KR200389425Y1 - Vacuum packing apparatus with nozzle-housing - Google Patents

Abstract

The present invention relates to a vacuum packaging machine, and relates to a vacuum packaging machine equipped with a nozzle housing that can be easily vacuumed even if a liquid or solid is present inside the vacuum packaging by mounting the nozzle housing.

Description

Vacuum Packaging Machine with Nozzle Housing {VACUUM PACKING APPARATUS WITH NOZZLE-HOUSING}

The present invention relates to a vacuum packaging machine, and relates to a vacuum packaging machine equipped with a nozzle housing that can be easily vacuumed even if a liquid or solid is present inside the vacuum packaging by mounting the nozzle housing.

In general, the vacuum packaging machine forms a vacuum packaging paper containing food and the like in a vacuum state and heat seals it, and is used to vacuum food and the like.

Vacuum packaging machine is generally configured by hinged base member and the cover member, the vacuum packaging is placed between the base member and the cover member and then the cover member is closed to take the vacuum packaging method.

Vacuum packaging machines can be divided into chamber type and nozzle type according to the vacuum packaging method.

The conventional chamber vacuum packaging machine shown in Figure 1 is known through Patent Publication No. 1996-0013082, etc., after the opening of the vacuum packaging paper 21 is placed in the chamber 34, using a vacuum pump, etc. By sucking the air inside the chamber, the inside of the vacuum packaging paper is vacuumed.

When the vacuum packaging is completed using a vacuum pump or the like, the opening of the vacuum packaging paper is heat-sealed and sealed by a heating unit 51 positioned in front of the cover member 33 and the base member 32 to complete the packaging. Is described in detail through the Utility Model Registration No. 20-0319700.

In the case of using the chamber type vacuum packaging machine as described above, in order to smoothly escape the air inside the vacuum packaging paper, the vacuum packaging paper having the embossing formed as shown in FIG. 2 should be used.

By the way, since the vacuum packaging paper with embossing is relatively expensive compared to the vacuum packaging paper without embossing, in order to vacuum the general packaging paper without embossing, a nozzle type vacuum packaging machine such as Registration Utility Model No. 20-0322449, etc. Was invented.

Nozzle type vacuum packaging machine is a suction nozzle is inserted through the opening of the vacuum packaging paper to make the inside of the vacuum packaging paper, which was disclosed through the registered Utility Model No. 20-0365095, etc. It is common to heat seal the opening through the part.

The vacuum packaging machine as described above may be configured to include an electronic control unit to automatically control its operation, as described above is disclosed in detail through the Republic of Korea Utility Model Publication No. 20-0235323, the details The description will be omitted.

However, in the conventional nozzle type vacuum packaging machine, in order to control the position of the nozzle during the vacuum and heat sealing, the nozzle is inserted into the inside of the vacuum packing paper during the vacuum and the nozzle must be separated from the vacuum packing paper during the heat sealing after the vacuum. There was a problem that complicated devices are required.

In addition, the nozzle-type vacuum packaging machine has a problem that the liquid or solid, which is located inside the vacuum packaging paper during the vacuum flows into the vacuum pump along the nozzle, the vacuum pump is damaged and broken.

An object of the present invention is to provide a vacuum packaging machine equipped with a nozzle housing capable of preventing the liquid or solid inside the vacuum packaging paper from flowing into the vacuum pump.

In order to achieve the above object, the vacuum packaging machine equipped with the nozzle housing of the present invention includes a base member having a heating part formed therein and a vacuum pump embedded therein; A cover member covering the base member; A nozzle housing mounted to the base member; An air suction port formed in the nozzle housing so as to communicate with the vacuum pump; It comprises a nozzle mounted to the nozzle housing, the nozzle housing accommodates the liquid or solid sucked through the nozzle.

The nozzle housing consists of an upper case and a lower case, and a gasket is mounted between the upper case and the lower case.

The nozzle housing has a nozzle insertion portion protruding from the nozzle housing, and a through hole is formed in the nozzle insertion portion.

The air inlet is formed on the bottom surface of the lower case, it is formed to surround the air inlet and the hollow suction projection protrudes upward.

Preferably, a gasket is mounted between the bottom surface of the lower case in which the air suction port is formed and the air passage formed in the base member to communicate with the vacuum pump.

The nozzle insertion portion includes an upper nozzle insertion portion and a lower nozzle insertion portion, wherein the upper nozzle insertion portion is formed in the upper case, and the lower nozzle insertion portion is formed in the lower case, and the upper nozzle insertion portion and the lower nozzle insertion portion are The nozzle inserts are formed in contact with each other.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

3 is a perspective view of a vacuum packaging machine according to an embodiment of the present invention, Figure 4 is a cross-sectional view of the vacuum packaging machine according to an embodiment of the present invention, Figure 5 is a nozzle housing 300 and the nozzle ( 400 is an exploded perspective view, and FIG. 6 is a cross-sectional view of the nozzle housing 300 according to the embodiment of the present invention.

As shown in FIG. 3 or FIG. 4, the present invention has a base member 200, a cover member 110 covering the base member 200, and a nozzle housing 300 mounted to the base member 200. Is done.

The base member 200 and the cover member 110 are hinged so that the cover member 110 rotates around the hinge.

The heating pressing part 120 is positioned at the foremost front of the cover member 110, and the heating part 220 is positioned at the position corresponding to the heating pressing part 120 at the base member 200.

The heating pressing unit 120 and the heating unit 220 are in contact with each other with the vacuum wrapping paper 600 interposed therebetween when heat sealing the vacuum wrapping paper 600.

In addition, upper and lower compression rubbers 130 and 230 are mounted at the rear of the heating pressing part 120 and the heating part 220, and mounting grooves are formed at the rear of the lower compression rubber 230, respectively. The nozzle housing 300 is mounted, and the nozzle housing 300 is equipped with a nozzle 400.

An inclination portion 240 is formed at the forefront of the base member 200. The inclination portion 240 is formed at the front edge of the base member 200. Unlike in the past, the inclination portion 240 is formed at almost right angles. It is formed to have a slope.

The inclined portion 240 serves to determine the position of the vacuum wrapping paper 600, the user by placing the vacuum wrapping paper 600 on the inclined portion 240, the vacuum wrapping paper 600 is biased toward either side. You can do it.

The lower recess 210 is formed on both left and right sides of the heating unit 220 in the base member 200.

A suction port (not shown) is positioned at the center of the lower recess 210, and the suction port communicates with the vacuum pump 250 embedded in the base member 200.

A packing 211 formed of a material having elasticity is positioned at the edge of the lower recess 210.

In addition, an upper recess 110 is formed at a position corresponding to the lower recess 210 in the cover member 110.

The packing 111 formed of an elastic material is positioned at the edge of the upper concave portion 110, and when the cover member 110 is closed over the base member 200, the upper concave portion 110 and the lower concave. The unit 210 forms a chamber.

The chamber is formed to be in close contact with the cover member 110 and the base member 200, and the adhesion between the cover member 110 and the base member 200 is increased by atmospheric pressure as the inside of the chamber becomes vacuum. do.

In the accompanying drawings, the upper recessed part 110 and the lower recessed part 210 are shown in the embodiment in which both are formed, but if the chamber including the suction port (not shown) can be formed, the upper recessed part 110 or lower recessed part. Only one of the portions 210 may be formed.

However, it is preferable that the packings 111 and 211 for sealing the chamber are also located on the side where the recess is not formed.

The nozzle housing 300 is composed of an upper case 310 and a lower case 320, as shown in Figures 4 to 6, the sealing between the upper case 310 and the lower case 320 Gasket 370 is mounted.

The upper case 310 and the lower case 320 may be formed to be separated separately, but one side is preferably hinged.

In addition, the nozzle housing 300 has a nozzle inserting portion 390 protruding outward, and the nozzle inserting portion 390 may be formed only in the upper case 310 or the lower case 320. 5 and 6, the upper case 310 and the lower case 320 are preferably in contact with each other.

That is, the nozzle insertion unit 390 is formed by the upper nozzle insertion unit 392 formed in the upper case 310 and the lower nozzle insertion unit 394 formed in the lower case 320 contact each other.

In this case, the upper and lower nozzle inserts 392 and 394 are in contact with each other to form a through hole 396, and the nozzle insert 390 is equipped with the nozzle 400 having the nozzle hole 410.

By doing so, the upper and lower cases 392 and 394 may be mutually coupled by mounting the nozzle 400 to the nozzle insert 390 without a separate coupling device for coupling the upper case 310 and the lower case 320. Can be.

An air inlet 340 is formed in the lower case 320, and the air inlet 340 is connected by a vacuum pump 250 and an air passage 252.

The lower case 320 receives liquid or solid sucked through the nozzle 400.

In this case, a separate container (not shown) may be mounted on the lower case 320 to accommodate the liquid or solid.

The width of the holder is smaller than the width of the lower case 320 so that the holder does not close the air inlet 340.

On the other hand, the air inlet 340 may be formed in the upper case 310, but is formed on the bottom surface of the lower case 320 and surrounds the air inlet 340 and is formed to protrude a hollow suction protrusion 342 to the top Preferably.

At this time, the hollow suction protrusion 342 is preferably formed to be larger than the maximum height of the liquid is deposited on the lower case (320).

In this way, the liquid or solid contained in the lower case 320 can be prevented from entering the air inlet 340.

A gasket 344 is mounted between the bottom surface of the lower case 320 in which the air inlet 340 is formed and the air passage 252 formed in the base member 200 to prevent air from being introduced or discharged therebetween.

In addition, the nozzle 400 mounted on the nozzle insert 390, that is, the nozzle 400 inserted around the outer shape of the nozzle insert 390 is formed to have a longer length than the nozzle insert 390. Thus, when the nozzle 400 is mounted on the nozzle insert 390, the nozzle 400 protrudes more than the nozzle insert 390.

For example, the length of the nozzle insert 390 is about 10 mm, and the length of the nozzle 400 is preferably about 30 mm.

At this time, the end of the nozzle 400, that is, the other end opposite to the end inserted into the nozzle insert 390 is disposed between the lower pressure rubber 230 and the heating part 220.

In this way, the pressing rubber (130,230) formed in the cover member 110 and the base member 200 during the operation of the vacuum packaging machine to press the nozzle 400.

The nozzle 400 may be made of plastic, iron, or the like, but preferably made of rubber.

In addition, the nozzle 400 may be tapered such that the height thereof becomes smaller toward the end, thereby allowing the air suction in the vacuum packing paper 600 to be better.

By making the nozzle 400 made of rubber, there is no need to install a separate packing member to block the inflow of air between the nozzle 400 and the nozzle insert 390, and it is easy to clean the nozzle 400. In addition, when the cover member 110 is closed, the nozzle 400 is gradually pressed by the pressing rubbers 130 and 230, and when the vacuum packing paper 600 is heat-sealed by the heating unit 220, air inflows through the nozzle 400. You can also stop.

When the nozzle 400 is made of plastic or steel, of course, a packing for sealing the nozzle insert 390 should be installed.

The present invention may use a vacuum wrapping paper that is not formed with embossing, it is preferable to use a vacuum wrapping paper formed with embossing.

In addition, by inserting a vacuum tray (not shown) into the vacuum packaging paper not embossing is formed, it can be packaged in a more complete vacuum state.

The vacuum tray refers to the one disclosed by the Registration Utility Model Publication No. 20-0378226.

Hereinafter, look at the operation of the embodiment of the present invention made of the above-described configuration.

First, the nozzle 400 is inserted into the opening of the vacuum packaging paper 600 to be disposed adjacent to the nozzle housing 300.

When the cover member 110 is closed, the pressure rubbers 130 and 230 compress the nozzle 400 and the vacuum wrapping paper 600 surrounding the nozzle 400 so that air does not flow into the vacuum wrapping paper 600.

When operating the vacuum pump 250 in this state, the vacuum pump 250 is connected to the air inlet 340 formed in the lower case 320 of the nozzle housing 300, inside the vacuum packaging paper 600 Gas is introduced into the nozzle housing 300 through the nozzle 400 and the through hole 314, and the air introduced into the nozzle housing 300 is sucked into the air suction port 340.

Meanwhile, the air inside the chamber formed between the upper recess 110 and the lower recess 210 is sucked into the vacuum pump 250 through the suction port formed in the lower recess 210.

Therefore, when the vacuum pump 250 operates while the cover member 110 and the base member 200 are closed, both the vacuum packaging paper 600 and the inside of the chamber become vacuum.

When the inside of the chamber becomes a vacuum, the adhesion between the cover member 110 and the base member 200 by the atmospheric pressure is increased accordingly, this increase in adhesion causes the compression of the elastic packing (111, 211).

When the elastic packing 111 and 211 are compressed, the cover member 110 can be lowered more toward the base member 200, and the lowering of the cover member 110 is in close contact with the heating unit 220 and the cover member 110. Will increase.

In this case, the liquid or solid may be introduced into the nozzle 400 by the suction force of the vacuum pump 250, but the liquid or the solid introduced into the nozzle 400 may pass through the through hole 396. It is introduced into the nozzle housing 300 through the drop in the lower case 320 is deposited.

By doing so, even if there is a liquid or solid inside the vacuum wrapping paper 600, only the gas can be sucked into the air suction opening 340 by the hollow suction protrusion 342, so that the vacuum pump 250 is not damaged.

When the inside of the vacuum wrapping paper 600 becomes a vacuum, the heating unit 220 formed on the base member 200 is operated to heat seal the opening of the vacuum wrapping paper 600.

At this time, the nozzle 400 is pressed by the pressing rubbers 130 and 230 to block the inflow of air through the nozzle 400.

When the heat sealing of the opening of the vacuum wrapping paper 600 is completed, the cover member 110 is opened to remove the vacuum wrapping paper 600 from the nozzle 400.

Meanwhile, the nozzle housing 300 is removed from the base member 200, and a hose (not shown) is connected to the air passage 252 formed in the base member 200 to vacuum-pack a vacuum container (not shown). It can be used to

The vacuum container used at this time refers to a general container used for vacuum packaging by attaching a vacuum valve to a container lid, which has been disclosed through the Utility Model Registration Publication No. 20-0332153.

Vacuum packaging machine equipped with the nozzle housing of the present invention is not limited to the above-described embodiment, it can be carried out in a variety of modifications within the range allowed by the technical idea of the present invention.

According to the vacuum packaging machine equipped with the nozzle housing of the present invention as described above has the following effects.

First, by mounting the nozzle housing, the liquid or solid sucked through the nozzle can be dropped and deposited in the nozzle housing without being moved to the vacuum pump, thereby preventing breakage of the vacuum pump.

In addition, the nozzle housing is made of a separate member and the base member, it is easy to clean and replace.

In addition, it is easy to clean the nozzle later by separating the nozzle from the nozzle housing.

Second, the nozzle housing is formed of an upper case and a lower case to facilitate opening and closing, and by mounting a gasket between the upper case and the lower case, the outside of the nozzle housing can be completely blocked from entering the air.

Third, by forming the nozzle insert, it is easy to mount / remove the nozzle to the nozzle housing.

Fourth, by forming a hollow suction projection, it is possible to prevent the liquid and the like deposited in the lower case to flow into the air intake.

Fifth, by installing a gasket between the bottom surface of the lower case and the air passage, it is possible to prevent the air flowing in / out therebetween.

Sixth, the upper and lower cases are formed in contact with the upper case and the lower case, the upper and lower cases can be combined by mounting the nozzle to the nozzle insert without a separate coupling device in the upper case or lower case.

1 is a perspective view showing a conventional chamber vacuum packaging machine,

Figure 2 is a perspective view showing a vacuum packaging paper formed with a conventional embossing,

3 is a perspective view of a vacuum packaging machine according to an embodiment of the present invention,

4 is a cross-sectional view of a vacuum packaging machine according to an embodiment of the present invention,

5 is an exploded perspective view of a nozzle housing and a nozzle of an embodiment of the present invention;

6 is a cross-sectional view of the nozzle housing of the embodiment of the present invention;

<Description of the symbols for the main parts of the drawings>

100: cover member, 110: upper recess

111: packing, 120: heating pressing portion,

130: upper pressurized rubber 200: base member,

210: lower recess, 211: packing,

220: heating part, 230: lower pressure rubber,

240: inclined portion, 250: vacuum pump

252: air passage, 300: nozzle housing,

310: upper case, 320: lower case,

340: air intake, 342: hollow suction projection,

344, 370: gasket, 390: nozzle insert,

392: upper nozzle insertion part, 394: lower nozzle insertion part,

396: through hole, 400: nozzle,

410: nozzle hole, 600: vacuum packaging paper.

Claims (6)

A base member having a heating portion and a vacuum pump embedded therein; A cover member covering the base member; A nozzle housing mounted to the base member; An air suction port formed in the nozzle housing so as to communicate with the vacuum pump; It comprises a nozzle mounted to the nozzle housing, The nozzle housing is vacuum packaging machine equipped with a nozzle housing, characterized in that for receiving the liquid or solid sucked through the nozzle. The method of claim 1, The nozzle housing is made of an upper case and a lower case, A vacuum packaging machine equipped with a nozzle housing, characterized in that the gasket is mounted between the upper case and the lower case. The method according to claim 1 or 2, The nozzle housing has a nozzle insertion portion protruding from the nozzle housing, The nozzle inserter is a vacuum packaging machine equipped with a nozzle housing, characterized in that the through-hole is formed. The method of claim 2, The air intake is formed on the bottom of the lower case, A vacuum packaging machine equipped with a nozzle housing, characterized in that the hollow suction projection is formed to surround the air inlet and protrude upward. The method of claim 4, wherein And a gasket is mounted between the bottom surface of the lower case in which the air inlet is formed and the air passage formed in the base member to communicate with the vacuum pump. The method of claim 3, wherein The nozzle insertion portion is composed of an upper nozzle insertion portion and a lower nozzle insertion portion, The upper nozzle insert is formed in the upper case, the lower nozzle insert is formed in the lower case, And the upper nozzle inserter and the lower nozzle inserter are in contact with each other to form a nozzle inserter.