BRPI0901049B1 - sealing gasket for a refrigerator door and sealing system - Google Patents

Abstract

SEALING GASKET FOR THE DOOR OF A REFRIGERATOR AND SEALING SYSTEM. The present invention relates to a sealing system for a refrigerator door and, more specifically, a sealing system of the type comprising a gasket to be inserted into a receiving channel (60) disposed in the refrigerator door. The sealing gasket of the present invention comprises an engagement part (40) connected to a sealing pouch (50), the engagement part (40) comprising an end portion (41) having a substantially triangular profile and a body portion (42) having a W-shaped cross section with curved walls (45, 46). The end portion (41) is formed by two symmetrically opposed flaps (43, 44), each flap (43.44) at an angle to each of the curved walls.

Description

Field of the Invention

The present invention relates to a sealing system for the door of a refrigerator and, more specifically, a sealing system of the type comprising a gasket to be inserted into a receiving channel arranged on the refrigerator door. .

Fundamentals of the Invention

Sealing the refrigerator compartment door of a refrigerator or freezer is essential to ensure adequate and efficient cooling. The entry of hot air into the generated refrigerated compartment and the exit of cold air from it impact efficiency in maintaining refrigeration, energy consumption (excessive activation of the compressor), and can also cause water to form inside and outside the compartment. due to the phenomenon of condensation or the undesirable formation of ice.

The gasket also has the important function of absorbing variations due to the dimensions of the refrigerator door and cabinet and as a result of the cabinet doorway. In fact, the gasket must be flexible enough to accommodate (or absorb) these variations in dimension, but it must be robust enough not to deform excessively in the face of tensile forces.

The most commonly used way to seal the refrigerator door is by means of a magnetic gasket. This gasket generally comprises a coupling part and a sealing pouch housing a magnet. The coupling part is received in a receiving channel arranged in an internal peripheral portion of the refrigerator door, and the magnet is housed in the sealing pouch that contacts a metallic flange of the refrigerator body to ensure the proper sealing of the door.

Although gaskets with these general characteristics are known, the design and construction characteristics of this type of gasket still represent a major technical challenge, since the properties achieved by a specific gasket design directly influence its sealing capacity and its useful life .

In this sense, three main properties of a gasket can be highlighted: its resistance to traction, its resistance to compression and its resistance to torsion.

When the refrigerator door is moved, for example, during the closing or opening of the door, the gasket, which is usually made of polymeric material, is “stretched” (opening) and “compressed” (closing). deformation of the gasket during these operations directly impacts its sealing capacity and its useful life.

In addition, since the sealing pouch houses a magnet, it is important that the sealing pouch supports the weight of that magnet, ensuring that it will contact the refrigerator flange in the correct position. Thus, it is desirable that the assembly undergoes little torsion when moving the door.

Description of the Prior Art

In view of the desired properties for the gasket, several different constructions and geometries have been proposed for a gasket. Such constructions are known, for example, from PI9913633-3, US 6,227,634, US 6,526,698, US 2004/0244297, US 2006/0188690 and PI0503971-1.

PI 9913633-3 describes a gasket whose coupling portion comprises at least three retaining shoulders, one of which has, in relation to a vertical, a more obtuse intermediate angle than the other two shoulders.

US 6, 227, 634 describes a gasket developed to better resist the forces of compression and traction that act on it when the door is displaced. The solution proposed in this document consists of the use of two different materials for making part of the sealing pouch.

US 6,526,698 describes a sealing system for the refrigerator-generator door, where the receiving channel of the coupling portion of the gasket has an asymmetrical profile, in order to facilitate the assembly of the gasket.

US 2004/0244297 describes profiles for a gasket sealing bag. According to this document, an additional flap is provided in the bag that transmits magnetic tension force from the region of the magnet to the region of the coupling part of the gasket.

US 2006/0188690 describes a gasket made from a specific material, which would have better extrusion properties.

Finally, PI 0503971-1 describes a gasket having a coupling part with a curvilinear profile and a sealing pouch subdivided into a side sealing bag, an intermediate sealing bag, a main sealing bag, three secondary sealing bags, and a magnet compartment.

Although the documents listed represent efforts to achieve an efficient sealing gasket construction with a long service life, the search remains for a solution that combines cost efficiency and ease of manufacture with a gasket with good resistance and variation absorption properties tensile strength, compressive strength and torsion strength.

Objectives of the Invention

In view of the above, it is an object of the present invention to provide a sealing system for a refrigerator door that provides an efficient seal, but which maintains an acceptable cost of manufacture.

It is another objective of the present invention to provide a low cost sealing gasket with good properties of variation absorption and tensile strength, compressive strength and torsional strength.

It is another objective of the present invention to provide a sealing gasket with a long service life, which presents little deformation when subjected to compression and traction efforts.

Summary of the Invention

The present invention achieves the above objectives by means of a sealing gasket for a refrigerator door comprising an engagement part connected to a sealing pouch. The engagement part comprises an end portion having a substantially triangular profile and a body portion having a W-shaped cross section with curved walls, the end portion being formed by two flaps, each flap at an angle with each of the curved walls.

In a preferred embodiment of the present invention, the sealing pouch comprises a base part for the engagement part, a body part in the form of a pillar, and a contact part that contacts at least part of a refrigerator cabinet . In that embodiment, the base part comprises a base wall which extends substantially parallel to the refrigerator door, the pillar-shaped body part comprises two side walls and a reinforcing structure, and the contact part comprises a part of magnet receiving and an end portion.

In one embodiment of the invention, the reinforcing structure comprises a lattice-shaped lattice structure, with one of the larger sides defined by a part of the base wall and one of the smaller sides defined by a part of the wall. In this embodiment, the second smaller side of the parallelogram starts at a support part of the base wall, the support part coinciding with the base wall part that joins with one of the curved walls of the body part of the coupling portion .

In the preferred embodiment of the present invention, the magnet receiving part is displaced with respect to the end of the outer flange of the refrigerator cabinet, towards the outside of the cabinet.

The present invention further contemplates a sealing system comprising the sealing gasket of the present invention, and a receiving channel comprising: a triangle-shaped part defined by two side walls which are at one apex end, and an opening part that receives a gasket hitch part.

Brief Description of Drawings

The figures show:

Figure 1 - Figure 1 illustrates a sectional view of a sealing gasket known from the prior art.

Figure 2 - Figure 2 illustrates the result of a simulation test representing the incidence of stress resulting from the compression of a gasket in the prior art.

Figure 3 - Figure 3 illustrates the result of a simulation test representing the deformation suffered by a gasket in the prior art during its compression.

Figure 4 - Figure 4 illustrates the result of a simulation test representing the deformation suffered by a gasket in the prior art when subjected to tensile forces.

Figure 5 - Figure 5 illustrates the result of a simulation test representing the deformation suffered by a prior art gasket when subjected to torsional forces.

Figure 6 - Figure 6 shows a sectional view of a first embodiment of the gasket of the present invention.

Figure 7 - Figure 7 shows a detailed sectional view of the engagement part of a first embodiment of the gasket of the present invention.

Figure 8 - Figure 8 shows a detailed sectional view of the engagement part and the receiving channel of a first embodiment of the sealing system of the present invention.

Figure 9 - Figure 9 illustrates the result of a simulation test representing the incidence of stress resulting from the extraction of the gasket of the present invention.

Figure 10 - Figure 10 illustrates the result of a simulation test representing the incidence of stress resulting from the insertion of the gasket of the present invention.

Figure 11 - Figure 11 illustrates a sectional view of a first embodiment of the gasket of the present invention.

Figure 12 - Figure 12 illustrates a schematic view of the gasket of the present invention when contacting the flange of a refrigerator cabinet.

Figure 13 - Figure 13 illustrates the result of a simulation test representing the incidence of stress resulting from the compression of the first gasket embodiment of the present invention.

Figure 14 - Figure 14 illustrates the result of a simulation test representing the deformation suffered by the gasket of the present invention during its compression.

Figure 15 - Figure 15 illustrates the result of a simulation test representing the deformation suffered by the gasket of the present invention when subjected to tensile forces.

Figure 16 - Figure 16 illustrates the result of a simulation test representing the deformation suffered by the gasket of the present invention when subjected to torsional forces.

Figure 17 - Figure 17 illustrates a sectional view of a second embodiment of the gasket of the present invention.

Figure 18 - Figure 18 shows a detailed cross-sectional view of the engagement part and the receiving channel of a second embodiment of the sealing system of the present invention.

Detailed Description of the Invention

The present invention will now be described in more detail on the basis of the execution examples shown in the drawings.

Figure 1 shows a gasket known in the art. The gasket 1 has an engaging portion 10 and a sealing pouch 20.

The engagement portion 10 has an arcuate end profile 11 and two shoulders 12 protruding from its side walls. Thus, when fixing the gasket to the door, the coupling potion 10 is inserted into a reception channel of circular or square shape, symmetrical or asymmetrical (see documents of the prior art, such as, for example, PI 9913633-3 or document PI0503971-1).

The sealing pouch 20 of the prior art gasket is formed by a base part 21 for the engagement portion 10, two side walls 22, an extreme part 23 and a magnet receiving part 24. The side walls 22, and part the walls of the extreme part 23 and the magnet receiving part 24 defining a hollow space 25.

In the commonly used gasket, the coupling portion has a total length of about 9.4 mm (from the plane that touches the end of the arc to the plane that touches the base part 21), and the sealing bag has a total length of about 14.4 mmm (from the plane that touches the base part 21 to the plane that touches the upper wall of the magnet receiving part 24).

The magnet receiving part 24 of the gasket known from the prior art generally has a rectangular profile, about 11.5 mm wide and 3.2 mm long, and the extreme part 23 has an asymmetric profile, the bottom wall about 11.5 mm wide and the sloping top wall starting at 5.6 mm from the bottom wall and ending at 7.1 mm high from the bottom wall (it should be noted, however, that the dimension of the extreme part 23 may vary depending on the product). One of the side walls of the extreme part 23 coincides with the side wall of the magnet receiving part 24 and the other of the side walls is substantially arc-shaped.

The side walls 22 are about 1 mm thick and each form a projecting flap 26, 27. The function of these flaps will be more clearly evident based on the description in figures 2 to 5, which illustrate the behavior of a gasket of the prior art in the face of compression, traction and torsion forces.

The base portion 21 of the engagement part 10 has a split profile in the form of an inverted V, the engagement portion being supported on one of the legs of the inverted V. The part of the base wall that supports the engagement portion is about 1 mm thick and the second leg is about 1.4 mm thick.

It should be emphasized that the dimensions of the gasket, as well as the details of construction and measurements of the walls that form the sealing pouch 20, have an important impact on the efficiency of the gasket, since they influence its behavior in relation to the forces of compression, traction torsion that the gasket suffers during the displacement of the door.

Figures 2 to 5 illustrate the behavior of a prior art gasket in relation to the forces of compression, traction and torsion. It should be noted that the prior art gasket shown in figures 2 to 5 differs somewhat from that shown in figure 1, with the gasket engagement portion shown in figures 2 to 5 showing four shoulders.

Figures 2 and 3 illustrate the behavior of the gasket when subjected to a compressive force: figure 2 illustrates the forces acting on the gasket and figure 3 illustrates the deformation of the gasket parts (in mm).

Figure 4 illustrates the gasket behavior when subjected to a tractive force, showing the deformation of the gasket parts (in mm).

Figure 5 illustrates the behavior of the gasket with respect to torsion due to the magnetic inertia and weight of the magnet.

Although the prior art gaskets illustrated in figures 1 to 5 are capable of providing some resistance to the forces of compression, traction and torsion, the gasket of the present invention was developed in order to provide even greater levels of resistance, being more resistant to deformation and , thus, able to maintain its sealing capacity more efficiently and durably.

Figure 6 shows a sectional view of a preferred embodiment of the gasket of the present invention. The gasket 30 comprises an engagement part 40 and a sealing pouch 50.

As best illustrated in Figure 7, the engagement part 40 has an end portion 41 with a substantially triangular profile and a body portion 42 whose cross section has a W-shape with curved walls. As known to those skilled in the art, the engagement part 40 is received by a receiving channel disposed on the inner periphery of the refrigerator door. Figure 8 shows details of the insertion of the engagement part 40 in a receiving channel 60 of a refrigerator door (not shown).

The geometry of the engagement portion 40 and the receiving channel 60 of the present invention has been developed in order to provide a more efficient fit between the parts, facilitating the engagement, and achieving greater retention force after engagement. Thus, the geometric solution proposed by the sealing system of the present invention provides a safer fixation of the sealing gasket to the door, allowing the sealing to remain in place even after successive and constant door shifts.

The end portion 41 is formed by two symmetrically opposite flaps 43, 44 that delimit the triangular shape, forming two of the walls of an isosceles triangle.

As shown in figures 6 to 8, the body portion 42 of the engagement part 40 has a substantially W-shaped cross section, but with curved walls. Thus, the two side walls 45, 46 are curved out of the engagement part, while the cross wall 47 is curved towards the interior of the W.

In the preferred embodiment of the gasket of the present invention, the total length of the engagement part (from the plane that touches the apex of the end portion 41 to the plane that touches the end of the domed walls 45, 46) is 9.1 mm, the largest width of the end portion 41 (measured between the free ends of the flaps 43 and 44) is 8.4 mm, and the largest width of the body portion 42 (measured in the outermost region of the walls 45, 46) is 5.6 mm.

Still in the preferred embodiment, the distance between the free ends of the flaps 43, 44 and the end of the walls 45, 46 is 4, 15mm.

Each flap 43, 44 makes an angle of about 41.9 ° with each side wall 45, 46. This angle, together with the length of the flaps, makes the gasket extraction and insertion functions in the door receiving channel of the refrigerator behave better than the gaskets known in the art

Accordingly, at the junction of the flaps 43, 44 with the body part 42 there is a strain relief cover 49, whose diameter, in a preferred embodiment is about 0.7 mm. This opening allows greater flexibility of the flaps 43 and 44, facilitating the gasket insertion function.

In the preferred embodiment, each flap 43, 44 is about 4.9 mm long and about 0.8 mm thick in its thinnest portion.

It should be emphasized, however, that these dimensions can be varied within the geometry proposed by the present solution, with a variation of about 10% in this dimension continuing to achieve the benefits brought by the proposed geometry.

The engagement part 40 also has an elongated drop-shaped opening 48, which extends from the transverse wall 47 to the apex formed at the junction of the flaps 43, 44.

In a preferred embodiment, the elongated opening 48 has, in its widest portion, a thickness of about 1.6 mm.

Although the engagement part 40 has been defined as comprising distinct parts and walls, it should be understood that that part is preferably made of a continuous piece.

The geometry of the receiving channel 60 of the present invention also influences the advantageous insertion and retention characteristics obtained with the present invention.

The channel 60 has a shape corresponding to that of the coupling part 40, comprising a triangle-shaped part 62 defined by two side walls 63, 64 which are at an apex end 65, and an opening part 66. The walls 63, 64 meet opening part 66 in a curved wall with a radius internal to the 2.10 mm channel (this curved wall having an extension of about 5.86 mm), and the wall forming the opening part 66 joins with the rest of the channel body by a curved wall with a radius of 1mm (this curved wall having an extension of about 1.91mm).

In the preferred embodiment of the present invention, the opening 66 of the channel has a length of 5.5 mm. It should be noted, however, that this dimension can be varied within the geometry proposed by the present solution, with a variation of about 30% in this dimension continuing to achieve the benefits brought by the proposed geometry.

Figures 9 and 10 illustrate test results that prove the efficiency of the setting of the sealing system of the present invention. Thus, figure 9 shows the result of a simulation test representing the stress incidence resulting from the extraction of the gasket of the present invention, and figure 10 shows the result of a simulation test representing the stress incidence resulting from the insertion of the gasket of the present invention.

The gasket of the present invention further comprises a sealing pouch 50. The sealing pouch 50 comprises a base part 51 for the engagement part 40, a body part 52 configured in the form of a pillar, a contact part 53 which contacts the refrigerator cabinet when the door is closed.

The base part 51 basically comprises a base wall 51 which closes the "W" formed by the body portion 42 of the engaging part 40 and extends the entire length of the body part 52 of the pocket 50. In the preferred embodiment illustrated in figures 6 to 14, the base wall 51 remains substantially parallel to the refrigerator door.

The body part 52 of the pouch 50 comprises two side walls 54, 55. When in the resting configuration (where the gasket does not suffer compression and traction forces), one of the walls 54 comprises a half arrowhead shape conferred by a first inclined wall part 54a starting at the base wall 51 and extending to a first curved wall part 54b. The first part of the curved wall 54b is followed by a second part of the upper inclined wall 54c that forms the base of the "half arrow" and ends in a second part of the curved wall 54d that extends to a part of the curved end wall 54e that extends substantially transversely to the base wall 51 of the pocket 50. The other of the walls (wall 55) comprises, in the resting configuration, a first curved wall part 55a that extends to an inwardly inclined wall part 55b ending in a second curved wall part 55c extending to a terminal wall part 55d extending substantially transversely to the base wall 51.

In the preferred embodiment of the present invention, the first inclined wall part 54a is about 7.23 mm, the first curved wall part 54b is about 3.95 mm, the second inclined wall part 54c is about 2.02 mm , the second curved wall part 54d is about 2.26mm and the end wall part is about 0.47mm. The first curved wall part 55a is about 8.72 mm, the inclined wall part 55b is about 2.94 mm, the second curved wall part 55c is about 1.64 mm and the part of the wall part terminal 55d is about 1.39 mm.

The end wall parts 54e and 55d extend to the walls that delimit the contact portion 53.

The body part 52 of the pocket 50 further comprises a reinforcement structure 56 adjacent to the base wall 51 and one of the walls 54 of the body part 52. In the preferred embodiment illustrated in the figures, that reinforcement structure 56 comprises a structure in lattice having a shape similar to that of a parallelogram, with one of the larger sides defined by a part of the base wall 51 and one of the smaller sides defined by a part of the first inclined wall part 54a of wall 54. The second smaller side of the parallelogram starts at a support part 57 of the base wall 51. The support part 57 coincides with the base wall part 51 which joins one of the curved walls 45 of the body part 42 of the engagement portion 40. In the preferred embodiment shown in the figures, the support part 57 has a reinforced thickness, in order to give more resistance to that junction point. The other side of the parallelogram starts on the second smaller side and extends to wall 54 (in a preferred embodiment, this side is about 6.56 mm). In order to provide greater strength to the reinforcement structure 56, an intermediate wall 37 is also provided, extending from a point of the base wall 51 next to the wall 54 to a median point of the second largest side of the parallelogram.

In the preferred embodiment, the sides of the reinforcement structure parallelogram make the angles C to G illustrated in Figure 11.

The contact part 53 of the pouch 50 comprises a magnet receiving portion 58 and an end portion 59. The magnet receiving portion 58 is substantially rectangular in shape, having two larger parallel walls and two smaller parallel walls. The end portion 59 has an asymmetric tongue shape and comprises a first part of the inclined wall 59a, a second part of the transverse wall 59b to the base wall 51 and a curved wall 59c, the curved wall projecting towards outside the body of the bag in a direction transverse to the base wall 51.

In gaskets known in the art, the position of the magnet receiving part is such that one end of the magnet coincides with the end of the front flange of the refrigerator cabinet to which the gasket contacts.

As shown in figure 12, in the preferred embodiment of the present invention, the position of the magnet receiving part 58 is such that the end of the magnet does not coincide with the end of the central flange 70, but is displaced towards the outside of the cabinet . In a preferred embodiment, this displacement is about 2mm, however, a variation of about 30% in this dimension continues to allow the advantages brought by the proposed geometry to be achieved.

This feature brings the benefit of robustness to the static drop of the door, making the seal more efficient. In this sense, it should be noted that the configuration of the end part 59, projected towards the refrigerator cabinet (out of the gasket body), helps to ensure an adequate seal, since it overlaps the end part of the metallic flange that does not receives the magnet, touching a 71 plastic flange of the refrigerator.

In this sense, it should be emphasized that the dimensions of the end part 59 can vary according to the dimensions of the refrigerator, since they must be measured in order to ensure that this part 59 leans against the plastic flange 71, providing a seal.

The proposed geometry for the sealing pouch 50, together with the proposed construction for the coupling part 40, allows the gasket of the present invention to show a higher efficiency than the gaskets known in the art, especially with regard to the resistance to forces compression, traction and torsion.

In this sense, figures 13 to 16 illustrate the behavior of the gasket of the present invention in relation to compression, traction and torsion forces. It should be noted that a comparison between figures 13 to 16 and figures 2 to 5 (which refer to the gasket of the prior art), indicates that the gasket of the present invention has a compressive strength about 195% greater than the gasket of the technique previous, a resultant traction deformation about 0.6% less than that of the prior art gasket, and about 2% less torsion than the prior art gasket.

In addition, the proposed solution for the gasket of the present invention allows an improvement in the resistance properties to compression, traction and torsion forces, without, however, this implying an increase in the gasket mass. On the contrary, the gasket of the present invention has an optimized amount of mass, with thin walls reinforced to the appropriate extent to provide strength. A comparison with the gasket of the prior art shown in figures 1 to 5, shows that the gasket of the present invention has on average 11% less mass than the gasket of the prior art. Naturally, this advantage generates a considerable reduction in the gasket cost.

It should be noted that the characteristics of the proposed geometry for the coupling portion 40 and the sealing pocket 50 directly influence the improvements obtained with the present invention.

In this sense, the decrease in gasket deformation by traction forces is directly related to the shape and dimensions of the thickness of the reinforcement structure 55, the length of the side walls 54, 55, the existence and dimensions of the inclined wall part 59a of the part of end 59, and the reinforcement at the support point 56. Similarly, resistance to compressive forces is directly related to the shape and dimensions of the thickness of the reinforcement structure 55, the dimension of the base of the “half arrow” of the wall 54 and the dimensions of the magnet receiving part 58. On the other hand, the improvement in resistance to tension has as main factors the dimension of the base of the “half arrow” of the wall 54, the thickness of the wall parts 54b, 54c, 54d and 54e and the dimensions of the magnet receiving part 58.

In the preferred embodiment of the present invention illustrated in figures 6 to 14, the total length of the gasket at rest is about 25.2 mm, the total length of the sealing pouch being about 16.5 mm (measured from the plane of the base wall 51 to the plane that touches the part of the end portion 59 that is most transverse to the plane of the base wall 59).

Still in the preferred embodiment, the magnet receiving part 58 has a substantially rectangular shape, with the larger sides measuring about 10mm and the smaller sides measuring about 2.5mm.

It should be emphasized, however, that these dimensions can be varied within the geometry proposed by the present solution, with a variation of about 10% in this dimension continuing to achieve the benefits brought by the proposed geometry.

Figures 17 and 18 show an alternative embodiment of the sealing system of the present invention. In this embodiment, the engagement part 40 has a construction similar to that of the embodiment illustrated in figures 6 to 14, but the bag has a different construction.

Thus, in this alternative embodiment, the pouch 50 comprises a base part 51 for the engagement part 40, a body part 52 configured in the form of a pillar, a contact part 53 that contacts the refrigerator cabinet when it is in contact with the refrigerator. the closed part.

The base part 51 basically comprises a base wall 51 which closes the "W" formed by the body portion 42 of the engaging part 40 and extends the entire length of the body part 52 of the pocket 50. In the embodiment illustrated in figures 15 and 16, the base wall 51 remains substantially parallel to the refrigerator door.

The body part 52 of the pouch 50 comprises two side walls 54, 55. When in the resting configuration (where the gasket does not suffer compression and traction forces), the walls 54, 55 each comprise an S shape, the supporting body part 20 further comprising two support elements 71, 72 capable of offering tensile strength of the bag 50, and a reinforcement 73 responsible for stabilizing the gasket during its work, that is, during the opening movement and closing the door, thus preventing the bag 50 from twisting.

Reinforcement 73 is configured as a wall parallel to the base wall 51, being connected to the latter by two inclined walls 74, 75.

The support element 71 comprises a curved wall connected to the reinforcement 73 and to the wall 54 of the body part of the bag, and the support element 72 comprises a sloping wall connected to the wall 54 of the body part of the bag to the base part of the bag .

In this sense, it should be noted that the bag part of the second embodiment of the gasket of the present invention has a contact part 53 of a different shape from that of the first embodiment, with the magnet receiving portion 58 being arranged adjacent to the hollow structures that were a contact part substantially parallel to the base wall 51.

It should be understood that the description provided on the basis of the figures above refers to only two of the possible embodiments for the device of the present invention, the real scope of the object of the invention being defined in the appended claims.

Claims (10)

1. Sealing gasket for a refrigerator door comprising an engaging part (40) connected to a sealing pouch (50), FEATURED by the fact that the engaging part (40) comprises an end portion (41) having a substantially triangular profile and a body portion (42) having a W-shaped cross section with curved walls (45, 46), the end portion (41) being formed by two flaps (43, 44), each of which flaps (43, 44) at an angle to each of the curved walls. 2. Sealing gasket according to claim 1, CHARACTERIZED by the fact that the junction between each of the flaps (45, 46) and each of the curved walls (44, 46) has a strain relief opening (49 ) 3. Sealing gasket according to claim 1 or 2, CHARACTERIZED by the fact that the sealing pouch (50) comprises a base part (51) for the coupling part (40), a body part (52 ) in the form of a pillar, and a contact part (53) that contacts at least part of a refrigerator cabinet. 4. Sealing gasket according to claim 3, CHARACTERIZED by the fact that the base part (51) comprises a base wall (51) which extends substantially parallel to the refrigerator door. 5. Sealing gasket according to claim 1 or 2, CHARACTERIZED by the fact that the body part (52) in the form of a pillar comprises two side walls (54, 55) and a reinforcement structure (56). 6. Sealing gasket according to claim 5, CHARACTERIZED by the fact that the reinforcement structure (56) comprises a lattice-shaped lattice structure, with one of the larger sides defined by a part of the base wall (51 ) and one of the smaller sides defined by a part of the wall (54). 7. Sealing gasket according to claim 6, CHARACTERIZED by the fact that the second smaller side of the parallelogram starts at a support part (56) of the base wall (51), the support part (56) coinciding with the base wall part (51) which joins one of the concave walls (45) of the body part (42) of the engagement portion (40). Sealing gasket according to any one of claims 3 to 7, CHARACTERIZED in that the contact part (53) comprises a magnet receiving part (58) and an end portion (59). 9. Sealing gasket according to claim 8, CHARACTERIZED by the fact that the magnet receiving part (58) is displaced in relation to the end of the external flange of the refrigerator cabinet, towards the outside of the cabinet. 10. Sealing system CHARACTERIZED by the fact that it comprises: a sealing gasket as defined in any one of claims 1 to 9, and a receiving channel comprising a triangle-shaped part (62) defined by two side walls (63, 64) which are at an apex end (65), and an opening part (66) which receives an engaging part (40) of the gasket.

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