of the vacuum pump base and the anti-vibration rubber for the pump base according to an embodiment of the present invention.

4A and 4B are detailed views and cross-sectional views of the anti-vibration rubber for the pump base shown in FIG. 3.

5 is a view showing an example of the anti-dust rubber for the pump shown in FIG.

6 is a view showing an example of the anti-vibration rubber for the housing base shown in FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the present invention may be embodied in many different forms and should not be limited to the described embodiments. It should be noted that the following examples are provided for the sake of explanation and to sufficiently convey the idea of the present invention to those skilled in the art. In addition, it should be noted that detailed description of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention are omitted.

1 is an exploded perspective view of an oxygen concentrator 10 according to a preferred embodiment of the present invention. Referring to FIG. 1, a vacuum pump base 34 damped and coupled to the upper portion of the housing base 32 with the anti-vibration rubber 62 for the pump base between the front housing 12A and the rear housing 12B constituting the housing 12. Is combined. In addition, a vacuum pump 36 damped and coupled to the upper part of the vacuum pump base 34 via the pump anti-vibration rubber 38 is disposed, and a gas separation membrane module 40 is disposed thereon. The vacuum pump 36 and the gas separation membrane module 40 disposed on the housing base 32 are surrounded by a pump case 30 (where 30 denotes a configuration in which the reference numerals 30A and 30B are combined).

In this case, a case sound absorbing agent 48 for absorbing and removing vibration noise transmitted from the inside to the outside is attached to the inner surfaces of the front housing 12a and the rear housing 12b constituting the housing 12. The pump case 30 has a structure in which a front pump case 30A and a rear pump case 30B are paired to store a vacuum pump 36 and a gas separation membrane module 40 coupled to an upper portion of the housing base 32 therein. The front and rear pump cases 30A and 30B should be tightly coupled so that there is no gap by a fastening screw.

Among the above components, the gas separation membrane module 40 selectively permeates only oxygen in the air sucked through the upper and left and right side portions to discharge the collected concentrated oxygen to the oxygen outlet and at the same time, the remaining air to the air outlet placed thereunder. Has the function to discharge it. In addition, the vacuum pump 36 positioned at the lower portion functions to pump the concentrated oxygen selectively discharged from the gas separation membrane module 40 to be discharged to the outside.

In addition, the upper left and right sides of the front and rear pump cases 30A and 30B have a dehumidification filter fixing part 42 (where 42 denotes a configuration in which the reference numerals 42a and 42b are combined) and a silencer high for fixing the dehumidification filter and the silencer. A government part (not shown in the drawing is shown in the silencer fixing part) is formed, and a pump driving chamber sound absorbing agent 46 for absorbing vibration noise caused by the driving of the vacuum pump 36 is attached to the lower inner surface of the pump case 30. At this time, the upper side of the pump case 30 is a first container for storing and storing the gas separation membrane module 40, the lower side is a second container for storing and storing the vacuum pump 36.

The configuration and operation of the oxygen concentrator according to the present invention as shown in FIG. 1 will be described in detail in Utility Application No. 2003-0035346 filed on November 12, 2003, by the inventors of the present application, "Mo Chang-yeon, Lim Tae-gyu and Lee Hyun-hee". It is becoming. Therefore, the present invention will be described in detail only in the structure of the damper for removing the vibration generated thereon in accordance with the operation of the vacuum pump 36, for the operation related to the generation of oxygen, please refer to the contents described in the above-mentioned prior application.

FIG. 2 is a view illustrating in more detail the configuration of a plurality of dustproof rubbers, a pump base, a vacuum pump, and a gas separation membrane module coupled to an upper portion of the housing base 32 located in the center of FIG. 1.

3 is a view for explaining the fastening structure of the vacuum pump base and the anti-vibration rubber for the pump base according to an embodiment of the present invention, Figures 4a and 4b is a detailed view and cross-sectional view of the anti-vibration rubber for the pump base shown in FIG. 5 is a view showing an example of the anti-dust rubber for the pump shown in FIG. 6 is a view showing an example of the anti-vibration rubber for the housing base shown in FIG.

Referring to FIG. 2, a vacuum pump 36 for pumping only oxygen collected and separated and permeated by the gas separation membrane module 40 is seated on a fastening boss formed on an upper portion of the housing base 32 and screwed to an upper portion of the vacuum pump base 34. Is coupled to At this time, between the vacuum pump base 34 and the vacuum pump 36 is placed in the anti-vibration rubber 38 for the pump formed as shown in Figure 5, the anti-vibration rubber 38 for the pump is formed on the upper part of the vacuum pump base 34 for the anti-vibration rubber fastener 64 It is fastened by screwing it in. The fastening is fastened by screwing the fastener 72 of the anti-vibration rubber 38 for pumps and the anti-vibration fastener 64 of the vacuum pump base 34.

Referring to FIG. 5, the anti-vibration rubber 38 for a pump according to the present invention includes a metal therein and primarily absorbs vibrations transmitted from the vacuum pump 36 in an external rubber, and secondly, absorbs in an internal metal a vacuum. A structure for absorbing vibrations by the pump 36 is achieved.

On the other hand, the lower part of the vacuum pump base 34 in which the anti-vibration rubber 38 for the pump is fastened to the upper part, the vacuum pump base into which the anti-vibration rubber 62 for the vacuum pump base, in which an insertion groove 70 is formed, as shown in FIGS. 4A and 4B. A leg plate 68 having a dustproof rubber insert 66 is formed. The leg plates 68 have a step with the anti-vibration rubber fastener 64 for the pump. This step is to absorb the vibration transmitted from the anti-vibration rubber 38 for the pump partly not only by the characteristics of the material of the vacuum pump base 34 but also by the structure of the vacuum pump base 34.

As described above, the vacuum pump base 34 in which the vibration base rubber 62 for the pump base is inserted into the leg plates 68 is seated on the upper fastening boss of the housing base 32, and a washer is placed on the hollow of the vibration base rubber 62 for the pump base. By fastening, the vacuum pump base 34 is fixedly coupled to the upper end of the housing base 32.

4A and 4B, the anti-vibration rubber 62 for the pump base is formed with an insertion groove 70 for inserting the vacuum pump base 34 in the middle portion thereof, so as to be effectively absorbed by using rubber to suppress the vertical vibration of the vacuum pump base 34. It has a structure.

Finally, the lower edge of the housing base 32 coupled to the upper end of the vacuum pump base 34 is fitted with the anti-vibration rubber 60 for the exterior base for transmitting the frequency of vibration transmitted from the upper side when the oxygen concentrator 10 is standing on the ground. A plurality of seating holes are formed, and the seating holes are fitted with the anti-vibration rubber 60 for the exterior base.

The anti-vibration rubber 60 for the exterior base has a first supporter 76 having a trapezoidal insert 78 formed thereon and having a locking groove 80 in the middle thereof, and a second supporter connected to the first supporter 76 by a connecting member 84. 82 is provided. The dustproof rubber 60 for the housing configured as described above is latched to the mounting groove when the insertion portion 78 is inserted into the seating groove of the housing base 32, and the first and second supporters 76 and 82 are the housing base 32. Maintain a certain distance from the ground.

The damping operation of the oxygen concentrator having the triple damper structure configured as described above is described in detail below.

The vacuum pump 36 for suctioning and discharging the outside air opens and closes the delivery valve and the suction valve alternately to discharge the high concentration of oxygen separated from the gas separation membrane module 40 while the gas is sucked and discharged. In this manner, vibration is generated in the vacuum pump 36 due to the reciprocating motion of the flanger during suction delivery of air.

The vibration of the vacuum pump 36 as described above is transmitted to the vacuum pump base 34 through the anti-vibration rubber 38 for the pump placed underneath. At this time, the frequencies of the vibrations transmitted to the anti-vibration rubber 38 for the pump are primarily absorbed by the anti-vibration rubber 38 for the pump, and the remaining frequencies of the unabsorbed vibrations are again caused by the stepped structure of the vacuum pump base 34 coupled to the lower portion thereof. Once absorbed, the remaining vibration frequencies are transferred to the anti-vibration rubber 62 for the pump base and absorbed again.

The remaining vibration frequencies after being delivered to and absorbed by the anti-vibration rubber 62 for the pump base are transmitted to and absorbed by the anti-vibration rubber 60 for the housing coupled to the housing base 32 and the lower portions of the vibrations which are not finally absorbed after the Delivered to the support surface.

Therefore, the vibration due to the driving of the vacuum pump is sequentially absorbed by the anti-vibration rubber 38 for the pump, the vacuum pump base 34, the anti-vibration rubber 62 for the pump base, the housing base 32, the anti-vibration rubber 60 for the housing base, and the like. It is not transmitted, and operation is possible in a comfortable state.

As described above, the oxygen concentrator according to the present invention is designed to absorb most of the vibration generated in the vacuum pump 36 in the anti-vibration rubber 38 for the pump and the vacuum pump base 34 and the anti-vibration rubber 62 for the pump base. The minor part consists of a triple damper absorbed by the housing 12 and the anti-vibration rubber 60 for the housing base, so that little vibration is transmitted to the housing.

As described above, the present invention fastens the vibration of the pump by fastening the pump dustproof rubber of the oxygen concentrator using the gas separation membrane module between the vacuum pump and the vacuum pump base, and fastening the dustproof rubber for the pump base between the vacuum pump base and the housing base. Occurs only in the pump case and prevents the pump from transmitting vibrations and reduces the pump vibrations, allowing the user to use the oxygen concentrator comfortably in a quiet atmosphere.

Claims (4)

A gas separation membrane module for selectively concentrating oxygen by selectively permeating only oxygen in air supplied from the outside of the first container region of the pump case; and storing the high concentration of oxygen permeated in the first container of the pump case. An oxygen concentrator having a vacuum pump for discharging to the outside through at least one of the dust-proof rubber for the pump placed and fastened between the vacuum pump and the lower vacuum pump base, the vacuum pump base and the lower housing An oxygen concentrator having a triple damper structure, comprising vibration damping rubbers for the pump base that is fastened between the bases to prevent vibration of the pump case caused by the driving of the vacuum pump to be transmitted to the housing base. According to claim 1, wherein the vacuum pump base has a triple damper structure characterized in that a step is formed between the anti-vibration rubber fastening portion for fastening the anti-vibration rubber for pump and the fastening portion for fastening the anti-vibration rubber for the pump base. Having an oxygen concentrator. According to claim 1, Oxygen concentrator having a triple damper structure characterized in that the bottom of the vacuum pump base is formed with a leg plate with a dust-proof rubber insert for inserting the anti-vibration rubber for the pump base. The triplet according to any one of claims 1 to 3, wherein vibration damping of the oxygen concentrator is not transmitted to the housing by fastening the dustproof rubber for the housing at predetermined intervals to the lower portion of the edge of the housing base. Oxygen concentrator with damper structure.