EP3686125A1 - Pressure relief valve with floating membrane and packaging container - Google Patents

Abstract

Pressure relief valve of a packaging container, comprising: a base body (2) with an edge region (3) and with a sealing surface (4), the edge region (3) being sealingly connectable to a wall (10) of a packaging container (100), and in which Sealing surface (4) at least one through opening (51) is formed which extends through the base body (2), a first membrane (6) which is arranged above the through opening (51) and at least partially covers the sealing surface (4), one second membrane (7), which at least partially covers the first membrane (6), and a fluid (8), which is applied to the sealing surface (4) and by means of which the first membrane (6) is kept floating on the sealing surface (4) is.

Description

State of the art

The present invention relates to a pressure relief valve of a packaging container and a packaging container.

It is known to use pressure relief valves in packaging containers which are used for packaging a filling material. Gases generated inside the packaging can be discharged from the packaging container through the pressure relief valve. The necessity of such a possibility of gas escaping from the packaging container arises, for example, in the case of a filling material which also outgasses after packaging and can therefore produce an overpressure in the packaging container. Often, however, the ingress of air, in particular of the oxygen present in the air, must be avoided at the same time in order to maintain the quality of the filling material. A pressure relief valve used for this shows, for example, the EP 2 396 244 B1 .

Disclosure of the invention

The pressure relief valve of a packaging container according to the invention with the features of claim 1 offers the advantage of an improved sealing of the packaging container and an improved opening behavior. In particular, a change between the open and closed state of the pressure relief valve is optimized. The pressure relief valve according to the invention closes earlier after an equalization of pressures inside and outside the packaging container, that is to say after an overpressure in the packaging container has been reduced by gas escaping from the packaging container into the environment. In addition, air is prevented from entering the packaging container more reliably. This is achieved according to the invention in that the pressure relief valve comprises a base body with an edge region and with a sealing surface, the sealing surface surrounding at least one through opening which extends through the base body. The through opening is preferably formed in the sealing surface. The edge area can be sealingly connected to a wall of the packaging container. The edge region, which in particular surrounds the sealing surface in a ring shape, can advantageously be connected to an inside of the wall of the packaging container, so that the pressure relief valve is arranged inside the packaging container. The connection between the edge area and the wall can be created in a variety of ways. For example, the pressure relief valve at the edge area can be sealed to the wall of the packaging container by means of an ultrasound connection. Alternatively, an adhesive connection would also be possible.

Furthermore, the pressure relief valve comprises a first membrane, which is arranged above the through opening and at least partially covers the sealing surface. In addition, the pressure relief valve comprises a second membrane, which at least partially covers the first membrane. Furthermore, a fluid is provided, which is arranged on the sealing surface, so that the fluid is arranged between the sealing surface and the first membrane. By means of the fluid, the first membrane is held floating on the sealing surface and in particular the second membrane is also held floating on the first membrane. A silicone oil or a similar fluid, which is suitable as a sealing liquid, is preferably provided as the fluid. The fluid thus causes the first membrane and the second membrane to move laterally on the sealing surface and within the edge region.

The sealing effect of the pressure relief valve is achieved by the interaction of the sealing surface, the first membrane, the second membrane and the fluid. The fluid causes an adhesion, whereby the first membrane adheres to the sealing surface and thus seals the passage opening. The capillary effect also ensures that the fluid is evenly distributed between the sealing surface and the first membrane. Because the through opening is also a very small one Cross-section, preferably in the range of a few tenths of a millimeter, in particular less than 0.5 mm, the capillary effect also prevents the fluid from flowing out through the passage opening.

If there is an overpressure in the packaging container in relation to the environment, for example caused by outgassing of a packaged product, a gas channel is formed in the fluid, which extends from the through opening through the fluid and slightly raises the first membrane. The gas can flow out to the environment through this gas channel, which brings about a pressure equalization. As soon as the pressure difference between the packaging container and the environment falls below a certain value again, the adhesive force of the fluid pulls the first membrane towards the sealing surface again and the gas channel is closed, so that the pressure relief valve closes again.

Because the pressure relief valve according to the invention comprises a plurality of membranes, a particularly good sealing effect and an optimized response of the pressure relief valve when opening and closing are achieved. The floating arrangement of the first membrane has a particularly favorable effect on the response of the pressure relief valve to pressure changes. The second membrane also has a favorable effect on the sealing effect and ensures particularly low oxygen diffusion through the pressure relief valve. In particular, the first membrane and the second membrane are formed from a flexible material. This interaction of the first membrane and the second membrane is particularly advantageous, since the arrangement according to the invention in the pressure relief valve means that the first membrane and the second membrane also have a certain mobility relative to one another. In addition, the first membrane and the second membrane can be dimensioned differently, for example with regard to their thicknesses. As a result, the first membrane and the second membrane can each be optimally adapted to the corresponding requirements with regard to the opening and closing behavior with certain pressure differences via the pressure relief valve for different purposes.

The subclaims relate to preferred developments of the invention.

The fluid is preferably arranged completely between the first membrane and the sealing surface and between the first membrane and the second membrane. The capillary effect distributes the fluid evenly between these elements. This results in a particularly favorable floating arrangement of the first membrane, which has a particularly advantageous effect on the sealing effect of the pressure relief valve. The fluid brings about an adhesion between the first membrane and the sealing surface as well as between the first membrane and the second membrane.

It is particularly favorable if a first outer dimension of the first membrane is smaller than or equal to a second outer dimension of the second membrane. The first outer dimension and the second outer dimension are each considered in a plane parallel to the sealing surface. The first outer dimension is preferably between 5% and 10% smaller than the second outer dimension. It is particularly advantageous if the two membranes each have circular cross sections in the plane parallel to the sealing surface, as a result of which the first outer dimension is a first diameter and the second outer dimension is a second diameter. Such a design of the first membrane with the same or smaller first outer dimension compared to the second membrane favors a uniform distribution of the fluid between the two membranes and between the first membrane and the sealing surface due to the capillary effect. This also favors the adhesive force that the fluid between the sealing surface and the first membrane and between the first membrane and the second membrane causes, which consequently tells a particularly good sealing effect of the pressure relief valve.

The first outer dimension of the first membrane and a position of the at least one through opening in the sealing surface are particularly preferably matched to one another such that the first membrane completely covers the at least one through opening. The through-opening remains covered by the first membrane even with maximum lateral displacement of the first membrane on the sealing surface and within the base body. If several through openings are formed in the sealing surface, each of these through openings is always covered by the first membrane.

This means that a minimum first outer dimension and / or the positions of the through openings are selected such that the through openings remain covered by the first membrane even with maximum lateral displacement. The maximum lateral displacement means that the first membrane is displaced on the sealing surface so far that the first membrane touches the edge area. This ensures that the pressure relief valve functions safely and reliably at all times.

It is furthermore advantageous if a thickness ratio of a first thickness of the first membrane to a second thickness of the second membrane is between 1: 1 and 1:10. The thickness ratio is preferably between 1: 2 and 1: 6. The thickness ratio is particularly preferably 1: 4, that is to say that the second membrane is advantageously four times as thick as the first membrane. Thus, the first membrane can be designed to be particularly flexible in order to ensure a sensitive response of the pressure relief valve even at low overpressures. In addition, the second membrane can be designed to be more rigid in order to guarantee a good seal from the environment and sufficient stability of the arrangement and thus to ensure the functional reliability of the pressure relief valve.

A ratio of a fluid volume of the fluid to an inner volume of the base body is preferably at least 3: 100. This ratio is preferably at least 5: 100 and particularly preferably at most 3:10. The total volume enclosed by the base body is considered to be the inner volume of the base body. In the event that the edge area of the base body is sealed to the inside of the wall of the packaging container, the internal volume is limited by the sealing surface, edge area and inside of the wall. This ensures that an optimal fluid volume is available in relation to the base body, which is ultimately primarily responsible for the adhesion of the first membrane to the sealing surface and thus for the sealing effect of the pressure relief valve due to the adhesive forces.

Furthermore, it is advantageous if two through openings are formed in the base body. The two through openings are eccentric and symmetrical to one another with respect to a central axis of the base body arranged. As a result, the opening and closing behavior of the pressure relief valve can be further improved. The eccentric arrangement of the through openings means that they are closer to the edges of the membranes. Thus, the outflowing gas has to cover a smaller distance through the fluid when an overpressure in the packaging container is equalized. The resistance to opening the valve is thus even lower. In addition, the reclosure is also improved, since when the pressure relief valve is open only a small part of the first membrane, namely above all the corresponding edge areas of the first membrane, is deformed radially outside the through openings and is lifted off the sealing surface. This means that only this area has to be reshaped in order to securely close again.

The first membrane and the second membrane are particularly preferably each formed as circular film disks. This means that the first membrane and the second membrane have a circular cross section, each of which is made very thin in order to have a film-like character. It is particularly favorable if the first membrane and the second membrane are each formed from a plastic. As a result, the two membranes can be produced particularly simply and inexpensively.

The first membrane preferably has greater flexibility than the second membrane. As a result, the first membrane is easier to deform and, for example, partial regions of the first membrane can be lifted off the sealing surface more easily in order to form the gas channel. The second membrane can be made more rigid than the first membrane in order to exert a certain restoring force on the first membrane, as a result of which the pressure relief valve closes again particularly quickly and reliably after pressure equalization between the packaging container and the surroundings

It is also advantageous if the base body has a round cross-sectional shape. In particular, the sealing surface has a circular cross section. Thus, the pressure relief valve is easy and inexpensive to manufacture and a uniform distribution of the fluid is promoted by the capillary effect.

The pressure relief valve preferably further comprises at least one third membrane. The third membrane is arranged between the first membrane and the second membrane. As a result, the mobility of the membrane arrangement can be increased further in order to further optimize the opening and closing behavior of the pressure relief valve.

The base body is preferably an injection molded part. The base body is particularly preferably formed from a plastic. The base body is thus particularly simple and inexpensive to produce, the geometry of the base body being simple and flexible.

The invention further relates to a packaging container which comprises at least one pressure relief valve according to the invention. The packaging container can be used, for example, for packaging food. It is particularly favorable if the packaging container is an aroma protective packaging for coffee. The packaging container with the pressure relief valve according to the invention enables products such as coffee to be packed in an airtight manner, wherein an overpressure which arises in the interior of the packaging container due to outgassing of the products can be reliably compensated for by the pressure relief valve. In particular, oxygen is reliably prevented from entering the closed packaging container by the pressure relief valve.

Brief description of the drawings

Figur 1

eine vereinfachte schematische Schnittansicht eines Überdruckventils gemäß einem ersten Ausführungsbeispiel der Erfindung,

Figur 2

eine Draufsicht des Überdruckventils der Figur 1,

Figur 3

eine vereinfachte schematische Schnittansicht eines Überdruckventils gemäß einem zweiten Ausführungsbeispiel der Erfindung, und

Figur 4

eine vereinfachte schematische Schnittansicht eines Überdruckventils gemäß einem dritten Ausführungsbeispiel der Erfindung.

The invention is described below on the basis of exemplary embodiments in conjunction with the figures. In the figures, functionally identical components are identified by the same reference numerals. It shows:

Figure 1

1 shows a simplified schematic sectional view of a pressure relief valve according to a first exemplary embodiment of the invention,

Figure 2

a plan view of the pressure relief valve of the Figure 1 ,

Figure 3

a simplified schematic sectional view of a pressure relief valve according to a second embodiment of the invention, and

Figure 4

a simplified schematic sectional view of a pressure relief valve according to a third embodiment of the invention.

Preferred embodiments of the invention

The Figure 1 shows a simplified schematic sectional view of a pressure relief valve 1 according to a first embodiment of the invention. The pressure relief valve 1 is connected to a wall 10 of a closed packaging container 100, only a small section of this wall 10 being shown. The pressure relief valve 1 is attached to a side 11 of the wall 10 facing an interior I of the packaging container 100.

The packaging container 100 can be used for packaging filling goods, such as all kinds of foods. For example, such a packaging container 100 is suitable as aroma protection packaging for coffee. The pressure relief valve 1 according to the invention ensures that gases can escape from the interior I of the packaging container 100 to an environment U, in the reverse direction preventing air from entering the interior I of the packaging container 100 through the pressure relief valve 1. Such a sealing of the packaging container 100 with the simultaneous possibility of compensating an overpressure is particularly advantageously possible by the overpressure valve 1.

In order to allow gases to escape from the interior I of the packaging container 100 to the environment U, two holes 12, 13 are formed in the wall 10 of the packaging container 100, each of which extends through the wall 10.

The pressure relief valve 1 comprises a base body 2, a first membrane 6 and a second membrane 7. The base body 2 is cup-shaped and essentially concentric to a central axis 21.

The base body 2 has a disk-shaped sealing region 20, which is adjoined by an annular edge region 3. At an end opposite the sealing area 20, the edge area 3 is connected to the wall 10 of the packaging container 100. The connection between edge area 3 and wall 10 is an ultrasound connection. An inner volume V of the base body 2 is thus enclosed by the base body 2 and wall 10 of the packaging container 100.

A surface of the sealing area 20 facing the inner volume V forms a sealing surface 4 of the pressure relief valve 1. The sealing surface 4 is a flat surface. In the sealing surface 4, two through openings 51, 52 are formed, each of which extends through the sealing region 20 of the base body 2. The two through openings 51, 52 are formed eccentrically and symmetrically to the central axis 21 of the base body 2, as in FIG Figure 2 to see.

The first membrane 6 is arranged on the base body 2 such that it partially covers the sealing surface 4. The first membrane 6 is arranged above the two through openings 51, 52 and covers them. The second membrane 7 is arranged so that it covers the first membrane 6.

Furthermore, a fluid 8, which here is a silicone oil, is applied to the sealing surface 4. The fluid 8 is also arranged between the first membrane 6 and the second membrane 7. By means of the fluid 8, the first membrane 6 and the second membrane 7 are held floating on the sealing surface 4 in order to bring about the sealing effect of the pressure relief valve 1. Due to the capillary effect, the fluid 8 is evenly distributed between the first membrane 6 and the second membrane 7. By means of adhesion between the sealing surface 4 and the first membrane 6, the fluid 8 ensures that the first membrane 6 is held on the sealing surface 4 by means of an adhesive force and thereby brings about the sealing, that is to say penetration of air from the environment U into the interior I of the Packaging container 100 prevented.

The fluid 8 also brings about a floating arrangement of the two membranes 6, 7 on the sealing surface 4. That is, the first membrane 6 and the second membrane 7 are arranged movably on the sealing surface 4 in the lateral direction of the center axis 21. Thus, the two membranes 6, 7 together with the fluid 8 form a movable sealing arrangement, which enables a quick and reliable response when changing between opening and closing the pressure relief valve 1.

If an overpressure occurs in the interior I of the packaging container 100 as a result of outgassing of packaged products, gas can flow out to the environment U through the pressure relief valve 1. For this purpose, a gas channel is formed in the pressure relief valve 1, which extends from one or both of the through openings through the fluid 8 and in the process slightly raises the first membrane 6 at its edge from the sealing surface 4. The gas can flow out to the surroundings U through this gas channel and through the holes 12, 13, as a result of which pressure equalization is brought about.

As soon as the pressure is sufficiently balanced, the gas channel is closed again by the fluid 8 and the first membrane 6 is pulled back towards the sealing surface 4 by the adhesive force of the fluid 8, so that the pressure relief valve 1 seals again. The second membrane 7 additionally supports this reclosing. In particular, the second membrane 7 causes a certain pre-tension, which favors a return of the first membrane 6 back to its starting position. In addition, the capillary effect has the effect that the fluid 8 is distributed evenly around the first membrane 6, so further favors that the first membrane 6 deforms back into its original shape.

Furthermore, the first membrane 6 and the second membrane 7 are each designed as circular film disks, as in particular also in FIG Figure 2 to recognize. The Figure 2 shows a top view of the pressure relief valve 1 of FIG Figure 1 , the packaging container is not shown. Like in the Figure 2 can be seen, the first membrane 6, the second membrane 7 and the base body 2 are each formed with a circular cross section and, in Unshifted state shown here, arranged concentrically to each other.

A first diameter D1 of the first membrane 6 is 5% smaller than a second diameter D2 of the second membrane 7. The second diameter D2 is also 10% smaller than an inner diameter D3 of the edge region 3 of the base body 2. The inner diameter D3 therefore also corresponds to one Outer diameter of the sealing surface 4. Due to the smaller first diameter D1 compared to the second diameter D2, the fluid 8 can be distributed particularly easily between the first membrane 6 and the second membrane 7 due to the capillary effect, since the fluid 8 easily around an edge of the first Membrane 6 can flow. The first membrane 6 also has a first thickness B1, which is equal to a second thickness B2 of the second membrane 7.

For optimal functioning of the pressure relief valve 1, the first diameter D1 and the positions of the two through openings 51, 52 are matched to one another such that the first diaphragm 6 still completely covers both through openings 51, 52 even with maximum lateral displacement on the sealing surface 4. That is, even if the first membrane 6 is shifted so far in the lateral direction A that it lies against the edge region 3, each of the through openings 51, 52 is still completely covered by the first membrane 6.

A fluid volume of the fluid 8 is in a ratio of 3: 100 to the inner volume V of the base body 2. This ensures that a sufficient fluid volume is available to finally adhere the first membrane 6 to the sealing surface 4 and thus by means of the adhesive force to achieve the sealing effect. In addition, this ratio also ensures that there is no unnecessary fluid volume, which could have a negative effect on a targeted, reliable adhesion of the first membrane 6 on the sealing surface 4 and the second membrane 7 on the first membrane 6.

The Figure 3 shows a simplified schematic sectional view of a pressure relief valve 1 according to a second embodiment of the invention.

The second exemplary embodiment essentially corresponds to the first exemplary embodiment in FIGS Figures 1 and 2 wherein the two membranes 6 ', 7' have different proportions relative to each other.

In the second embodiment in the Figure 3 the first diameter D1 'of the first membrane 6' and the second diameter D2 'of the second membrane 7' are identical. Furthermore, the second thickness B2 'of the second membrane 7' in the second exemplary embodiment is four times as large as the first thickness B1 'of the first membrane 6'. In other words, the thickness ratio of the first membrane 6 'to the second membrane 7' is 1: 4. As a result, the second membrane 7 'is significantly more rigid than the first membrane 6' and a more stable arrangement of the two membranes 6 ', 7' can be achieved. It can thereby be achieved that the pressure relief valve 1 opens later in comparison to the first exemplary embodiment, that is to say at a higher pressure in the interior I compared to the environment U, since a greater resistance has to be overcome until the first membrane 6 ′ lifts off the sealing surface 4 . In addition, the pressure relief valve 1 closes even faster, since the second membrane 7 'causes a higher restoring force.

The Figure 4 shows a simplified schematic sectional view of a pressure relief valve 1 according to a third embodiment of the invention. The third exemplary embodiment essentially corresponds to the first exemplary embodiment in FIGS Figures 1 and 2 a third membrane 9 is additionally provided, which is arranged between the first membrane 6 and the second membrane 7. The third membrane 9 has a third diameter D4, which is equal to the first diameter D1 of the first membrane 6. Due to the capillary effect, the fluid 8 is evenly distributed between all three membranes 6, 7, 9 and between the first membrane 6 and the sealing surface 4. The third membrane 9 further promotes the mobility of the floating membrane arrangement and thus ensures a further optimized sealing effect of the pressure relief valve 1, in particular with regard to opening and closing for or after the compensation of an overpressure in the interior I of the packaging container 100.

Claims (13)

Pressure relief valve of a packaging container, comprising: - A base body (2) with an edge area (3) and with a sealing surface (4), the edge area (3) being sealingly connectable to a wall (10) of a packaging container (100), and wherein the sealing surface (4) has at least one Surrounds through opening (51) which extends through the base body (2), a first membrane (6) which is arranged above the through opening (51) and at least partially covers the sealing surface (4), - A second membrane (7) which at least partially covers the first membrane (6), and - A fluid (8) which is applied to the sealing surface (4), the fluid (8) being arranged between the sealing surface and the first membrane (6). Pressure relief valve according to claim 1, wherein the fluid (8) is arranged completely between the first membrane (6) and the sealing surface (4) and between the first membrane (6) and the second membrane (7). Pressure relief valve according to one of the preceding claims, wherein the first membrane (6) has a first outer dimension (D1) in a plane parallel to the sealing surface (4), the second membrane (7) having a second outer dimension (D2) in a plane parallel to the sealing surface (4), and wherein the first outer dimension (D1) is less than or equal to the second outer dimension (D2). Pressure relief valve according to claim 3, wherein the first outer dimension (D1) and a position of the at least one through opening (51) in the sealing surface (4) are coordinated with one another such that the first membrane (6) completely covers the at least one through opening (51), with any lateral displacement of the first membrane (6) on the sealing surface (4). Pressure relief valve according to one of the preceding claims, wherein a thickness ratio of a first thickness (B1) of the first membrane (6) to one second thickness (B2) of the second membrane (7) is between 1: 1 and 1:10, in particular between 1: 2 and 1: 6, particularly preferably 1: 4. Pressure relief valve according to one of the preceding claims, wherein a ratio of a fluid volume of the fluid to an internal volume (V) of the base body (2) is at least 3: 100, in particular at least 5: 100, and preferably at most 3:10. Pressure relief valve according to one of the preceding claims, wherein two through openings (51, 52) are formed in the base body (2), and wherein the two through openings (51, 52) are arranged eccentrically and symmetrically with respect to a central axis (21) of the base body (2) . Pressure relief valve according to one of the preceding claims, wherein the first membrane (6) and the second membrane (7) are each designed as circular film disks. Pressure relief valve according to one of the preceding claims, wherein the first membrane (6) has a greater flexibility than that of the second membrane (7). Pressure relief valve according to one of the preceding claims, wherein the base body (2) has a round cross-sectional shape. Pressure relief valve according to one of the preceding claims, comprising at least a third membrane (9) which is arranged between the first membrane (6) and the second membrane (7). Pressure relief valve according to one of the preceding claims, wherein the base body (2) is an injection molded part and is in particular formed from plastic. Packaging container comprising at least one pressure relief valve (1) according to one of the preceding claims.

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