KR20100019845A - A vacuum pump for an airtight container - Google Patents

Abstract

PURPOSE: A vacuum pump for an airtight container is provided to simplify the structure by a small number of composition parts, and to secure a perfect vacuum state of the container by the form of a volume variable air absorption chamber. CONSTITUTION: A vacuum pump for an airtight container comprises the following: an air absorption chamber(10) as a volume variable chamber including an opened bottom and an exhausting valve on the other side; an operational device(20) inducing the change of a volume by shrinking and expanding the air absorption chamber; and a supporting frame(30) fixing the composition parts including the air absorption chamber to a proper position. The air absorption chamber comprises a folded pipe(11) forming the walls around the edge, and an upper plate(12) forming the upper side of the air absorption chamber while connected to the folded pipe.

Description

Vacuum pump for an airtight container

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vacuum pump for a closed container, and more particularly, to a vacuum pump of a very preferred form capable of ensuring a high degree of vacuum while having a simple internal structure.

In order to prevent corruption of foods, it is common to put them in a sealed container and put them in a refrigerator. Recently, the inside of the sealed container is first vacuumed with a vacuum pump before being put into the refrigerator.

Even in the case of storing fruits or vegetables in an airtight container in a refrigerator, it is common to confirm their decay after a considerable period of time, and the process of decay is due to the presence of air inside the airtight container and the propagation of microorganisms. Vacuum state storage such as this is said to have a significant meaning in terms of suppressing corruption.

In view of this, in recent years, several types of vacuum pumps for hermetic containers have been developed and marketed.

However, there is a problem in that the overall structure including a passage structure for guiding and discharging air sucked from the vacuum container into the atmosphere is complicated and the number of components is large.

Moreover, since it is a kind of unusual structure that uses a conventional O-ring as a valve, air mixing on the air discharge passage is inevitable and the air intake mechanism from the sealed container is considerably large. In an irrational relationship, it is inevitable to point out the inherent problem that not only complete vacuum formation in a closed container is possible, but also a sufficient degree of vacuum is virtually difficult.

SUMMARY OF THE INVENTION The present invention has been made in view of such a conventional problem, and an object thereof is to provide a vacuum pump for a closed container of a preferred form, which can ensure a high degree of vacuum while having a simple internal structure.

The present invention also proposes a vacuum pump internal structure capable of ensuring a complete vacuum beyond a considerable degree of high degree of vacuum.

An object of the present invention as described above is to directly put the opening of the variable volume air intake chamber in the vacuum pump to the air outlet of the airtight container side and suck the air therein, and the air suctioned, that is, the air introduced from the airtight container Is achieved by adopting an air exhaust structure in the form of exhausting air directly through the exhaust valve into the atmosphere.

In other words, the vacuum pump of the present invention appropriately adjusts the volume-variable air intake chamber which is in contact with the air outlet of the sealed container, an operating device that induces a volume change by contracting or expanding the air intake chamber, and these air intake chambers. It is configured to include a support frame fixed to the position.

According to the present invention, it is possible to obtain a vacuum pump for a hermetically sealed container having a very simple structure and a small number of components, including the air inlet structure from the sealed container into the vacuum pump and the air discharge structure from the vacuum pump to the atmosphere.

Further, depending on the design shape of the volume-variable air intake chamber in the vacuum pump, it is possible to ensure a complete vacuum in the sealed container.

EMBODIMENT OF THE INVENTION Hereinafter, the vacuum pump for sealed containers of the Example of this invention is demonstrated in detail based on an accompanying drawing.

As shown in FIG. 1, which is a cross-sectional view of the vacuum pump for a closed container according to the first embodiment of the present invention, the vacuum pump 1 has a volume in which a lower end thereof is opened and an exhaust valve V1 is mounted on the other side. An air intake chamber 10 as a variable chamber, an actuating device 20 which contracts or expands the air intake chamber 10 to induce its volume change, and components such as these air intake chambers are properly positioned. It is configured to include a support frame 30 to be fixed to.

As shown, the air suction chamber 10 includes a corrugated pipe 11 forming a circumferential wall surface thereof, and an upper plate 12 coupled to the corrugated pipe 11 and forming an upper surface of the air suction chamber. As the upper plate 12 is moved up and down, the inner space of the corrugated pipe 11 is contracted or expanded, that is, the volume of the air suction chamber is changed.

The air intake chamber 10 is preferably made of soft synthetic resin or rubber in order to properly perform this characteristic function.

P1 and P2 denote pins interposed between the coupling parts, and V1 denote exhaust valves, respectively.

Reference numerals 21, 22, 23, and 24 denote slide plates, connecting bodies, springs, and operating cylinders constituting the operating device 20, respectively, and their functions will be described later.

Referring to FIG. 2, which is a plan view of the air intake chamber 10, the exhaust valve V1 attached on the upper surface of the top plate 12 has a simple structure as shown (exhaust through the air intake chamber upper surface). There may be various valve mounting structures other than the one in which the valve plate is bonded (hatched) to one side of the hollow (dotted portion).

The upper end of the air intake chamber 10 (in this embodiment, the upper surface of the top plate 12) is provided with a connecting projection 12-1 for interconnection with the aforementioned operation device 20.

One side end of the connecting body to be described later is pin-coupled between the pair of connecting protrusions 12-1 formed at regular intervals on both left and right side ends.

These connection protrusions 12-1 are, of course, formed with pin-holes facing each other.

Fastening ring (R) is fastened to the upper end of the corrugated pipe (11), that is, the upper plate (12) by fastening them to each other firmly, the fastening ring (R) is a good metal wire (wire), but the There is no need to specifically limit the material.

Corrugated pipe 11 constituting the lower end of the air suction chamber 10 is made of a soft synthetic resin or rubber, and tends to be in close contact with the surface of a food container, such as a food storage container, which is usually made of synthetic resin. This plays an important role in blocking the inflow of air from the surrounding atmosphere.

In addition, in the illustrated embodiment, the corrugated pipe 11 and the top plate 12 are manufactured as separate parts, but of course, these may be integrally manufactured.

According to FIG. 3, which shows the structure of the support frame and the mutual coupling relationship with the air intake chamber 10 in a front sectional view, the support frame 30 surrounds the air intake chamber 10 and has an open lower end thereof. Of the cylindrical body 31 of the cylindrical body 31 and the lower engaging plate 32 which is engaged with the lower end of the cylindrical body 31 and has an annular shape, that is, a central hole, and the upper end of the cylindrical body 31 in a rotatable state. It comprises a combined roller (33).

As shown, the lower end portion of the air suction chamber 10, that is, the lower end portion of the corrugated pipe 11, is engaged at the edge of the central hole on the lower coupling plate 32, between the cylindrical body 31 and the lower coupling plate 32. It is preferable to make mutual coupling of a screw connection structure.

On the other hand, when briefly explaining the mutual coupling, that is, the assembly relationship between the corrugated pipe 11 and the lower coupling plate 32, assembled all the components in their respective positions and finally screw the lower coupling plate 32 and Then, a method such as inserting a finger or the like into the central hole thereof, pulls the lower end of the corrugated pipe 11 made of a flexible material and engages the lower coupling plate 32.

Referring to FIG. 4, which is a plan view of the cylindrical body 31, four electric support members 31-1 are formed at left and right sides of the upper end of the cylindrical body 31, and a pair of these electric support members formed at regular intervals ( 31-1) The rollers (see FIG. 3) are pinned between the gaps.

As shown in the drawing, the upper end surface of the cylindrical body 31 is not a simple plate but both front ends thereof protrude in a lateral direction, and the vertically projected electric support 31-1 is located at the protruding extended portion. Form.

Reference numeral h1 denotes a hole through which a rope as a connector component to be described later is drawn out from the inside of the cylinder 31 to the outside, while reference numeral h2 denotes that the rope is connected to the sliding plate (see FIG. 1). Aisle home.

Referring again to FIG. 1, the operating device 20 includes a slide plate 21 as an annular plate member which is inserted into an outer circumference of the cylindrical body 31 constituting the support frame 30 and reciprocates up and down. A spring 22 mounted between the upper end of the air intake chamber 10 and the inner upper end surface of the cylindrical body 31 and the connecting body 22 to form a mutual interlocking system by connecting the plate 21 and the air intake chamber 10. (23), and an operation cylindrical body 24 which is fitted to the outer circumference of the cylindrical body 31 and whose lower end contacts the upper surface of the sliding plate 21 to transmit external operating force to the sliding plate 21. It is configured by.

External operating force means the force pressed down by the user of the vacuum pump during the pumping operation. The connecting body 22 is a rope having an appropriate thickness, and preferably made of a material having sufficient flexibility and having a small length variation due to temperature or the like.

On the other hand, the working cylindrical body 24 is normally in a position as shown in FIG. 1 except for the pumping operation for forming the vacuum in the sealed container so that the lower opening of the air intake chamber 10 can be closed and protected. It is desirable to.

According to FIG. 5, which is a perspective view of the connecting body, and FIG. 6, which is a plan view of the sliding plate, the connecting body 22 is coupled to both ends of the rope 22-1 of appropriate length and diameter and the rope 22-1. And integrated connectors 1 and 2 (22-2, 22-3).

Connector 1 (22-2) has a plate shape having a hole (h3) for pin coupling with the connecting projection (12-1) of the upper end of the upper plate 12, while connector 2 (22-3) is a sliding plate 21 It has a columnar shape such that it is caught in the rope passage groove h4 on ().

The rope passage groove h4 is a groove cut to an appropriate depth from the edge of the slide plate 21, and is mutually coupled in such a manner that the connector h2 22-3 as the connector component is caught in the groove h4.

According to various coupling schemes between the air suction chamber 10 and the connector 22 and the sliding plate 21 and the connector 22, the connector 1 and 2 (22-2, 22-3) is different from the drawing. Of course, other shapes or structures may be used.

7 is a side view showing a state in which the lower end surface of the working cylindrical body is in contact with the upper end surface of the sliding plate, that is, the overall engagement state in the pumping operation.

As shown, a vertical opening (H) of a suitable width is formed on the side wall of the working cylinder (24), which means that the motor support (31-1) and the roller (33) of the upper end of the cylinder (31) are operated. This is the result of cutting the corresponding part in order to prevent it from acting as an obstacle in the vertical reciprocating motion of the sieve 24 (see the vertical arrow).

Thereby, when the upper end of the operation cylindrical body 24 is put on the upper end of the closed container for vacuuming in the closed container and the vertical opening H is present, the operating cylindrical body 24 and the sliding body ( 21) As well as the whole descending, the lowering operation is transmitted to the air intake chamber in the cylindrical body 31 through the rope 22-1.

As shown, it is preferable that the lower end of the corrugated chamber 11 protrudes lower than the lower coupling plate 32, which is the lower surface of the corrugated chamber 11 due to the pressing force of the operator during the pumping operation. This is to make the contact more closely.

On the other hand, the return of the working cylindrical body 24, that is, the raising, is made by the elastic force of the spring 23 in the cylindrical body 31.

Referring to FIG. 8, a process of forming a vacuum in a hermetically sealed container using a vacuum pump according to an embodiment of the present invention, that is, a process of drawing out the air inside the hermetically sealed container is as follows.

The lower opening of the air suction chamber 10 surrounds the exhaust valve V2 of the upper surface of the sealed container 100 so that the vacuum pump 1 is brought into close contact with the upper surface of the sealed container 100 and then the working cylinder When pressing (24), as the sliding plate 21 which is in contact with the lower surface of the operation cylindrical body 24 is lowered together, the lowering force is transmitted to the upper end of the air suction chamber through the rope 22-1, the top plate 12 Is raised.

In this process, as well as the spring 23 is compressed, the compressed spring 23 acts as a power for lowering and restoring the upper plate 12 in a subsequent step.

As the upper plate 12 rises, the inner space expands while the corrugated pipe 11 expands, and as a result, a negative pressure is formed inside the air intake chamber 10.

Due to this negative pressure, a pressure difference is generated between the inner space of the air intake chamber 10 and the inner space of the airtight container 100, and the internal air of the airtight container 100 on a relatively high pressure state is exhaust valve V2. While opening and folds out of the inner space of the corrugated pipe 11, that is, the air intake chamber 10.

As shown in the drawing, the exhaust valve V2 is only open to the outside of the sealed container.

With reference to FIG. 9, the air discharge process from an air suction chamber to the atmosphere is demonstrated.

When the user releases the pressing force against the working cylindrical body 24, the upper plate 12 is lowered as the elastic restoring force of the spring 23 in the compressed state is applied, so that the inner space of the corrugated pipe 11, that is, the air suction chamber 10 It contracts.

As the air intake chamber 10 starts to contract and at the same time its internal pressure is higher than the internal pressure of the hermetic container 100, the exhaust valve V2 of the hermetic container is closed, and the air intake chamber contracts to some extent or less. When the internal pressure is higher than atmospheric pressure, the air intake chamber side exhaust valve V1 is opened toward the atmosphere.

As a result, the air inside the corrugated pipe 11, that is, the air inside the closed container which has flowed into the air suction chamber, is discharged into the atmosphere.

Meanwhile, as in the case of the airtight container side exhaust valve V2, the air intake chamber side exhaust valve V1 is of course configured to open toward the atmosphere.

By repeatedly performing this process, the air inside the sealed container 100 is released into the atmosphere to achieve a vacuum state.

Fig. 10 is a cross-sectional view showing the hermetically sealed container of the second embodiment of the present invention, in which the other components except for the top plate 12 'are the same as in the first embodiment.

In the vacuum pump 1 'of the second embodiment, the upper plate 12' has a shape in which the central portion thereof is recessed. As a result, the inner space when the air suction chamber is maximally retracted, that is, the air suction starts. The former initial internal space volume is near zero, allowing full vacuum in the sealed container.

In the case of a vacuum pump according to the conventional structure, there is not only a separate suction passage leading to the air suction chamber (a complicated structure distinctly different from the air suction chamber of the present invention), but also a considerable initial internal space including the passage space. As a result, the air inside the sealed container could not be completely drained.

In other words, a full vacuum was virtually impossible in a conventional vacuum pump for closed containers.

As such, in the case of the vacuum pump according to the second embodiment having a structure capable of fully evacuating the sealed container, the vacuum pump for the sealed container of the present embodiment has a very important meaning in terms of improving the vacuum efficiency.

FIG. 11 is a vacuum pump for a hermetically sealed container according to a third embodiment of the present invention. Since the upper end of the side wall of the cylindrical body 31 'serves as an electric support, separate electric transmission as in the case of the first and second embodiments is performed. There is no support (see FIG. 4), and both ends of the upper end surface of the cylindrical body 31 'protrude just to prevent upward departure of the sliding plate 21.

In the third embodiment, the cylindrical body 31 'is recessed to form a space enough to accommodate the smooth rotation of the roller 33 at both front ends thereof, and a separate pin support plate 31 is formed on the side wall of the recessed portion. '-1) is inserted into the structure.

In other words, in this case, the pin, the roller 33 and the pin support 31'-1 are assembled in a set form, and then assembled by inserting them from above the cylindrical body 31 '.

In the vacuum pump of the third embodiment of the present invention, the cylindrical upper end surface is flat, which has its own characteristics to give a simple feeling, and as the assembly method of the roller 33, there may be various methods other than the pin supporting plate 31'-1 as described above. Of course you can.

As mentioned above, although the vacuum pump for airtight containers of the Example of this invention was demonstrated in detail based on an accompanying drawing, various design changes within the range which does not deviate from the meaning of this invention are possible.

However, it should be understood that all minor changes as long as they have the configuration specified in the claims are within the technical scope of the present invention.

1 is a front sectional view of a vacuum pump for a sealed container according to a first embodiment of the present invention,

2 is a plan view of the air intake chamber constituting the vacuum pump of the first embodiment;

3 is a front sectional view showing the structure of the support frame constituting the vacuum pump of the first embodiment and mutual coupling relationship with the air intake chamber;

4 is a plan view of a cylindrical body constituting the vacuum pump of the first embodiment;

5 is a perspective view of a connecting body constituting the vacuum pump of the first embodiment;

6 is a plan view of the sliding plate constituting the vacuum pump of the first embodiment;

7 is a side view showing the overall coupling state in the pumping operation;

8 is a view showing a vacuum forming process in a closed container,

9 is a view showing an air discharge process from the air suction chamber to the atmosphere;

10 is a front sectional view of a vacuum pump for a closed container according to a second embodiment of the present invention,

Fig. 11 is a plan view of a cylindrical body that constitutes the vacuum pump of the third embodiment.

Explanation of symbols on the main parts of the drawings

10 air suction chamber 11 corrugated pipe

12: top plate 20: operating device

21: sliding plate 22: connector

23 spring 24 operating cylinder

30 support frame 31 cylindrical body

32: lower coupling plate V1, V2: exhaust valve

Claims (6)

An air intake chamber 10 as a variable volume chamber having a lower end portion thereof and an exhaust valve V1 mounted on the other side thereof; An actuating device 20 which contracts or expands the air intake chamber 10 to induce a volume change thereof; A vacuum pump for a sealed container, characterized in that it comprises a support frame (30) for fixing components such as the air suction chamber in a proper position. The method of claim 1, The air suction chamber 10 includes a corrugated pipe 11 forming a circumferential wall surface thereof, and an upper plate 12 coupled to the corrugated pipe 11 and forming an upper surface of the air suction chamber. Vacuum pump. The method of claim 1, The operating device 20 is a slide plate 21 as an annular plate member which is inserted into an outer peripheral portion of the cylindrical body 31 constituting the support frame 30 and reciprocates up and down, and the slide plate 21 and air suction. Connecting body 22 to form an interlocking system by connecting the seal 10, a spring 23 mounted between the upper end of the air suction chamber 10 and the inner upper end surface of the cylindrical body 31, the cylindrical body It characterized in that it comprises a working cylindrical body 24 which is fitted to the outer peripheral portion of 31 and its lower end is in contact with the top surface of the sliding plate 21 to transfer the external operating force to the sliding plate 21. Vacuum pump for containers. The method of claim 1, The support frame 30 surrounds the air suction chamber 10 and has a cylindrical body 31 having a lower end thereof open, and a lower coupling plate 32 that is combined with the lower end of the cylindrical body 31 and is generally annular. And a roller (33) coupled to the upper end of the cylindrical body (31) in a rotatable state. The method of claim 3, wherein The connector 22 includes ropes 22-1 of appropriate length and diameter, and connectors 1 and 2 (22-2, 22-3) coupled to and integrated at both ends of the rope 22-1. Vacuum pump for sealed container, characterized in that configured to. The method of claim 3, wherein A vertical opening (H) is formed in the side wall of the working cylinder (24), the vacuum pump for a sealed container.

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