KR101161732B1 - Vacuum Generating Apparatus and Vacuum Container Using the Same - Google Patents

Abstract

The present invention relates to a vacuum generator and a vacuum container using the same, a vacuum generating device integrally provided with a container cap that can maintain a vacuum state inside the container for a long time by using the upper and lower cam structures.
The present invention covers a top of the container body having a receiving space, the container cap formed with a through hole in the center; A cylinder having a cylindrical portion having a circular inner circumferential surface opened upwardly and having an outer circumference coupled to and fixed to an inner circumference of the container cap, and having a circular protrusion formed at a central portion thereof to form an inlet and a lower valve groove communicating with the container body; A piston having a tubular shape which is open downward and has an exhaust port and an upper valve groove formed in the center of the upper surface, and extends from the lower side of the upper surface to surround the exhaust port; An upper cap coupled to an upper portion of the piston through a coupling protrusion surrounding the upper valve groove; An upper valve coupled to the upper valve groove to open and close the exhaust port according to the descending and rising of the piston; A lower valve for opening and closing an inlet port according to the rise and fall of the piston in the lower valve groove; A pressure valve cover having a first cylindrical portion and a second cylindrical portion having a lower outer circumference coupled to the circular protrusion; An elastic member that provides an upward restoring force for the piston; And a pressurizing cap rod having a lower end portion pressurized at an uppermost portion of the lower valve, an outer circumferential portion coupled to a second cylinder portion of the pressure valve cover, and a lower cam disposed at the upper end portion.

Description

Vacuum Generating Apparatus and Vacuum Container Using the Same}

The present invention relates to a vacuum generating device and a vacuum container using the same, in particular, a vacuum generating device having a vacuum generating device that is integrally provided in the container cap to maintain the vacuum state inside the container for a long time by using the upper and lower cam structure and the same It relates to the used vacuum container.

In general, various kinds of foods such as vegetables and fish are easily oxidized due to contact with other harmful substances such as oxygen or microorganisms contained in the air when they come into contact with the outside air, and decay.

In addition, in the case of fermented food, the fermentation and ripening rate of the food proceeds too fast as the breeding of microorganisms is further activated, resulting in poor preservation.

On the other hand, to delay the fermentation and decay of food is the key to blocking the outside air, and proposed for this is a closed container, that is, a vacuum container.

As such a vacuum container, configurations such as Korean Registered Utility Model Publication No. 280847 (name: vacuum sealing device of the container) and Registered Utility Model Publication No. 200997 (name: vacuum food storage container) have been proposed, There is a lot of risk of loss because the vacuum formation of the weak or the vacuum forming means must always be provided separately.

On the other hand, Japanese Patent Laid-Open No. 11-49243 (name: a food preservation container) has proposed a structure in which a vacuum is generated by opening and closing the first valve and the second valve in a corresponding direction by a vertical sliding action of the cap. .

That is, when the cap is raised, the pump chamber is in a vacuum state and the second valve is closed while the first valve is opened while air is introduced from the inside of the lid to the pump chamber, and when the cap is lowered again, the first valve is closed in reverse to the above. As a result, the second valve opens and the air inside the pump chamber is discharged to the outside. When the lifting operation of the cap is repeated several times, the inside of the lid can be set to a vacuum state by gradually discharging air from the inside of the lid to the outside.

When the cover is combined with the container, the inside of the container can be formed in a vacuum state, and the food can be deteriorated or decayed while the food is stored therein.

However, in the above-described conventional configuration, not only the manual vertical slide action of the cap for vacuum formation is to be performed manually, but also the force for moving the cap upward is particularly increased when the vacuum force inside the cover increases. There are disadvantages.

In addition, since the second valve is provided on the upper surface of the cap during the lifting operation of the cap, a portion that is pressurized during the lowering operation of the cap, which opens the second valve, is inconvenient due to inconvenience or the second valve. There is a problem that interferes with the operation of.

In view of this problem, Korean Laid-Open Patent Publication No. 2004-429069 (name: vacuum container for food preservation) has a mechanism for rapidly forming a vacuum in the interior of the container by a piston action using a spring force. It is proposed a food preservation container that can be easily manipulated and safer food storage by reducing the operation force.

To this end, Korean Patent Laid-Open Publication No. 2004-429069 covers an upper portion of a container member for accommodating food, and forms a sliding groove in the center and a first valve groove in the sliding groove, and an inlet port in the center of the first valve groove. And a lid member formed at an upper end of the sliding groove to prevent the release groove; A first valve member which forms a plurality of vent holes at an outer circumferential edge of the plate surface and is installed in the first valve groove to control the intake port at the center; The lower part is a tubular shape capable of raising and lowering flow of the first valve member, and the upper part is extended upward in a tubular shape having an inner diameter smaller than the vent hole position of the first valve member to form a guide part, and a plurality of vent holes are formed on the upper surface. A valve guide member; A spring member which is stretched in a vertical direction with a lower end mounted on an outside of the guide portion of the valve guide member; A spring member is accommodated inside the tubular shape, and an exhaust port is formed in the center of the second valve groove recessed downward in diameter at the center of the upper surface, and a locking groove is formed at one side of the upper end of the anti-rotation surface. A piston member provided with a sealing means at the locking jaw while forming a locking jaw in the locking jaw; A release preventing member slidingly coupled to the release preventing groove of the sliding groove to prevent the release of the piston member; a second valve member installed in the second valve groove formed on the upper surface of the piston member to control the central exhaust port; ; A vacuum container for food preservation has been proposed, which includes a cap member having a sliding groove formed on an inner circumferential surface thereof, and a locking member coupled to a piston member.

The Korean Laid-Open Patent Publication No. 2004-429069 discloses that the first valve member for controlling the intake port during pumping of the piston does not maintain the set position accurately and flows laterally, thus not reaching a rapid vacuum state. When the piston is stopped, the first valve member and the second valve member do not have a structure that keeps the inlet and the exhaust ports blocked, respectively, and the internal space of the piston does not maintain a sealing state with the outside. If the internal space of the piston does not maintain a constant pressure after the leakage occurs there is a problem that the vacuum in the container is also released slowly. As a result, there is a problem that the shelf life of foods and the like stored in the vacuum container is shortened.

In addition, the conventional vacuum container has a structure in which the inlet port is directly exposed to the inside of the container, and thus, when the powder content is stored in the container, the powder should flow into the inlet port during the pumping operation of the piston and the first valve member should be in close contact. The first valve groove does not have a flat state, which causes leakage.

Moreover, the conventional vacuum vessel does not have a structure capable of suppressing the lateral flow of the piston in which the up and down movement is made along the inside of the cylinder, so that friction with the inner circumference of the release preventing member during the up and down movement of the piston is prevented. While it does not occur smooth up and down sliding operation, as a result it is difficult to reach a rapid vacuum state.

Accordingly, the present invention has been made to solve the above-mentioned problems of the prior art, the object of which is to provide an intake port of the lower valve by a selective cam position coupling between the upper cam formed at the lower part of the piston and the lower cam of the pressure cam rod. The present invention provides a vacuum generating apparatus and a vacuum container using the same, by implementing a complete sealing state by further reinforcing the blocking state.

Another object of the present invention is a vacuum generating device that can effectively set the intake port to the sealing state while maintaining the set position during the up and down movement of the piston according to the lower valve is made of an umbrella shape having an insertion projection inserted into the inlet port and It is to provide a vacuum container using the same.

Still another object of the present invention is to provide a vacuum generating device having a lower cover that covers an inlet port at a lower part of a cylinder to prevent powder contents from being easily sucked into the inlet port, thereby minimizing malfunction of the valve. .

It is another object of the present invention to provide a vacuum generator that guides the piston to a faster vacuum state by providing a piston guide inside the cylinder, which enables stable up and down movement of the piston.

Still another object of the present invention is to provide a vacuum container that can maintain a vacuum state inside the container for a long time, thereby enabling safer food storage.

In order to achieve the above object, according to an aspect of the present invention, the present invention covers a top of the container body having a receiving space, the container cap formed with a through hole in the center; A circular shape having a cylindrical shape having a circular inner circumferential surface open upward, the outer circumference portion is fixedly coupled to the inner circumference of the container cap, and has an inlet for communicating with the container body in the center and a lower valve groove around the intake portion. A cylinder in which protrusions are formed; A piston having a tubular shape which is open downward and having an exhaust port in the center of the upper surface and forming an upper valve groove around the exhaust port, and extending from the lower side of the upper surface to surround the exhaust port and having at least two upper cams at the lower end thereof; An upper cap coupled to an upper portion of the piston through a plurality of coupling protrusions surrounding the upper valve groove; An upper valve movably coupled to the upper valve groove to open and close an exhaust port as the piston descends and rises; A lower valve movably coupled to the lower valve groove to open and close an intake port according to the rising and falling of the piston; A pressure valve cover having a first cylindrical portion having a lower outer circumference coupled to the circular protrusion around the intake portion and a second cylindrical portion having a smaller diameter than the first cylindrical portion; An elastic member that provides an upward restoring force when the piston is lowered; And at least two lower cams having a lower end portion pressurized on an uppermost portion of the lower valve, an outer circumferential portion coupled to a second cylinder portion of the pressure valve cover, and an upper portion selectively engaged with the upper cam when the piston descends. It provides a vacuum generating device for a vacuum container, comprising a rod.

According to another aspect of the invention, the present invention covers a top of the container body having a receiving space, the container cap formed with a through hole in the center; A circular shape having a cylindrical shape having a circular inner circumferential surface open upward, the outer circumference portion is fixedly coupled to the inner circumference of the container cap, and has an inlet for communicating with the container body in the center and a lower valve groove around the intake portion. A cylinder in which protrusions are formed; A piston guide having a lower outer circumference coupled to the lower inner circumference of the cylinder and having at least one pair of vertical coupling grooves formed on an outer circumferential surface thereof; At least one pair of engaging projections coupled to the at least one pair of vertical coupling grooves on the inner periphery of the lower end in a tubular shape which opens downward, and forms an upper valve groove around the exhaust port and the exhaust port in the center of the upper surface, and from the lower side of the upper surface. A piston extending around the exhaust port and having at least two upper cams at a lower end thereof; An elastic member that provides an upward restoring force when the piston is lowered; An upper cap coupled to an upper portion of the piston through a plurality of coupling protrusions surrounding the upper valve groove; An upper valve movably coupled to the upper valve groove to open and close an exhaust port as the piston descends and rises; A lower valve movably coupled to the lower valve groove to open and close an intake port according to the rising and falling of the piston; A pressure valve cover having a first cylindrical portion having a lower outer circumference coupled to the circular protrusion around the intake portion and a second cylindrical portion having a smaller diameter than the first cylindrical portion; And at least two lower cams having a lower end portion pressurized on an uppermost portion of the lower valve, an outer circumferential portion coupled to a second cylinder portion of the pressure valve cover, and an upper portion selectively engaged with the upper cam when the piston descends. It provides a vacuum generating device for a vacuum container, comprising a rod.

The piston is locked by rotating the piston around the piston guide, and the locking of the piston is performed by lowering the piston along the vertical coupling groove of the piston guide to the bottom of the piston guide along the horizontal coupling groove of the piston guide. It is preferable that the coupling protrusions are coupled to each other, and when the piston is locked, the lower cam and the upper cam are preferably combined with the protrusion of the lower cam so as to press the lower valve to maximize the coupling length.

In addition, the upper valve and the lower valve is preferably made of an umbrella connected to the conical inclined portion to the support portion inserted into the exhaust port and the inlet port, respectively.

Furthermore, the piston guide has an outer cylindrical portion having a lower outer peripheral portion coupled to and fixed to a lower inner peripheral portion of the cylinder and having at least one pair of vertical coupling grooves formed on an outer circumferential surface thereof, and extending inward from the outer cylindrical portion to form a second cylinder of the pressure valve cover. It includes an inner cylindrical portion is inserted and supported, the lower end of the elastic member is preferably coupled to the outer circumference of the inner cylindrical portion.

In this case, the elastic member is made of a reverse cone shape, the lower end is preferably coupled to the outer circumference of the piston guide inner cylinder portion and the upper end is coupled to the lower portion of the upper surface of the piston.

In addition, the upper side of the pressure cap rod is provided with a plurality of engaging projections on the outer circumference, the plurality of coupling projections may be slidingly coupled to a plurality of coupling grooves formed in the inner circumferential portion of the second cylinder portion of the pressure valve cover.

Further comprising a lower cover surrounding the lower side of the cylinder, it is preferable to block the intake portion of the cylinder exposed to the container body.

According to another aspect of the invention, the present invention provides a container body having a receiving space; A container cap covering an upper portion of the container body and having a through hole formed at a center thereof; A circular shape having a cylindrical shape having a circular inner circumferential surface open upward, the outer circumference portion is fixedly coupled to the inner circumference of the container cap, and has an inlet for communicating with the container body in the center and a lower valve groove around the intake portion. A cylinder in which protrusions are formed; A piston having a lower end of the outer circumference coupled to the lower end of the inner circumference of the cylinder and having at least one pair of vertical engagement recesses formed corresponding to the outer circumference and at least one pair of horizontal engagement recesses formed along the circumferential surface from the bottom of the at least one pair of vertical engagement recesses. guide; At least one pair of engaging projections coupled to the at least one pair of vertical coupling grooves on the inner periphery of the lower end in a tubular shape which opens downward, and forms an upper valve groove around the exhaust port and the exhaust port in the center of the upper surface, and from the lower side of the upper surface. A piston extending around the exhaust port and having at least two upper cams at a lower end thereof; An elastic member that provides an upward restoring force when the piston is lowered; An upper cap coupled to an upper portion of the piston through a plurality of coupling protrusions surrounding the upper valve groove; An upper valve movably coupled to the upper valve groove to open and close an exhaust port as the piston descends and rises; A lower valve movably coupled to the lower valve groove to open and close an intake port according to the rising and falling of the piston; A pressure valve cover having a first cylindrical portion having a lower outer circumference coupled to the circular protrusion around the intake portion and a second cylindrical portion having a smaller diameter than the first cylindrical portion; And at least two lower cams having a lower end portion pressurized on an uppermost portion of the lower valve, an outer circumferential portion coupled to a second cylinder portion of the pressure valve cover, and an upper portion selectively engaged with the upper cam when the piston descends. And a rod, wherein the piston has at least one pair of engaging protrusions formed at an inner circumference thereof and is coupled to at least one pair of vertical coupling recesses to slide along the at least one pair of vertical coupling recesses at the time of raising and lowering, the locking at least Provided is a vacuum container, characterized in that the pair of engaging projections are rotated along at least one pair of horizontal coupling recesses.

In this case, each of the upper valve and the lower valve has an umbrella shape in which a conical inclined portion is connected to the support portion inserted into the exhaust port and the inlet port through the inclined connection surface, and when the piston is set to the locked state, the inclined connection surface is connected to the inlet port. It is desirable to block.

In addition, the forming angle between the support portion and the inclined connection surface of the upper valve and the lower valve may be set in the range of 100 to 130 degrees.

As described above, the present invention implements a complete sealing state by further reinforcing the blocking state of the inlet port of the lower valve by the selective cam position coupling between the upper cam formed in the lower portion of the piston and the lower cam of the pressure cam rod. The vacuum inside the container can be maintained for a long time, and as a result, the vacuum inside the container can be maintained for a long time, thereby enabling safer food storage.

In addition, according to the present invention, as the lower valve is formed in an umbrella shape having an insertion protrusion inserted into the inlet port, it is possible to effectively set the inlet port to a sealing state while maintaining the set position during the up and down movement of the piston.

Furthermore, in the present invention, the lower cover of the inlet port is provided at the bottom of the cylinder to prevent the powder contents from being easily sucked into the inlet port, thereby minimizing the malfunction of the valve.

In addition, in the present invention, by providing a piston guide inside the cylinder, a stable upward and downward movement of the piston can be made, leading to a faster vacuum.

1 is a perspective view of a container cap having a vacuum generating apparatus according to a preferred embodiment of the present invention,
2 is a cross-sectional view showing the locked state after the pumping is completed in the vacuum generator as an application example applied to the vacuum vessel in the cross-sectional view AA line of FIG.
3 is a cross-sectional view of a vacuum generator according to a preferred embodiment of the present invention;
4 is a cross-sectional view showing a state in which the piston is pressed in the vacuum generating device of FIG.
5 is an exploded view of the vacuum generating device of FIG.
6 and 7 are a plan view and a bottom view of the cylinder of FIG. 5, respectively;
8, 9 and 10 are a plan view, a bottom view and a right side view of the piston guide of FIG. 5, respectively;
11 and 12 are a plan view and a bottom view of the piston of FIG. 5, respectively;
13 and 14 are a plan view and a bottom view of the pressure cam rod of Figure 5, respectively,
15 and 16 are a plan view and a bottom view of the pressure valve cover of Figure 5, respectively,
17 and 18 are cross-sectional views showing a state before assembly of the pressure cam rod and the pressure valve cover of FIG.
19 is a sectional view of a lower valve (upper valve).

Hereinafter, with reference to the accompanying drawings will be described in detail a vacuum generating apparatus and a vacuum container using the same according to a preferred embodiment of the present invention.

First of all, the present invention can be applied to a vacuum container for setting various kinds of foods such as vegetables and fish, various seeds, etc. in a vacuum state by blocking the air flow from the outside, and can be applied regardless of the shape and size of the container. Do.

In the following description of the embodiments with reference to the drawings, the present invention will be described by way of example in which the vacuum generating device is applied to a container cap coupled to a rectangular box-shaped container.

1 is a perspective view of a container cap having a vacuum generating apparatus according to a preferred embodiment of the present invention, Figure 2 is a cross-sectional view of the line AA of Figure 1 applied to the vacuum container, after the pumping is completed in the vacuum generating apparatus 3 is a cross-sectional view showing a locked state, FIG. 3 is a cross-sectional view of a vacuum generator according to a preferred embodiment of the present invention, FIG. 4 is a cross-sectional view showing a pressurized state in the vacuum generator of FIG. 3, FIG. An exploded view of a vacuum generator.

1 to 5, the vacuum container 1 according to the preferred embodiment of the present invention has a container main body 3 having a receiving space thereinto accommodate food therein and a lower end of the container main body 3. Container cap 10 is coupled to the upper end.

As long as the container main body 3 has an accommodation space for accommodating food therein, any one such as a cylinder and a square cylinder can be applied.

The container cap 10 has a circular through hole 11 in a central portion thereof, and a circular protrusion 12 extends in a lower portion of an upper surface thereof, and an upper end portion of a cylinder 50 to be described below is coupled to a side inner peripheral portion. The groove 13 to which the upper outer periphery of the cylinder 50 is coupled is formed.

The vacuum generator 5 according to the present invention is coupled to the container cap 10 to form the inside of the container body 3 in a vacuum state, the upper cap 20, the piston 30, the piston guide 40 ), A cylinder 50, a pressure cam rod 60, a pressure valve cover 70, a lower cover 80, an upper valve 91, a lower valve 93, and a spring 19.

First, as shown in FIGS. 6 and 7, the cylinder 50 has a cylindrical portion 51 and a cylindrical portion 51 having a cylindrical structure in which the piston 30 can slide upward and downward on an inner circumference thereof. Interconnected through a plurality of radial reinforcement frames 58, and comprising a flange 52 of approximately quadrangular shape.

The flange 52 of the cylinder 50 is coupled to the groove 13 of the container cap 10 in a snap manner so that the vacuum generator 5 is mounted to the container cap 10. However, the coupling between the flange 52 of the cylinder 50 and the container cap 10 is of course also possible to be pressed by sliding rotation in addition to the snap method described above.

In addition, the lower end surface 53 of the cylindrical portion 51 is formed with a lower valve groove 56 protruding in the center to accommodate the lower valve 91, the lower valve groove 56 of the The inlet port 57 is formed through the center.

A pair of engaging projections 54a and 54b are formed on the inner circumference of the cylindrical portion 51, and the same line position as the pair of the engaging projections 54a and 54b also on the inner circumference of the circular projection 55. A pair of engaging projections 55a and 55b respectively protrude in the axial direction. In this case, the pair of coupling protrusions 54a and 54b and the pair of coupling protrusions 55a and 55b are coupling grooves of the coupling grooves 45a and 45b of the piston guide 40 coupled thereto and the pressure valve cover 70. It is preferable to form different sizes in consideration of the orientation according to the sizes of the 7676 and 76b.

As shown in FIGS. 8 to 10, the piston guide 40 has coupling grooves 45a and 45b formed in the flange 48 at the lower end thereof with a pair of coupling protrusions 54a and 54b of the cylinder 50. Combined and fixed.

In addition, the piston guide 40 has a pair of vertical coupling grooves 46a and 46b formed on the outer circumferential surface thereof so that the pair of coupling protrusions 39a and 39b of the piston 30 to be described later engage with the outer cylindrical portion 41. And an inner cylindrical portion extending along the axial direction so as to form a predetermined through hole 44 at the inner end after the extending portion 42 extends in the center direction in the middle of the inner circumferential portion of the outer cylindrical portion 41. 43). As the upper side of the pressure valve cover 70 is inserted into the inner cylindrical portion 43, the flow of the pressure valve cover 70 is suppressed.

In addition, a pair of horizontal engagement grooves 47a and 47b are formed in the outer cylindrical portion 41 of the piston guide 40 in one direction from the lower ends of the pair of vertical engagement grooves 46a and 46b, respectively, along the outer circumference. The pair of horizontal coupling grooves 47a and 47b is lowered after the piston 30, and when the piston 30 is rotated with respect to the piston guide 40, the pair of coupling protrusions 39a and 39b of the piston 30 are coupled to the piston ( 30) is used to set the locked state.

11 and 12, the piston 30 is made of a generally inverted cup shape, the inner periphery of the lower end is coupled to the pair of horizontal coupling grooves (47a, 47b) of the piston guide 40 A pair of coupling protrusions 39a and 39b protrude, and a pair of annular protrusions 32 and 33 are formed at intervals on the outer peripheral portion of the lower end to seal the grooves formed in the groove formed between the pair of annular protrusions 32 and 33. -Ring 17 is engaged.

In addition, the upper end of the piston 30 is formed through the exhaust port 36 in the center of the upper surface extending in the center direction, the inner cylinder portion 31 surrounding the exhaust port 36 is protruded to the inside thereof An upper valve groove 35 on which the upper valve 91 is seated is formed, and a plurality of, for example, eight coupling recesses 38 are formed on the outer side of the inner cylindrical portion 31.

The lower side of the upper surface of the piston 30 extends in a cylindrical shape along a periphery of the exhaust port 36 by a predetermined length, and then the protrusions 37a, the inclined portions 37b and the recesses 37c at the lower ends of the extension portions, respectively. Is connected along the circumference is repeated a plurality of upper cam 37 is protruded. In the illustrated embodiment, three upper cams 37 are formed, but for example, two or four cam structures may be provided.

The upper surface of the piston 30 is coupled to the upper cap 20 of the disc shape, the upper cap 20 is formed on the lower side, for example, a plurality of coupling protrusions 21, the piston 30 is formed Coupling is made with a plurality, for example, eight coupling grooves 38 formed on the upper surface of the.

On the other hand, the upper valve 91 is seated in the upper valve groove 35 of the piston 30, the flow in the up / down direction to open and close the exhaust port 36 in accordance with the up and down movement of the piston 30 The upper valve 91 has the same structure as the lower valve 93 seated in the lower valve groove 56.

Since the upper and lower valves 91 and 93 have the same shape, the lower valve 93 will be described with reference to FIG. 19. As shown in FIG. 19, the lower valve 93 has a support portion 93a having a hollow portion in the lower center of the conical inclined portion 93b so as to form an umbrella shape, and has a conical inclined portion 93b. Between the support parts 93a, a planar inclined connection surface 93c is connected. In addition, the inclined connection surface 93c may of course connect the conical inclined portion 93b and the support portion 93a in a curved shape. The support portion 93a is formed with a circular groove 93d open downward in the center portion.

In the illustrated embodiment, the structure in which the inclined connecting surface 93c is connected between the conical inclined portion 93b and the support portion 93a is illustrated, but is not essential and the conical inclined portion 93b without the inclined connecting surface 93c is illustrated. It is also possible that the support portion (93a) is connected to the lower center of the.

The support portion 93a of the lower valve 93 is inserted into and supported by the inlet port 57 of the cylinder 50, and only the outer circumferential portion 93b is seated in the lower valve groove 56. In this case, the inclined connection surface 93c serves to block the inlet port 57 when the lower valve 93 is lowered by the pressure inside the piston 30 or the pressurization of the pressurizing cam rod 60.

The upper and lower valves 91 and 93 are preferably made of a soft material such as synthetic rubber such as silicone so as to be flexible as a whole as well as the outer periphery of the conical inclined portion 93b.

The formation angle α formed between the support portion 93a and the inclined connection surface 93c of the lower valve 93 is preferably set in the range of 100 to 130 degrees. When the forming angle α is less than 100 degrees, the sealing of the intake port 57 is not effectively performed. When the formation angle α is greater than 130 degrees, the phenomenon of being inserted into the intake port 57 at the time of exhaust and not exiting at the intake time May occur.

As shown in FIGS. 15 to 18, the pressure valve cover 70 is connected to a first cylindrical portion 71 and a second cylindrical portion 72 having an inner diameter smaller than that of the first cylindrical portion 71. Coupling grooves 76a and 76b are formed at a lower end of the first cylindrical portion 71 so as to be coupled to and fixed to the pair of coupling protrusions 55a and 55b of the cylinder 50, and the second cylindrical portion 72 is formed. In the inner circumferential portion 75 of the plurality of, for example, four longitudinal grooves, that is, the channels 74a-74d are formed so that the vertical projections 64a-64d formed on the outer circumferential portion of the pressure cam rod 60 are slidable. To be combined.

In this case, the width of any one of the channels (74a-74d) and the width of the vertical projection coupled to it can be formed relatively larger in consideration of the coupling direction.

In addition, the pressure valve cover 70 is provided with a plurality of air distribution holes 73a-73d in the stepped portion between the first and second cylindrical portions 71, 72.

The pressurizing cam rod 60 coupled to the inner circumferential portion 75 of the second cylindrical portion 72 of the pressurizing valve cover 70 has vertical projections 64a-64d formed at the outer circumference thereof, and protrudes at the upper end portions, respectively. The first cylindrical portion 62 in which a plurality of, for example, three lower cams 63 protrude from the 63a, the inclined portion 63b, and the recess 63c are connected to each other along a circumference and are repeated, and the inner diameter thereof. The second cylindrical portion 61 smaller than the first cylindrical portion 62 is connected to the lower side.

The three lower cams 63 of the pressurizing cam rod 60 have the same structure as the upper cams 37, and the protrusions 63a of the lower cams 63 when the pumping operation of the piston 30 is made to each other. ) Corresponds to the recess 37c of the upper cam 37, the inclined portion 63b of the lower cam 63 corresponds to the inclined portion 37b of the upper cam 37, The recess 63c is in contact with the protrusion 37a of the upper cam 37.

The lower end of the second cylindrical portion 61 of the pressurizing cam rod 60 is inclined inwardly so as to accommodate the uppermost conical shape of the lower valve 93.

Between the outer circumferential portion of the inner cylindrical portion 43 of the piston guide 40 and the downward projection of the piston 30, an inverted conical spring 19 is provided which provides an elastic restoring force for the piston 30.

The non-explained member 7 shown in FIG. 6 represents a vacuum release valve for releasing a vacuum state inside the container body 3.

Hereinafter will be described in more detail with respect to the operation of the present invention according to the configuration of the embodiment.

The vacuum generator 5 according to the present invention is made as shown in FIG. 3 when the components shown in FIG. 5 are assembled to each other, and when assembled to the upper portion of the container body 3, the vacuum container 1 as shown in FIG. Is obtained. 2 shows a state in which the pressurized cam rod 60 presses the lower valve 93 by the locking after the pumping is completed, and thus the lower valve 93 is compressed to the inlet port 57 after the pumping is completed.

In this state, when the piston 30 is pressurized and pumped up and down, the air inside the container is discharged to the outside of the container.

In more detail, after receiving a certain amount of food in the interior of the container body (3), when the assembly of Figure 3 and the piston 30 is pressed by the palm of the palm 30 as shown in Figure 4 the piston 30 is a spring ( 19) The descent is made while compressing.

At this time, the upper cam 37 located on the lower surface of the piston 30 presses the lower valve 93 while being in contact with the lower cam 63 of the pressurizing cam rod 60. The portion 93b is in close contact with the lower valve groove 56 while only the outer circumferential portion is made to block the intake port 57 to a slight extent. Subsequently, the inclined connection surface 93c of the lower valve 93 blocks the intake port 57 as the piston 30 further descends, so that the strong intake port 57 is blocked.

In this case, the contact between the upper cam 37 and the lower cam 63 is such that the protrusion 63a of the lower cam 63 corresponds to the recess 37c of the upper cam 37, and the lower cam 63 is inclined. The portion 63b corresponds to the inclined portion 37b of the upper cam 37, and the recess 63c of the lower cam 63 is in contact with the protrusion 37a of the upper cam 37. .

In addition, in the present invention, when the piston 30 is lowered, a pair of vertical couplings in the vertical direction in which the pair of engaging projections 39a and 39b of the piston 30 are formed on the outer cylindrical portion 41 of the piston guide 40. As the guide is made along the grooves 46a and 46b, the lowering is performed without the left / right flow, and furthermore, the upper end of the piston 30 is guided to the inner circumference of the container cap 10 so that the lowering is made, thereby making stable operation. You lose.

A sealing O-ring 17 is inserted between the pair of annular projections 32 and 33 on the outer surface of the piston 30 so that the cylinder of the piston 30 and the cylinder 50 when the piston 30 is lowered. The sealing state is maintained between the parts 51.

In addition, the upper side of the pressure valve cover 70 is inserted into the inner cylindrical portion 43 of the piston guide 40, the lower end of the reverse cone spring (19) is disposed on the outer periphery of the inner cylindrical portion 43, Since the structure which suppresses the lateral flow of the cylindrical part 43 is employ | adopted, the flow of the pressurization valve cover 70 is suppressed. As a result, even if the upper cam 37 is pressed against the lower cam 63 of the pressure cam rod 60 coupled to the pressure valve cover 70, the flow of the lower cam 63 is suppressed while the upper cam 37 is removed from the upper cam 37. Transmission of the pressing force to the lower cam 63 can be made effectively, and the lower valve 93 is also made to block the stable inlet port 57.

On the other hand, when the lower valve 93 blocks the inlet port 57, the inside of the piston 30 is pressurized as the piston 30 descends, and the upper valve 91 is maximized from the exhaust port 36 by this pressure. In addition, the conical inclined portion of the upper valve 91 is easily leaked by pressurized air as the outer circumference thereof is flexible, and the air inside the piston 30 is forcedly discharged to the outside through the exhaust port 36. do.

Subsequently, when the pressure holding the piston 30 is removed, the piston 30 is automatically raised by the elastic repulsive force of the spring 19. At this time, the lower valve 93 and the upper valve 91 acts as opposed to when the piston 30 is raised.

That is, as shown in FIG. 3, when the piston 30 is raised by the elastic force of the spring 19, an instantaneous negative pressure is generated inside the piston 30 while the volume of the inner space of the piston 30 increases. The valve 91 shuts off the exhaust port 36. When the piston 30 rises in such a state, the inside of the piston 30 is set to a larger negative pressure state while raising the lower valve 93 by this negative pressure to draw the air inside the container body 3 through the inlet port 57. Aspirated.

As the piston 30 rises, the internal air of the container body 3 passes through the inlet port 57, and then passes through the plurality of air distribution holes 73a-73d of the pressure valve cover 70 to form the piston 30. Flows inside. The raising of the piston 30 takes place until the annular projection 32 on the outer side of the piston 30 reaches the bottom of the vessel cap 10 and is blocked.

As described above, the present invention sucks air from the inside of the container body 3 into the piston 30 by causing the piston 30 to move up and down by removing the pressure to press or press the piston 30, and again. The interior of the container body 3 is brought into a vacuum state by the repetition of the operation to be discharged to the outside.

In other words, by forcibly discharging air from the inside of the container main body 3 to the state of low pressure, it is possible to maintain the original state of the food stored in the inside for a longer time, thereby further limiting the shelf life of the food Extend.

Meanwhile, in the present invention, after the inside of the container body 3 is formed in a vacuum state, the coupling recess 45a is coupled to the pair of engaging projections 54a and 54b of the cylinder 50 in a state where the piston 30 is lowered as much as possible. 45b is coupled to rotate the piston guide 40 having a fixed position in the pivoting direction of the piston 30 in the right direction, and is coupled to the pair of vertical coupling grooves 46a and 46b of the piston guide 40. Locking state as shown in FIG. 2 while the pair of engaging projections 39a and 39b of the piston 30 move to the end along the pair of horizontal engagement grooves 47a and 47b of the piston guide 40 (suppression of the piston Status).

In this case, when the piston 30 is rotated in the right-hand direction by rotating the piston guide 40 in the pivot axis, the upper cam 37 formed below the piston 30 and the lower cam 63 of the pressure cam rod 60 are rotated. The cam engagement position is changed in between. That is, the protruding portion 37a of the upper cam 37 that has been coupled with the recess 63c of the lower cam 63 passes through the inclined portion 63b of the lower cam 63 and protrudes 63a of the lower cam 63. To reach a state of coupling.

That is, as shown in the enlarged view of FIG. 2, when the protrusion 37a of the upper cam 37 is engaged with the protrusion 63a of the lower cam 63, the upper cam 37 and the lower cam ( The second of the pressurizing cam rod 60 having the lower cam 63 while the length between the 63 is longer than the depth h between the protrusions 37a and 63a and the recesses 37c and 63c. The cylindrical portion 61 further pressurizes the lower valve 93 so that the lower valve 93 is pressed, so that the inclined connection surface 93c blocks the upper end of the inlet port 57.

As a result, in the present invention, by further reinforcing the blocking state of the inlet port 57 of the lower valve 93, a complete sealing state for the inside of the container can be realized to maintain a vacuum state inside the container for a long time.

After that, when the food stored in the container body 3 is to be taken out for a predetermined period of time, the vacuum is released by operating the vacuum release valve 7 to release the vacuum into the container body 3, The container cap 10 can be easily separated from the container body 3.

In addition, in the present invention, the cup-shaped lower cover 80 that covers the lower protrusion of the cylinder 50 as a whole is coupled to cover the intake port 57 disposed below the cylinder 50. As a result, the internal air sucked into the intake port 57 is sucked through the two-stage bent flow path between the lower cover 80 and the cylinder 50, thereby preventing the contents of the powder form from being easily sucked into the intake port 57. Thereby, the malfunction of the lower valve 93 can be minimized.

In the above description of the embodiment, the container cap 10 and the cylinder 50 have been proposed to be separately manufactured after assembling and fabricating them for ease of mold design, but may be manufactured in one piece as necessary.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the embodiments set forth herein. Various changes and modifications may be made by those skilled in the art.

The present invention relates to a vacuum generating apparatus, and can be applied to a vacuum container capable of maintaining a long shelf life of fresh food, fruit, aquatic products and the like.

1: vacuum container 3: container body
5: vacuum generator 7: vacuum release valve
10: container cap 11: through hole
12: round projection 13: groove
17: O-ring 19: spring
20: upper cap 30: piston
31: inner cylindrical portion 32, 33: annular projection
35: upper valve groove 36: exhaust port
37: upper cam 37a, 63a: projection
37b, 63b: inclined portion 37c, 63c: groove portion
40: piston guide 41: outer cylindrical portion
42: extension part 43: inner cylindrical part
46a, 46b: vertical coupling groove 50: cylinder
51: cylindrical portion 52: flange
53: lower surface 56: lower valve groove
57: intake port 58: reinforcement frame
60: pressurized cam rod 61, 71: first cylindrical portion
62, 72: second cylindrical portion 63: lower cam
64a-64d, 74a-74d: Vertical protrusion 70: Pressure valve cover
73a-73d: hole 75: inner circumference
80: lower cover 91: upper valve
93: lower valve 93a: support portion
93b: conical slope 93c: sloped connection surface
21, 39a, 39b, 54a, 54b, 55a, 55b: engaging protrusion
38,45a, 45b, 76a, 76b: engaging groove

Claims (12)

A container cap covering an upper portion of the container body having a receiving space and having a through hole formed in the center thereof;
A circular shape having a cylindrical shape having a circular inner circumferential surface open upward, the outer circumference portion is fixedly coupled to the inner circumference of the container cap, and has an inlet for communicating with the container body in the center and a lower valve groove around the intake portion. A cylinder in which protrusions are formed;
A piston having a tubular shape which is open downward and having an exhaust port in the center of the upper surface and forming an upper valve groove around the exhaust port, and extending from the lower side of the upper surface to surround the exhaust port and having at least two upper cams at the lower end thereof;
An upper cap coupled to an upper portion of the piston through a plurality of coupling protrusions surrounding the upper valve groove;
An upper valve movably coupled to the upper valve groove to open and close an exhaust port as the piston descends and rises;
A lower valve movably coupled to the lower valve groove to open and close an intake port according to the rising and falling of the piston;
A pressure valve cover having a first cylindrical portion having a lower outer circumference coupled to the circular protrusion around the intake portion and a second cylindrical portion having a smaller diameter than the first cylindrical portion;
An elastic member that provides an upward restoring force when the piston is lowered; And
A pressurized cap rod having at least two lower cams having a lower end pressurized on an uppermost portion of the lower valve, an outer circumferential portion coupled to a second cylinder portion of a pressurized valve cover, and an upper cam selectively engaged with an upper cam when the piston descends. Vacuum generating device for a vacuum container comprising a. A container cap covering an upper portion of the container body having a receiving space and having a through hole formed in the center thereof;
A circular shape having a cylindrical shape having a circular inner circumferential surface open upward, the outer circumference portion is fixedly coupled to the inner circumference of the container cap, and has an inlet for communicating with the container body in the center and a lower valve groove around the intake portion. A cylinder in which protrusions are formed;
A piston guide having a lower outer circumference coupled to the lower inner circumference of the cylinder and having at least one pair of vertical coupling grooves formed on an outer circumferential surface thereof;
At least one pair of engaging projections coupled to the at least one pair of vertical coupling grooves on the inner periphery of the lower end in a tubular shape which opens downward, and forms an upper valve groove around the exhaust port and the exhaust port in the center of the upper surface, and from the lower side of the upper surface. A piston extending around the exhaust port and having at least two upper cams at a lower end thereof;
An elastic member that provides an upward restoring force when the piston is lowered;
An upper cap coupled to an upper portion of the piston through a plurality of coupling protrusions surrounding the upper valve groove;
An upper valve movably coupled to the upper valve groove to open and close an exhaust port as the piston descends and rises;
A lower valve movably coupled to the lower valve groove to open and close an intake port according to the rising and falling of the piston;
A pressure valve cover having a first cylindrical portion having a lower outer circumference coupled to the circular protrusion around the intake portion and a second cylindrical portion having a smaller diameter than the first cylindrical portion; And
A pressurized cap rod having at least two lower cams having a lower end pressurized on an uppermost portion of the lower valve, an outer circumferential portion coupled to a second cylinder portion of a pressurized valve cover, and an upper cam selectively engaged with an upper cam when the piston descends. Vacuum generating device for a vacuum container comprising a. The vacuum generating device for a vacuum container according to claim 2, wherein the piston is locked by rotating the piston about the piston guide. The method of claim 2 or 3, wherein the locking of the piston is made when the engaging projection of the piston is coupled along the horizontal coupling groove of the piston guide in a state where the piston is lowered along the vertical coupling groove of the piston guide to the bottom. ,
When the piston is locked, the lower cam and the upper cam is a vacuum generating device for a vacuum container, characterized in that the protrusion of the upper cam is coupled with the protrusion of the lower cam so as to maximize the coupling length to press the lower valve. The vacuum generating apparatus of claim 1 or 2, wherein the upper valve and the lower valve are formed in an umbrella shape in which a conical inclined portion is connected to a support portion inserted into an exhaust port and an intake port, respectively. The method of claim 2, wherein the piston guide
An outer cylindrical part having a lower end of the outer circumference coupled to the lower end of the inner circumference of the cylinder and having at least one pair of vertical coupling grooves formed on an outer circumferential surface thereof;
An inner cylinder portion extending inward from the outer cylinder portion to support the second cylinder portion of the pressure valve cover;
The lower end of the elastic member is a vacuum generating device for a vacuum container, characterized in that coupled to the outer circumference of the inner cylindrical portion. The vacuum generating apparatus of claim 6, wherein the elastic member is formed in an inverted cone shape, the lower end of which is coupled to the outer circumference of the piston guide inner cylinder, and the upper end of which is coupled to the lower part of the upper surface of the piston. According to claim 1 or claim 2, wherein the upper side of the pressure cap rod is provided with a plurality of engaging projections on the outer peripheral portion, the plurality of engaging projections in the plurality of coupling grooves formed in the inner peripheral portion of the second cylindrical portion of the pressure valve cover Vacuum generating device for a vacuum container, characterized in that the sliding coupling. The vacuum generating apparatus for a vacuum container according to claim 1 or 2, further comprising a lower cover surrounding the lower side of the cylinder to block the intake portion of the cylinder from being exposed to the container body. A container body having a receiving space;
A container cap covering an upper portion of the container body and having a through hole formed at a center thereof;
A circular shape having a cylindrical shape having a circular inner circumferential surface open upward, the outer circumference portion is fixedly coupled to the inner circumference of the container cap, and has an inlet for communicating with the container body in the center and a lower valve groove around the intake portion. A cylinder in which protrusions are formed;
A piston having a lower end of the outer circumference coupled to the lower end of the inner circumference of the cylinder and having at least one pair of vertical engagement recesses formed corresponding to the outer circumference and at least one pair of horizontal engagement recesses formed along the circumferential surface from the bottom of the at least one pair of vertical engagement recesses. guide;
At least one pair of engaging projections coupled to the at least one pair of vertical coupling grooves on the inner periphery of the lower end in a tubular shape which opens downward, and forms an upper valve groove around the exhaust port and the exhaust port in the center of the upper surface, and from the lower side of the upper surface. A piston extending around the exhaust port and having at least two upper cams at a lower end thereof;
An elastic member that provides an upward restoring force when the piston is lowered;
An upper cap coupled to an upper portion of the piston through a plurality of coupling protrusions surrounding the upper valve groove;
An upper valve movably coupled to the upper valve groove to open and close an exhaust port as the piston descends and rises;
A lower valve movably coupled to the lower valve groove to open and close an intake port according to the rising and falling of the piston;
A pressure valve cover having a first cylindrical portion having a lower outer circumference coupled to the circular protrusion around the intake portion and a second cylindrical portion having a smaller diameter than the first cylindrical portion; And
A pressurized cap rod having at least two lower cams having a lower end pressurized on an uppermost portion of the lower valve, an outer circumferential portion coupled to a second cylinder portion of a pressurized valve cover, and an upper cam selectively engaged with an upper cam when the piston descends. Including;
The piston has at least one pair of engaging projections formed in the inner circumference thereof is coupled to at least one pair of vertical coupling recesses to slide up and down along at least one pair of vertical coupling recesses, and the at least one pair of engaging projections when locked A vacuum vessel, characterized in that rotated along at least one pair of horizontal engagement grooves. The method of claim 10, wherein the upper valve and the lower valve is made of an umbrella shape connected to the support portion is inserted into the exhaust port and the inlet port through the inclined connection surface, respectively,
And the inclined connection surface blocks the inlet port when the piston is set to the locked state. 12. The vacuum container according to claim 11, wherein the forming angle between the support portion of the upper valve and the lower valve and the inclined connection surface is set in a range of 100 to 130 degrees.

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