KR200256485Y1 - Can having self-chilling function - Google Patents

Abstract

The present invention relates to a container capable of self-cooling capable of effectively cooling a beverage such as water, a soft drink or an alcoholic beverage, and more particularly, can improve the self-cooling efficiency of the stored beverage as well as inadvertently. The present invention relates to a self cooling can that can recharge the refrigerant even if it leaks.

To this end, the present invention is a refrigerant chamber 410 of a predetermined shape is fixed to the support plate 420, to cool the beverage using the latent heat of evaporation by ejecting the refrigerant (G) charged in the refrigerant chamber 410 In constructing a can 400 having a self cooling function: a cylindrical housing 500 which is inserted and fixed to a cylindrical portion 411 of the coolant chamber 410 and has a plurality of coolant access holes 501 formed on an outer circumferential surface thereof. )and; It is installed at one end of the housing 500 and is opened by the pressure of the refrigerant when the refrigerant is injected, is normally closed by the bias of the elastic means 510 is provided with a packing 521 so that the refrigerant is not ejected to the outside The lifting bar 520; One end of the elevating rod 520 is provided with a recess 531a and the inner periphery of the recess 531a has a head portion 531 having a plurality of elongated holes 531b, and the head portion 531 A coolant passage 532 communicating with the groove 531a in the axial direction is formed therein so that the end portion of the head portion 531 is engaged with the packing 521 of the elevating rod 520 by the elastic means 533. However, when pulling out the knob 534 exposed to the outside of the can lower end 403, the refrigerant is discharged to the outside through the refrigerant passage 532 to seal the beverage in the can; And a burstable safety layer 540 attached to the can lower end 403 to prevent inadvertent pulling of the knob 534 of the sealing rod 530.

Description

Can having self-chilling function

The present invention relates to a container capable of self-cooling capable of effectively cooling a beverage such as water, a soft drink or an alcoholic beverage, and more particularly, can improve the self-cooling efficiency of the stored beverage as well as inadvertently. The present invention relates to a self cooling can that can recharge the refrigerant even if it leaks.

In general, cans for storing beverages, such as soft drinks or alcoholic beverages, have a structure that is convenient to carry. In order to maintain the beverage stored in such cans in a low temperature state, a separate refrigeration facility is required, and in particular, a cold storage facility such as a separate ice box is required to drink the beverage in a cool state outdoors. Since such cans are generally disposable, after drinking the beverage in the cans, the cans no longer need to be stored in refrigeration or cold storage facilities.

However, in order to provide such a refrigerating facility or a cold storage facility, a separate space and a cost are required. In particular, there is a problem in that the cans are moved to a state in which the cans are stored in the cold storage facility. In addition, while a long time is required to cool a can by a conventional refrigerating facility or a cold storage facility, a problem arises in that the operating cost of the above-described facility or facility is increased to rapidly cool the can.

In order to solve this problem, in recent years, the refrigerant has a large latent heat of evaporation and a ratio of liquid specific heat and liquid specific heat to evaporative heat so that even a small amount of refrigerant in the canister can lower the temperature of the beverage or beer. If a small one or a refrigerant stored in the refrigerant chamber solidifies at a high temperature, it cannot be used as a cooling refrigerant. Therefore, a cooling device using a refrigerant having a low solidification temperature has been developed so that the refrigerant can be used even at a low temperature. .

In addition, there was another technique of using a compressed gas, a heat exchange between a beverage and a reactant by reaction of water and a drug, and a compressed gas is ejected into the beverage and cooled.

In addition, by combining the characteristics of the refrigerant and the structure of the refrigerant chamber to secure a large amount of lateral or longitudinal space in the refrigerant chamber in order to maximize the cooling area, the contact area between the beverage and the refrigerant chamber is increased, and the refrigerant chamber is monotonically in the form of a cup. Although the refrigerant stored in the refrigerant chamber has a low condensation pressure, a high critical temperature, a low solidification temperature, and a large amount of latent heat of evaporation, a situation in which the refrigerant is continuously improved.

However, despite the existing technology as described above, the fact that self-cooling cans are not idealized so far is that the new refrigerants have not been approved by the governments for safety, and the cooling speed is slow, which impairs practicality. In the case of using the compressed gas, the cooling effect is reduced when the size of the refrigerant chamber storing the compressed gas is minimized, and the refrigerant chamber may explode at room temperature when the refrigerant chamber is enlarged, which makes it impossible to commercialize it. .

In particular, in the case of using compressed gas, in order to maximize the cooling effect, a plurality of openings are formed in the transverse direction or the longitudinal direction so that the structure of the refrigerant chamber can be in contact with the beverage in many cases. Bars are made of holes to form a tube, the structure of the cylinder is complicated, there is a fear that the airtightness is reduced, there is a disadvantage that mass production is impossible.

For example, a conventional can cooling device (Utility Model Registration Application Publication No. 1999-03937) that allows a beverage to be cooled by drinking on the fly will be schematically described with reference to FIGS.

Referring to FIG. 1, a conventional can 10 having a self cooling function includes a can body 12, a can upper end 14 and a can lower end 16. These can upper ends 14 and can lower ends 16 are seamed at the upper and lower ends of the can body 12, respectively. A can opener (not shown) is riveted to the can upper end 14, and the can upper is broken as the score line (not shown) formed in the can upper end 14 is ruptured by pulling the can opener upward. Openings are formed in the end 14 so that people can drink the beverages contained in the can 10.

In addition, one refrigerant cylinder 18 and a plurality of auxiliary refrigerant cylinders 52 are provided in the can 10, the upper end of the refrigerant cylinder 18 is closed, and the lower end is open, and the refrigerant cylinder 18 is provided. The refrigerant storage space 22 and the refrigerant expansion space 42 are provided in a manner that is in communication with each other, and the refrigerant cylinder 18 at the boundary of the refrigerant storage space 22 and the refrigerant expansion space 42. The nozzle 20 is formed inside, and when the refrigerant is discharged through the nozzle 20, due to a hydrodynamic effect generated by the rapid flow of the refrigerant in the nozzle 20, the temperature of the nozzle 20 portion Is rapidly cooled, and thus the cooling effect of the beverage can be doubled, and the plurality of auxiliary refrigerant cylinders 52 are connected to the refrigerant storage space 22 of the refrigerant cylinder 18 via the tube 50 to thereby cool the refrigerant. Supplementally stores the

As shown in FIG. 2, the upper end of the clip member 26 is sealed seam at the lower end of the refrigerant cylinder 18, and an opening is formed in the can lower end 16 of the can 10. The lower end of the clip member 26 is sealingly seamed to a portion of the can lower end 16 which provides an opening. A cylinder fixture 24 is in close contact with the outer surface of the can lower end 16, and a central portion of the cylinder fixture 24 is formed in such a manner that the wedge portion 28 protrudes upward. The wedge 28 is inserted through the opening into the can 10 and then snap-fitted to the clip member 26. The lower end of the refrigerant cylinder 18 is closed by the closing member 34, and the closing member 34 is seamed together with the lower end of the refrigerant cylinder 18 and the upper end of the clip member 26.

The cylinder fixture 24 is formed with a horizontal refrigerant passage 40 extending in the horizontal direction, the wedge portion 28 is formed with a female screw hole 30 extending in the vertical direction. The lateral refrigerant passage 40 and the female threaded hole 30 communicate with each other. The movable member 54 is screwed into the female threaded hole 30, and the center portion of the movable member 54 is fitted in a manner that the pin 32 penetrates. The pin 32 may move together with the movable member 54, and a plurality of axial grooves 46 are formed on an outer surface of the pin 32. The head portion 36 is integrally formed at the lower end of the pin 32. Accordingly, by rotating the head portion 36 by hand, the pin 32 can be moved up and down along the female screw hole 30. In this case, the movable member 54 may have a cutout 48 formed therein so that the plurality of axial grooves 46 and the lateral refrigerant passage 40 may communicate smoothly. A depression 38 is formed on the lower surface of the cylinder fixture 24, and the head portion 36 of the pin 32 is positioned on the depression 38. Since the safety film 44 is adhered to the lower end surface of the cylinder fixture 24 by an adhesive, the pin 32 is not exposed to the outside, thereby preventing the unintentional rotation of the pin 32.

Therefore, when you want to drink beverages rupture the safety film 44 and rotate the head portion 36 of the pin 32, the pin 32 is moved upwards and the tip of the pin 32 is the closing member ( 34). As a result, the refrigerant is discharged to the outside through the plurality of axial grooves 46, the cutouts 48, and the transverse refrigerant passage 40 formed on the outer surface of the fin 32, thereby deodorizing the beverage. It can be cooled.

However, in the cooling can shown in Figs. 1 and 2, it is difficult to substantially inject refrigerant into the cylinders 18 and 52, and the closing member 34 is ruptured once by the pins 32 so that the refrigerant is completely discharged. There was a problem that can not charge the refrigerant again.

In other words, there is a problem that unintentionally man can operate the head 36 to refill the refrigerant upon release of the refrigerant according to the closing member 34, thereby losing the original intended self-cooling function.

Meanwhile, Patent Application Publication No. 2000-31487 discloses a can having a self-cooling function to vaporize and release compressed and stored liquefied carbonic acid gas to the outside as shown in FIGS. 3 and 4 to cool the drinking water. The helical cylinder 100 is coupled to the canzer part 300, and the stopper 200 is assembled to the diffusion hole which is the inner hole of the coupling part, and thus the helical cylinder 100 (the detailed structure is omitted in FIGS. 3 and 4). ), The length is proportional to the volume of the beverage container, and the cylinder 100 is compressed in any shape at the lower portion thereof, and the nozzle portion 102 is formed between the pressing portions 101, and the nozzle The lower part of the part 102 forms the diffusion tube 103, and the coupling portion 105 is formed at the lower end of the diffusion tube 103.

As shown in FIG. 3, when the stopper 200 is assembled, the sealing protrusion 211 of the sealing rod 210 passes through the through hole of the nozzle portion 102 and is coupled to and sealed at the upper end thereof. It is elastically passed through the coupling portion 105 is fixed to the step 104, the sealing portion 206 (see Fig. 4) is in close contact with the coupling portion 105 to maintain the sealing force.

Therefore, in the same state as 3 to drink the beverage contained in the can, pressing the stopper 200 upwards, as shown in Figure 4 the stopper 200 is moved upwards, because the stopper 200 is moved upward The refrigerant discharge grooves 212, 209, 207 are opened, and the refrigerant G entrained in the helical cylinder 100 is vaporized as it flows into the diffusion pipe 103 through the refrigerant discharge groove 212, and the refrigerant vaporized and diffused at the same time. (G) is discharged to the outside through the refrigerant discharge grooves (209, 207).

In the above process, the refrigerant G cools the beverage contained in the beverage can by the latent heat of evaporation.

However, the cooling cans shown in FIGS. 3 and 4 are also difficult to substantially inject the refrigerant into the cylinder 100, and when the sealing protrusion 211 of the sealing rod 210 is moved upward and the refrigerant is completely discharged, the refrigerant again. There was a problem that can not be charged.

In other words, a person unintentionally presses the stopper 200 upwards to prevent refilling of the refrigerant upon release of the refrigerant due to the sealing protrusion 211 of the sealing rod 210, thereby losing the original intended self-cooling function. There was a problem.

The present invention has been made to solve the problems inherent in the can having a self-cooling function according to the prior art as described above, the object of the present invention is to improve the self-cooling efficiency for the stored beverage as well as unintentional Therefore, even if the coolant flows out, it is possible to recharge the coolant to provide a self cooling can.

1 is a schematic cross-sectional view showing the structure of a can having a self-cooling function according to the present invention;

2 is a partially enlarged cross-sectional view illustrating a refrigerant discharge structure of the can of FIG. 1;

3 and 4 are internal structural views of a can having a self-cooling function according to another prior art in which a spiral cylinder is sealed in the canister;

5 is a cross-sectional view of a self cooling can according to the present invention;

Fig. 6 is a partially enlarged view of Fig. 5, showing a state of normal operation in which the can is not cooled;

FIG. 7 is a partially enlarged view of FIG. 5, which is a state diagram when liquefied carbon dioxide is injected into a can; FIG.

FIG. 8 is a partially enlarged view of FIG. 5, showing a state in which liquefied carbon dioxide is discharged to cool the can; FIG.

9 is a cross-sectional view of another embodiment of the present invention.

* Description of symbols on the main parts of the drawings *

400: can 401: can body

402: Can Upper End 403: Can Lower End

410: refrigerant chamber 411: cylindrical portion of the refrigerant chamber

420: support plate G: refrigerant

500: housing 501: refrigerant access holes

510,533: elastic means 520: lifting bar

521: packing 530: sealed

531: head portion 531a: groove

531b: cleaning process 532: refrigerant passage

534: knob 540: breakable safety shield

Self cooling cans according to the present invention for achieving the above object, the refrigerant chamber of a predetermined shape is fixed to the support plate, to cool the beverage using the latent heat of evaporation by ejecting the refrigerant charged in the refrigerant chamber In forming a can having a self-cooling function, the cylindrical housing is inserted into and fixed to a cylindrical portion of the refrigerant chamber, and a cylindrical housing having a plurality of refrigerant access holes formed on an outer circumferential surface thereof; An elevating rod installed at one end of the housing and opened by pressure of the refrigerant when the refrigerant is injected, and normally closed by a bias of the elastic means to prevent the refrigerant from being blown out; One end of the elevating rod is provided with a recess, and the inner circumference of the groove has a head portion having a plurality of elongated holes, and a refrigerant passage communicating in the axial direction with the recess of the head portion is formed therein, and the head portion is formed by elastic means. An airtight rod having an end portion engaged with the packing of the lifting rod, wherein a refrigerant is discharged to the outside through the refrigerant passage when the knob exposed to the outside of the can lower end is pulled out to cool the beverage in the can; And a rupturable safety film attached to the can lower end to prevent inadvertent pulling of the knob of the sealing rod.

The refrigerant chamber used in the present invention -Shaped or It is preferable to be welded to the supporting plate as a -shaped tube.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention in detail as follows.

5 is a partial cutaway view of a can having a self cooling function according to the present invention. Similar to the description with reference to FIG. 1, the can 400 according to the present invention includes a can body 401 and a can upper. An end 402 and a can lower end 403, which can seam end 402 and can lower end 403, respectively, seam at the top and bottom of the can body 401.

And inside the can 400 The shaped coolant cylinder 410 is fixed to the support plate 420 adjacent to the lower end 403 by a suitable method (such as welding). Therefore, as will be described later, the can 400 according to the present invention can cool the beverage using latent heat of evaporation caused by ejecting the refrigerant G charged in the refrigerant chamber 410, and also facilitates the refrigerant. Injecting into the seal 410 allows the refrigerant to be recharged even though it is unintentionally leaked.

Referring to Figure 6, this figure shows a state in which the refrigerant (G) is filled in the refrigerant chamber 410, for this purpose the present invention includes a cylindrical housing 500, this housing 500 Is fixedly inserted into the cylindrical portion 411 of the refrigerant chamber 410, and a plurality of refrigerant access holes 501 are formed on the outer circumferential surface thereof so as to inject a refrigerant (for example, liquefied carbon dioxide) as described later. The passage of these refrigerants is provided at the time of blowing.

As shown in FIG. 7, the elevating rod 520 is installed at one end of the housing 500 and is opened by the pressure of the refrigerant when the refrigerant is injected. As shown in FIG. 6, the lifting rod 520 is normally applied to the bias of the elastic means 510. The lift bar 520 is closed so that the refrigerant is not ejected to the outside, and the lifting bar 520 is provided with two stoppers 520a and 520b and a packing 521. Here, the stopper 520a determines the lifting height of the lifting rod 520, and the packing 521 is attached to the stopper 520b.

On the other hand, the bottom of the elevating rod 520 bar is located bar 530, the sealing rod 530 has a groove (531a) is accommodated in one end of the lifting bar 520 and the inside of the groove (531a) The peripheral portion includes a head portion 531 in which a plurality of elongated holes 531b are formed. Therefore, the sealing rod 530 is formed in the refrigerant passage 532 communicated in the axial direction with the groove 531a of the head portion 531 therein, the end portion of the head portion 531 by the elastic means 533 is raised. In order to engage with the packing 521 of the steel rod 520, when pulling the knob 534 exposed outside the can lower end 403, the refrigerant is discharged to the outside through the refrigerant passage 532 to drink the beverage inside the can. It is supposed to cool.

Referring back to FIG. 5, the can lower end 403 is attached to the breakable safety layer 540 to prevent inadvertent pulling of the knob 534 of the sealing rod 530.

The working state of the present invention configured as described above will be described in detail.

First, the process of injecting the refrigerant G into the can 400 will be described. As shown in FIG. 7, the injection nozzle of the liquefied carbon dioxide injector, which is a refrigerant in the state where the sealing rod 530 is pushed into the can 400, is described. (Not shown) is inserted into the refrigerant passage 532 of the knob 534 in the direction of the arrow A, and when liquefied carbonic acid is injected, the stopper of the lifting rod 520 by the injection force of the liquefied carbonic acid gas ( 520b and the packing 521 attached thereto are slightly spaced apart from the end of the head portion 531. Here, the biasing force by the elastic means 510 is considered to be smaller than the injection pressure of the refrigerant. Accordingly, as the packing 521 is spaced apart from the end of the head portion 531, the liquefied carbonic acid gas G is formed through a plurality of thin holes 531b formed in the groove 531a of the head portion 531 in the axial direction. It can be charged in the refrigerant chamber 410 in the direction of the arrow (B).

Then, when the filling of the refrigerant G is completed and the injection nozzle of the liquefied carbon dioxide injector is removed from the knob 534, the lifting rod 520 is lowered by the restoring force by the elastic means 510, and thus, FIG. As shown in the drawing, the packing 521 is closely engaged with the end of the head portion 531, so that the refrigerant G cannot be ejected through the refrigerant passage 532. In this case, the elastic means 510 and 533 Since the lifting bar 520 and the sealing bar 530 is further maintained in a compressed state, a gap between the end of the head portion 531 of the sealing bar 530 and the packing 521 of the lifting bar 520. Since it is tightly coupled without any refrigerant, the refrigerant will not leak at all. Thereafter, the can lower end 403 is attached with a breakable safety film 540 made of aluminum, as shown in FIG. 5, and the can is commercially available.

As shown in FIG. 6, the safety bar 540 is removed in order to drink the contents, and when the knob 534 is pulled downward as shown in FIG. 8, the sealing rod 530 is lowered. In this case, the packing 521 is closely attached to the packing 521. The ends of the sealing rods 530 that were present are spaced apart. Accordingly, as the end portion of the head portion 531 is spaced apart from the packing 521, a plurality of thin holes 531b formed in the axial direction in the recesses 531a of the head portion 531 are formed in the refrigerant chamber 410. It is ejected to the outside through the refrigerant passage 532.

Therefore, as the refrigerant is ejected to the outside in a moment, the beverage can be rapidly cooled by deodorizing the heat of the beverage.

FIG. 9 shows a can similar to the can shown in FIG. In place of the coolant chamber 410 Since the refrigerant chamber 410 has a shape, other functions are the same, detailed description thereof will be omitted.

As described above, the present invention not only improves the self cooling efficiency of the stored beverage, but also has the advantage of recharging the refrigerant even if the refrigerant accidentally flows out.

Although the present invention has been described with reference to the accompanying drawings, the present invention is not limited thereto and there may be many variations and modifications within the scope of the following claims.

For example, the shape of the refrigerant chamber may have a spiral or other shape in addition to those shown.

Claims (2)

A refrigerant chamber 410 having a predetermined shape is fixed to the support plate 420, and has a self cooling function for cooling the beverage using latent heat of evaporation caused by ejecting the refrigerant G charged in the refrigerant chamber 410. In constructing the can 400 having: A cylindrical housing 500 inserted into and fixed to the cylindrical portion 411 of the coolant chamber 410 and having a plurality of coolant access holes 501 formed on an outer circumferential surface thereof; It is installed at one end of the housing 500 and is opened by the pressure of the refrigerant when the refrigerant is injected, is normally closed by the bias of the elastic means 510 is provided with a packing 521 so that the refrigerant is not ejected to the outside The lifting bar 520; One end of the elevating rod 520 is provided with a recess 531a and the inner periphery of the recess 531a has a head portion 531 having a plurality of elongated holes 531b, and the head portion 531 A coolant passage 532 communicating with the groove 531a in the axial direction is formed therein so that the end portion of the head portion 531 is engaged with the packing 521 of the elevating rod 520 by the elastic means 533. However, when pulling out the knob 534 exposed to the outside of the can lower end 403, the refrigerant is discharged to the outside through the refrigerant passage 532 to seal the beverage in the can; And Self-cooling can is attached to the can lower end (403) characterized in that it consists of a tear-resistant safety film (540) for preventing the unintentional pulling of the knob (534) of the sealing rod (530). The method of claim 1, wherein the refrigerant chamber 410 is -Shaped or Self cooling can characterized in that it is shaped.