SE449084B - KLEMFORPACKNING - Google Patents

Description

10 15 20 25 30 449 084 N v logn å -logi - logßl / S0 + 5,45 -___ ~ - * lQ> 1ogn å u, sas1ogsU + u,? O4iogu f:, 3u 1: 1, och > 51 / 30- 2 (3) where n stands for viscosity of the content (cP), S stands for the cross-sectional area of the piece passage (mmz), S] stands in front of the area (mmz), 2 stands for the length of the living area in the shoulder direction and E represents the elastic recovery (g) of the tubular body in an unpackaged state.

The flexible, hollow plate container according to the invention is a container for squeezing out a content by pressing of the wall of the container, and this container may have the shape of a tube, a hollow bottle or the like.

Embodiments of the invention are described in more detail below with reference to the accompanying drawings, in which Fig. 1 is a plan view showing an embodiment of the package according to the present invention, Fig. 2 is a longitudinal sectional view of the package in Fig. 1, Fig. 3 is a longitudinal sectional view on a larger scale of a part of the package in Fig. 1, Fig. 4 is a cross-sectional view in larger scale along the line IV-IV in Fig. 1, Fig. SA shows schematically an example of the state when a viscous content is sucked into bake, Fig. SB schematically shows another example of the position when a viscous content is sucked back, Fig. SC shows schematically the dimensions of a number of parts, Figs. 6A and B shows graphical presence or absence of air intake in shape of the relationship between the viscosity of the contents and the residence part length, Figs. 7A, B, C show graphical presence or absence of air intake in the form of the relationship between the viscosity of the contents and the cross-sectional area of the nozzle passage, Fig. 8 is a sectional view on a larger scale referring to the laminated construction of a wall of the tubular container, Fig. 9 is a plan view showing another example of a tubular container according to the present invention invention, Figs. 10A, B, C are cross-sectional views showing examples in cross-sectional shape of the nozzle passage, Fig. 11A is a perspective view of showing the main portion of a tubular container according to a further embodiment of the invention, Fig. 11B is a perspective view showing the section along the line A-A in Fig. 11B. 1 and 2 The embodiment of a package shown in Figs. 10 15 20 25 30 3 449 084- according to the present invention comprises a tubular, container I, a lid 2 and a container packed in the container I hnll. Behnllaren I consists of a high cylindrical tube body 4, a narrowing portion n connected to the pipe body 4 and a clamping opening 6 and the pipe body 4 are closed at the rear end by means of an Eogrand 7.

As shown on the larger scale views according to Figs. 3 and 4 is between the tapered portion 5 and the clamping opening 6 formed a narrowed nozzle passage 8 and one with this via a ledge 10 connected to a ledge portion 9.

In this embodiment, the container 1 is made by blowing of a thermoplastic blank so that the respective parts integrated and the nozzle passage 8 is formed by the blank receiving intervene with a mold to reduce its diameter. In this edition embodiment shown in Fig. 4, the nozzle passage 8 has a square cross-sectional shape and the residence part 10 has a circular cross-sectional shape. The cross-sectional shapes of these parts are natural. not limited to those listed above, but may be selected free.

In this embodiment, the nozzle opening 8 is made by retraction of portions lying between four projections 9a 9.

According to the present invention, in the container packed the contents 3 a viscosity of 1000 to 250 000 cP, especially 5000 to 150 000 cP, at the state of use.

According to the present invention, further, the dimensions of the container and the viscosity of the contents determined in such a way that the requirements corresponding to the following relationships are met: iøgn š -iogi - iog sï / so + 5.45 (1) iogn ä o, sss iogso + 0.764 iog fi + 2.30 (2) and S1 / soš 2 (3) where n stands for viscosity (CP) of the content, SO stands for the cross-sectional area of the piece passage (mm2), S1 stands for the length in the shoulder direction and E stands for the elastic recovery (g) of the tubular body in an unpackaged state.

When the pipe body 4 with the contents is compressed for clamping of the viscous contents from the opening 6 and when the 449 084 4 10 15 20 25 the force 'on the pipe body ceases, it is observed in fig¿ few Qgh.§B showed the condition. More specifically, in the condition in which hnllct is clamped out by snmmnnprcssing of the pipe body I, nur Up to the position FO in Fig. SA and covers the plane of If the compression force ceases, the contents are sucked 3 in the retaining part 10 towards the pipe body 4, so that the contents outer end obtains a surface (P1) in the form of a paraboloid according to Fig. SA. If the viscous content 3 is further absorbed, as shown in Fig. SB, its central part is further sucked in, through finally an air passage is formed 11. At the state when the air passage is formed, air is sucked into the container and as mentioned above written, the air comes in contact with the contents over a large surface, resulting in a deterioration of the contents.

In the present invention, it is important to a period of about 20 seconds from the time the content is by squeezing until the container is resealed by means of the lid 2, the outer end surface of the viscous contents shall be located at the clamp opening side, at a distance from the critical the position FZ in Fig. SC.

According to Fig. SC, the flow volume V0 of the viscous contents is the direction sucked through the nozzle passage below the above period proportional to the cross - sectional area So and of the passage 8 inversely proportional to the viscosity n of the contents, whereby the flow volume V0 corresponds to the following relationship: V0 = k1 --- (4-1) Since the outer end surface FZ of the viscous content is approximate tive can be considered as a conical surface and assuming that the height of the conical surface is h and the base surface is S1 (this surface is equal to the cross-sectional area of the living area), the following band for flow volume V0: V0 = k2S1h Since the value of (Q-h) is equal to zero (2-h = 0) at (4 ~ 2) critical condition mentioned above, the following relationship is established: so 2 - h = E - kx ----- = 0 (4-3) . 81.11 The logarithm of this relationship can be expressed as follows: 10 15 20 25 30 35 f '' logn '= -log! -log - S0 + log kg (la) -, _ - “Ä In the connection above, k1, k¿ and ks are consonants. The value of log kB calculated from experimental results is 5.45.

The above relationship (Ia) and the experimental results are introduced in fig. 6A and óB, on which the ordinate indicates the contents viscosity n and the abscissa indicate the length 2 i of the living part 10 the axis direction. Pig. 6A shows the results obtained when S1 / S0 is 16 and fig. 6B shows the results obtained when S1 / S0 is 4. The rings indicate the state of the viscous contents in the container after 30 seconds from squeezing out the contents is what is shown in fig. SA and the crosses indicate that the condition of the viscous contents of the container after 30 seconds from the dress is what is shown in fig. SB.

From those in fig. The results shown in Figures 6A and 6B are clear that the above relationship (Yes) is decisively significant to prevent the presence of air intake. More specifically, if the dimensions of the holder and the viscosity of the contents are selected so that the requirements of connection (1) are met, the air suction is prevented. Especially if the viscosity of the contents is constant is an increase in the length 2 of the living part 10 i the axis direction and of the ratio S1 / S0 between the residence part cross-sectional area and the cross-sectional area of the nozzle passage effective for to prevent air intake, and if the dimensions of the container are constant is an increase in the viscosity of the contents as well as sam to prevent air intake.

According to the present invention, it is important to include the viscosity n of the hold, the cross-sectional area S0 of the nozzle passage and the elastic recovery E of the tubular body of the container is selected so that the requirements for the empirical relationship (Z) are met.

The experimental results are entered in Figs. 7A, B and C, on which the ordinate indicates the viscosity n of the contents and the abscissa san indicates the cross-sectional area S0 of the nozzle passage 8. Pig. 7A shows the results obtained when the elastic body of the tubular ning E is 100 g, fig. 7B shows the results obtained when the elastic recovery E of the tubular body is 200 g and Fig. 7C shows the result obtained when the elastic recovery E is 50 g. Rings indicate the state of the viscous content after squeezing out the contents is what is shown in fig. SA and X indicates the state of the viscous contents of the container 10 15 20 ZS 30 35 449 084 Û after ïöïseconds from the exclusion of content] ct_än_det ° ¿ as shown in Fig. SB.

From the results shown in Figs. A, B and C, no clear that the relationship (2) is crucial significant to prevent air intake, and the presence of air intake is prevented operating in the area above that indicated by the following connection: Log n = 0.588 logS0 + 0.64 logE + 2.30 (2a) Namely, if the viscosity of the contents is constant, a decrease in cross-sectional area SO of the nozzle passage or a reduction of the elastic recovery of the tubular body 4 effective to prevent air intake.

According to the present invention, it is important that when the compressive force on the pipe body 4 ceases and when it the viscous contents of the holding part 10 are sucked into the container, to obtain such a volume reduction that the viscous content the outer end of the hold obtains a surface F1 in the form of a paraboloid or a cone F1, shown in Fig. 5A, the holding part 10 shall have a relatively large cross-sectional area S1, that the nozzle passage 8 should have a relatively small cross-sectional area S0 and that a batch portion shall be formed between the residence part 10 and nozzle passage 8. When the opening of the container has a uniform continuous cross-section, the air intake can not at all is prevented by sucking in with such a volume reduction the entire outer end surface of the hold.

In the present invention, the air intake can be satisfactorily positioning is prevented by selecting the surface ratio S1 / S0 at least 2, especially at least 3. In case this relationship S1 / S0 is too large, the compressibility of the container is reduced and the shape of the holder deteriorates. It is thus preferred that the relationship S1 / S0 is not greater than 20, in particular not greater than 10.

From the description above it is clear that according to the present invention, air intake can be prevented by the formation of the piece passage 8 and the residence part 10 and by fixing the values of S0, S1 / S0 and ß, so that the requirements for the relationships (1), (Z) and (3) are satisfied, even if the viscosity of the contents 3 n is relatively low and the elastic recovery E of the container is relatively large.

The tubular container 1 according to the invention can be 10 15 20 25 35 40 r 449 084 set-of any material. It can, for example, be forward; made of a plastic material. a mctnllfolic, a laminate of these or a laminate nv a plastic material or a muiull- foil with paper.

As the plastic material, olefin resins such as LD poly- etcn, MD polyethylene or HD polyethylene, isotactic polypropylene, a crystalline ethylene-propylene copolymer, an ethylene-vinyl acetate copolymer and an ion crosslinked olefin copolymer, nylon resins such as nylon 6, nylon 6,6 and nylon 12, polyesters such as polyethylene terephthalate and polybutylene terephthalate, vinyl chloride resins, vinylidene chloride resins and a styrene-butadiene copolymer, a styrene-butadiene-acrylonitrile copolymer and a ethylene-vinyl alcohol copolymer, for the metal foil may be mentioned an aluminum foil, a tin foil, an iron foil and a steel foil.

According to the present invention, a clamp can be made packaging which very effectively prevents the suction of air 'by using a plastic material which has a high gas tightness but is not suitable for the preparation of a conventional clamp packaging of this kind due to the relatively large elastic recovery; examples of such plastic materials are vinyl chloride resin, vinylidene chloride resin, high nitrile resin, poly- ester or polyamide.

Of course, a not completely gas-tight plastic can be used, such as olefin resin, which can be coated with a gas-tight plastic such as vinylidene chloride resin or can be laminated with a gas-tight plastic or a metal foil.

Fig. 8 shows a cross section through a laminate 12 forming the wall of the container 1. This laminate 12 comprises a gas dense layer 13 and inner and outer surface layers 14 and 15 produced of an olefin resin. The gas-tight layer 13 is laminated and bonded to the inner and outer surface layers 14 and 15 by bonding medium layer 16a and lobe. The gas-tight layer 13 may consist of a metal foil, such as an aluminum foil, or a gas-tight plastic such as vinylidene chloride resin.

In the case of the present invention the tubular the container 1 is made only of a plastic material, can as shown in Figs. 1 and 2, all parts of the container set by blowing a substance. The container 1 can naturally is produced in a manner as shown in Fig. 9 a cylindrical tube body 4 is produced by a laminate sheet 10 15 20 25 30 35 40 449 084 8 according to the mold is formed into a cylinder and that the cylinder 'mold overlapping edges heat bonding To form a straight line joint IF, with a tapered portion 5, a nozzle clamp suction 8 and a retaining member 10 are formed in one piece by injection molding. of a plastic material and wherein the cylindrical tube body than the open end is melt-welded at the tapered portion with by means of ultrasound or the like to form a peripheral fog 18.

Referring to Figs. 11A and IIB, another embodiment is shown. embodiment of the tubular container of the present invention invention, the neck is between the clamping opening 6 and the tapered one lot 5 divided into upper and lower parts of the lot is answered by the nozzle passage 8, and the upper part 9b has one even short cylindrical shape, with an external thread 9d for the lid is made on the lower part 9c.

Not only the shape shown in Fig. 4, but also a circular one shape shown in Fig. 10A, a star-like shape or any other form may be optionally assigned 8. As shown in Fig. 10C can also be inserted in the opening 6 of the container and an asterisk-shaped 8 can be formed in the bottom portion of the inner plug. IN shown in Fig. 10B nozzle passage an inner plug 19 nozzle passage this case opens a plurality of projections 20 in the clamping direction when the contents are clamped mes, and the squeezability is advantageously improved.

The invention will now be described in detail with reference to the following examples which are not intended to limit the invention scope of the application.

Example 1 and Comparative Example 1 A tomato paste was packed in a soft circular container of a laminate composed mainly of LD polyethylene and a oxygen-tight layer, which had a volume of S00 cms and whose transverse the average area at the opening of the residence part was 16 mmz, while the the length of the holding part was 12 mm and the cross-section of the nozzle passage surface was 4 mmz, whereby the container was repeatedly compressed for squeezing out the tomato paste. .

The tomato paste could be evenly squeezed without the container being returned. took the original condition until all the tomato paste was consumed.

The return force produced when the container is assembled was pressed and the pressing force ceased was at most 87 g. the viscosity of the paste was 35,000 cP at the time of use, measured with a Brookfield rotary viscometer. 10 15 20 25 30 Q 449 os4 Sdm comparison pucked a tomntpasta 1 en-re4ati§t¿ rigid circular container of a laminate composed mainly of polypropylene and an oxygen-tight layer, which had a volume of 500 cms and the same opening and nozzle dimensions as those at the container in Fig. 1. The container was repeatedly compressed for squeezing out the tomato paste. When the empty paste was once squeezed out and the clamping force ceased, the container regained the original the form. If the container is eating, the food patty was compressed out violently along with air sucked into the container when it regained its original shape, whereby an even squeezing could not be implemented. When the container is allowed to lie on worked several days after it had been used one several times, the tomato paste was discolored due to oxidizing ing. The greatest return force of the container was produced when it was compressed and the pressing force ceased was 350 g. the viscosity of the paste was 32,000 cP.

Examples 2 to 7 and Comparative Examples 2 to 5 The containers listed in Table 1 were also packed with them contents listed in Table 1 and tested in the same way as described in Example 1. The results obtained are shown in Table 1.

In the results column in Table 1, "good" means that the container did not regain its original shape within 30 seconds after squeezing out content and "bad" means that the container regained its original the mold within 30 seconds after squeezing out the contents, so that the contents and air were sucked in.

* T (g) of the container that the maximum value of the return force was developed when In Table 1, return means force the middle part of the container was compressed so that both walls stapled together and the pressing force ceased, which was measured with a Tensilone tester, and viscosity * (cP) means that the value was measured by means of a Brookfield viscometer at when the container was used. 449 084 ms æ fi cm if o fi wp wc æw .W qø Qm cw fi mwm fifl szmmmz wo: ÅMEEU woum «M @ p fl: w» m> æ om Hw fifl xn fl u ou fi w HN> W> N Uå fl åw U> fi m5H ¥ C fi <uwsaowcpm fi pw: wuw> Hom | Q4> m um: fi EmH.mEu Qom : wanna QN ou fl w |> Hon ~ »mn: w.» MH: x »fl u.mEu cow cwumxñom P- H m fl owmxmc: GA u »mn: w.um fi5 xx fi u.mEu oom m.N ou fl w Hm> m> ä ux fi xm wwcmuumwmcc fl: mum> Hom ¶ -nu> m uæc fl ëm fi pen ».mëu Qom . Hm> m> m ux fi xm mucmpuwwmcc fl w wmëpowcnm fi pm: ouw> Hom | mq> m wmc fi šm fi msu com vw hm fi sxw fl u cupmz fl omloq wwmncm .pwm fi m .wx _ w fi HoHxH »c«> »Hom w xm fl ßëon> m wnm fifi mawn w fl suomumk neu oo < m-m; @ fi poHx = @ w fi H> = H> > m ux fi xm www mncmppmmmcc fi: www mN pm fi sxh fl u |> Hom «Q4> w ~ mc fi EmH.nEu com cwuo> fi o @ | oQ __ Hmcommxw: pHmn: m.HmH: xæ «u ~ mEu oo ~ uwxuwuwcss wo: fi1 E & v wohm Epom «Wwu fi: mpm> e | wxu> umc: 2 oam fifi wswm ~ flfl wnmß E m fi maëwxø mwcmhowëww w Hmaamxo Q fi CNh®% EmW and Hmzemxo w fi cmæßmåmñ N Hwmæwxu øvcwHmmEww ß fl æañwxm 0 Hmaswxm lf? fi vnswxm w Hwmäwxm ff) Hmmsoxm Hmcsmxm ß) 449 084 Uw fififl w pm flfi æv ëw fififl w pw fifl mw 1 ppom »Wow puow uuow uuow ._ Qpow ooß Q oow ß ooo vw ooo m oow w oem __ ooo ow fi ooo wN ooo ßw oco cm uw fifl mw fifi wumwc fl c | v: m> cm v «> uo fifi mz | o :: «wo: fi muv N uwu «moxm«> .f mzcuumx mmccowmë EmhvñOv fi w mamow w fl smwx .wwcco fi mä wm fi xosu whwwxuzpu mxmx fififi p Emhx wmamwuocvno fi EWMÅOÅW HHmcm :: H ñw = fi = - mm-o «v P H fi mßmß No No ca » oo of No if? if if oø cmkmñ fl m fi mm wo: fi mv pwmpx _ * mucmH @ w »m ~ < ow ow O_ oN o ~ wc fi cmmm mcw fi ww «WHH«: ®mm: mo: fi eev wwpmg m Hwmeoxø wvcmhwwsmw w Hmnsmxo wwcmpmwëmn Q Hwmewxm @@ = m »@wEmw N fl mmewxw wøcmwmwëmw ß Hwmemxm Q Hwmsmxm m Hwnemxm w Hmmëmxm m fl mnëøxx N ~ @ QE®zm

Claims (3)

449,084 k Patent claims Clamp package consisting of a flexible, hollow container (1) of plastic and a viscous content (3) packed therein, the container comprising a flexible, cylindrical tube body (4), a tapered portion (5) connected to the tube body. ), a clamping opening (6) and a bottom joint (7), characterized in that the hollow container (1) is made in one piece by blow molding a blank of thermoplastic material, that between the tapered portion (5) and the clamping opening (6) is formed by engaging the corresponding part of the blank with a mold for reducing the diameter of the blank, a single, narrowed nozzle passage (8) and a retaining part (9) connected to the nozzle passage (8) via a ledge portion (9). 10) for the contents, that the contents have a viscosity of 1000 to 250,000 cP and that the dimensions of the container and the viscosity of the contents are within the ranges that meet the tear-off relationships represented by the requirements: log n 2 -log L - log S1 / S0 + 5.45, log n 2 0.588 log S0 + 0 , 764 log E + 2.30, and 20 2 S1 / S0 š 2 where n stands for viscosity of the contents (cP), SO stands for the cross-sectional area (mmz) of the nozzle passage (8), S1 stands for the cross-sectional area (mmz) of the holding part (10) , 2 stands for the length of the holding part (10) in the shaft direction and E stands for the elastic recovery (g) of the pipe body (4) in an unpackaged state. Clamp packaging according to claim 1, characterized in that the viscosity of the contents is 5000 to 150 000 cP. Clamp package according to claim 1, characterized in that the ratio S1 / S0 is in the range between 3 and 10.