WO2007134724A1

WO2007134724A1 - Door seal profile

Info

Publication number: WO2007134724A1
Application number: PCT/EP2007/004137
Authority: WO
Inventors: Klaus RÜHLING; Helmut Hanna
Original assignee: Rehau Ag + Co
Priority date: 2006-05-19
Filing date: 2007-05-10
Publication date: 2007-11-29
Also published as: EP2018506A1; DE102006023848A1

Abstract

A door seal profile (1) is used to construct a door seal for a refrigerator that has a door and a housing base as housing components. The door seal is intended to seal the door against the housing base. The door seal profile (1) has a fastening section (3) to engage in a receiving groove of one of the housing components. A base section (8) of the profile serves to rest against a first housing component that has the receiving groove and adjacent thereto. The base section (8) rests tightly against the first housing component over at least one base seal gasket section (9). A contact section (13) of the profile serves as a sealing contact on a second housing component. A corrugated section (17) flexibly joins the base section (8) and the contact section (13). The base section (8) has a base bottom (10) and as a base seal section at least one sealing lip (9) made of a first plastic material. The sealing lip (9) is molded on the base body (10) via a connecting ridge (11) made of a second plastic material that is softer than the first plastic material. A door seal profile is thus obtained, with which there is a secure seal via the base seal section, with less problematic production than in the prior art.

Description

Door weatherstrip

The invention relates to a door seal profile for constructing a door seal for a cooling device according to the preamble of claim 1.

Such a door seal is known from EP 1 129 319 B1. The local door seal profile has a base sealing portion which is produced by encapsulation of a base body. This is disadvantageous in terms of production since it is not easy to guide the basic base body. The registered by the encapsulation in the base body heat can be dissipated poorly, which can lead to an undesirable distortion of the base body.

It is therefore an object of the present invention to develop a door seal profile of the type mentioned and a door assembly of a refrigerator with such a door seal profile such that a secure seal over the base sealing portion is given at less problematic production.

This object is achieved by a door seal profile with the features specified in claim 1.

According to the invention, it has been recognized that in order to ensure a secure and sealing engagement of the base sealing section, it is not absolutely necessary to produce it from soft plastic material by extrusion coating. An equally reliable sealing result is achieved when a relatively hard plastic material is used as the base sealing portion, which is integrally formed on the basic base body via a comparatively soft plastic connecting web. The soft connecting web gives the base sealing section the flexibility necessary for a secure sealing effect. At the same time, the production of a base section with a soft connecting web and a turn hardened base sealing section formed thereon is simpler in terms of manufacture, since the connecting techniques used for this purpose are not associated with a heat input which is comparable with the encapsulation according to EP 1 129 319 B1. A coextrusion of the base according to claim 2 enables a production of the door seal profile with mass production techniques.

An attachment portion according to claim 3 results in a door seal profile with a desirably high pull-out force. Even if the door seal initially adheres to the second housing component when the refrigerator door is opened, it is ensured by the fastening section that the fastening section remains securely in the receiving groove, since the frictional engagement and / or the other mechanical resistance of the holding body in the receiving groove is sufficiently high ,

In a retaining lip according to claim 4, a desired increase in the pull-out force results in particular due to the mechanical resistance, which opposes the retaining lip at a withdrawal of the mounting portion of the receiving groove. In addition, the at least one retaining lip can still perform a sealing function.

A holding coating according to claim 5 can be produced with little effort.

It has been shown that an increased coefficient of friction, the z. B. can be achieved due to an embodiment of the holding body made of softer plastic material, sufficient for the desired increase in the pull-out force in many cases. An increase in the coefficient of friction can also be achieved independently of the material hardness of the plastic material, for example by a corresponding surface structuring of the holding body.

The embodiment according to claim 6 brings with it the advantages which have already been mentioned in those according to claim 2.

The embodiments according to claims 7 and 8 lead to a particularly simple production of the door seal profile.

This applies in particular to a profile produced in total by coextrusion according to claim 9. As regards the door assembly, the object mentioned is achieved by a door assembly with the features specified in claim 10.

The advantages of this door assembly correspond to those already mentioned above with reference to the door seal profile.

An undercut area according to claim 11 leads to an advantageous additional increase in the pull-out force.

An embodiment of the invention will be explained in more detail with reference to the drawing. In this show:

Figure 1 in cross section a door seal profile, which is engaged via a mounting portion in a refrigerator door, which is shown in fragmentary form.

Fig. 2 increases the door seal profile compared to the illustration of Figure 1;

FIGS. 3 and 4 show further embodiments of a door seal profile in a representation similar to FIG. 2;

5 shows a further embodiment of a door seal profile in a representation similar to FIG. 1 in an instantaneous position of the door seal profile prior to engagement of the fastening section; and

Fig. 6, the door seal profile of FIG. 5 with an engaged mounting portion.

A in the drawing generally designated 1 door seal profile is used to construct a door seal for a refrigerator, of which in the drawing in Fig. 1, only a section of a refrigerator door 2 is shown. In addition to the refrigerator door 2, the cooling unit as a further housing component has a housing main body, not shown. The door seal seals in the closed position of the refrigerator door 2 latter against the housing base body. The door seal profile 1 is divided into several profile sections. A fastening section 3 shown in the drawing below serves for latching into a receiving groove 4, which is formed in an inner door section 5 of the refrigerator door 2 as a groove profile running around the door opening. By this engagement, the door seal profile 1 is attached to the inner door section 5. The fastening section 3 has as fastening basic body 6 two hook-shaped fastening webs bent outward in the shape of a hook. At the free ends of these fastening webs 6 extending from the mounting portion 3 outwardly retaining lips or fastening sealing lips 7 are formed, which are made of a softer compared to the mounting base 6 plastic. The retaining lips or fastening function of the fastening sealing lips 7 is due to their increased friction on the inner wall of the receiving groove. 4 The retaining lips or fastening function of the fastening sealing lips 7 are due to their increased friction on the inner wall of the receiving groove. 4 These sealing lips 7 are shown in Fig. 1 in a relaxed position in which they are of course not present when snapping into the receiving groove 4, since then the sealing lips 7 and the ends of the hook-shaped fastening webs of the mounting base 6 inside of the receiving groove issue. The sealing lips 7 are arranged inclined to the fastening webs 6 with respect to a plane E, which is perpendicular to an extension direction AR or an insertion direction ER. The free ends of the sealing lips 7 extend a little way in the direction of the extension AR. The plane E is in particular no mirror symmetry plane of the sealing lips 7. A in Fig. 1 upwards, ie in the direction of an arrow 8a in Fig. 1 directed extraction force, for example, by priming the housing body on the door seal when opening the refrigerator door 2 is formed , Set the sealing lips 7 a sufficient counter force, since they have a high friction against the groove wall of the receiving groove 4 and there to pull out the door seal the sealing lips 7, which initially act as barbs, must be folded. As a result, the pull-out force of the attachment section 3 in the extension direction AR out of the receiving groove 4 is at least 20% higher than the insertion force of the attachment section 3 in the insertion direction ER into the receiving groove 4.

The attachment portion 3 is integrally formed on a base portion 8 of the door seal profile 1. The latter is located on the refrigerator door 2 adjacent to the receiving groove 4 via base sealing portions 9 sealingly. The base portion 8 has a base body 10. At the latter, the base sealing portions 9 are formed in the form of sealing lips via a respective connecting web 11. The two connecting webs 11 are made of a plastic material which is softer than the material of which the basic base body 10 and the base sealing lips 9 are formed. The base body 10 and the base sealing lips 9 are made of the same plastic material.

The connecting webs 11 form hinge hinges, so that the base sealing lips 9 are pivotable about axes relative to the base body 10, which run parallel to the longitudinal axis of the door seal profile 1. This pivoting is indicated in FIG. 2 using the example of the left-hand base sealing lip 9 there.

The right in Fig. 1 base sealing lip 9 is used for sealing engagement with an outer door portion 12 of the refrigerator door 2. The left in Fig. 1 base sealing lip 9 is used for sealing contact with the inner door section. 5

For sealing engagement with the second housing component, that is to say on the housing main body of the cooling device, an abutment section 13 of the door seal profile opposite the fastening section 3 is used. The contact section 13 is subdivided into two adjacent hollow chambers 14, 15, one of which, for example, can receive a magnetic strip. At the inner door section 5 facing hollow chamber 15, a contact-sealing lip 16 is formed. The latter is in the mounted position of the door seal profile 1 on the inner door section 5.

Between the contact portion 13 and the base portion 8, a bellows portion 17 is arranged, which connects the base portion 8 flexible with the abutment portion 13. The bellows section 17 has two flexible and elastically flexible bellows walls 18, 19. The bellows section 17 is integrally formed on the one hand on the contact section 13 and on the other hand on the base section 8.

The entire door seal profile 1 is produced by coextrusion. In this case, the fastening base body 6, the base base body 10 and the base sealing lips 9 are made of hard PVC. The remaining components, ie the fastening sealing lips 7, the connecting webs 11, the bellows section 17 and the contact section 13 with the contact sealing lip 16 are made of soft PVC. The entire door seal profile 1 therefore consists of exactly two different materials. In other embodiments, it is possible to make the door seal profile 1 also from more than two different materials. 3 and 4 show further embodiments of a door seal profile 1. Components which correspond to those which have already been explained above with reference to FIGS. 1 and 2 bear the same reference numerals and will not be discussed again in detail.

When door seal profile 1 of FIG. 3, the contact portion 13 has a cavity, namely the cavity 14 for receiving a magnetic strip. The bellows portion 17 has, in addition to the bellows wall 18, a further bellows wall 20, which is integrally formed on the base body 10 at the same location as the bellows wall 19 of the embodiment of FIGS. 1 and 2. The bellows wall 20 is made of the same material as the bellows wall 18th The bellows wall 20 is integrally formed on the abutment portion 13 in such a way that it initially continues in alignment with a contact surface of the abutment portion in an area adjacent to the hollow chamber 14. The bellows wall 20 thus simultaneously fulfills the functions "installation" and "flexible connection of the base section 8 with the contact section 13".

In the case of door seal profile 1 according to FIG. 4, a further bellows wall 22 is additionally formed in addition to the bellows wall 20 between a lower right corner of a boundary wall 21 in FIG. 4 around the hollow chamber 14. The bellows wall 22 is made of the same material as the bellows wall 18.

At the base body 10, the bellows wall 22 is formed approximately centrally between the bellows walls 18 and 20.

FIGS. 5 and 6 show a further embodiment of a door seal profile 1. Components which correspond to those which have already been explained above with reference to FIGS. 1 to 4 bear the same reference numerals and will not be discussed again in detail.

The attachment portion 3 of the door seal profile 1 according to FIGS. 5 and 6 has no hook-shaped outwardly bent fastening webs, but two fastening webs 6, each with a on the inner groove wall of the receiving groove 4 to be extended bead area 23rd In the insertion direction ER directly adjacent to the region of largest diameter of the fastening section 3 at the bead regions 23, retaining coatings 24 are extruded onto the fastening webs. The holding coatings 24 are made of soft plastic material, in particular of soft PVC.

The arrangement of the holding coatings 24, which travels the largest circumference of the bead region 23, requires that the fastening webs of the fastening section 3 essentially engage with the receiving groove 4 when the fastening section 3 is inserted into the receiving groove 4 (see FIG Contact is coming. Since the mounting base 6 is made of hard plastic material, the coefficient of friction of the mounting base 6 on the receiving groove 4 is relatively small, resulting in a relatively small insertion force when locking the mounting portion 3 in the receiving groove 4 in the insertion direction ER. In the latched position of the fastening section 3 in the receiving groove 4 shown in FIG. 6, the retaining coatings 24 bear on the groove wall of the receiving groove 4 at undercut areas 25 of the receiving groove 4.

Since the friction coefficient of the soft retaining coatings 24 on the groove wall of the receiving groove 4 is substantially higher than the coefficient of friction of the other hard mounting base 6 on the groove wall of the receiving groove 4, it requires a much higher pull-out force than the insertion force to the mounting portion 3 to pull out the receiving groove 4. At the beginning of this pull-out process, in particular the static friction of the holding coatings 24 on the groove wall of the receiving groove 4 must be overcome. The extraction force of the attachment portion 3 in the extension direction AR from the receiving groove 4 is 5 and 6 in the embodiment of FIGS. At least 20% higher than the insertion force of the mounting portion 3 in the insertion direction ER in the receiving groove. 4

Instead of PVC, the door seal profile 1 may also be made of a different polymeric material in the various embodiments. It is important that the mounting base 6, the base body 10 and the base sealing lips 9 made of a harder polymeric material and that the holding body 7, 24, the connecting webs 11, the bellows portion 17 and the abutment portion 13 with the abutment-sealing lip 16th made of a softer polymeric material. In the embodiments of holding bodies described above, these are each made of a plastic material which is softer compared to the fastening body. To increase the pull-out force relative to the insertion force, it is important to increase the friction of the holding body on the groove wall of the receiving groove against the friction of the other mounting base body on the groove wall. The holding body can therefore be made generally of materials with a relation to the mounting base increased friction coefficient. This material is not limited to a softer plastic material than the material of the mounting base body. The increase of the friction coefficient can be realized, for example, by a corresponding surface structuring of the holding body.

- Claims -

Claims

claims

1. Door seal profile (1) for building a door seal for a cooling unit, which has a door (2) and a housing body as housing components, wherein the door seal to seal the door (2) against the housing base, wherein the door seal profile (1 a fastening section (3) for latching into a receiving groove (4) of one of the housing components (2), a base section (8) for engaging a first housing component (2) having the receiving groove (4) adjacent to the receiving groove (4) which at least one base sealing portion (9) sealingly abuts against the first housing component (2), a contact portion (13) for sealing engagement with a second housing component, a the base portion (8) and the abutment portion (13) flexibly interconnecting bellows portion (17), characterized in that the base portion (8) has a base base body (10) and as a base sealing portion at least one sealing lip (9) of a m having the first plastic material, wherein the sealing lip (9) on the base body (10) via a connecting web (11) made of a second plastic material, which is softer than the first plastic material is formed.

2. door seal profile according to claim 1, characterized in that the base base body (10), the connecting web (11) and the base sealing lip (9) are made by coextrusion.

3. door seal profile according to claim 1 or 2, characterized in that the fastening portion (3) has a mounting base body (6) made of a first plastic material and for engagement with a groove wall of the receiving groove (4) at least one holding body (7; which is designed so that the pull-out force of the fastening portion (3) in the extension direction (AR) from the receiving groove (4) is at least 20% higher than the insertion force of the mounting portion (3) in the insertion direction (ER) in the receiving groove (4).

4. Door seal profile according to claim 3, characterized in that the holding body is designed as a holding lip (7) made of a second plastic material which has a higher coefficient of friction, in particular softer, than the first plastic material, wherein the retaining lip (7). at least in sections relative to a plane (E), which is perpendicular to the extension direction (AR) or the insertion direction (ER), is arranged inclined.

5. door seal profile according to claim 3, characterized in that the holding body is designed as a holding coating (24) made of a second plastic material which has a higher coefficient of friction, in particular softer, than the first plastic material, wherein the holding coating (24) is arranged on the attachment portion (3) such that the attachment portion (3) when inserted into the receiving groove (4) at least partially does not abut the retaining wall (24) on the groove wall of the receiving groove (4), the attachment portion (3) when pulling out of the receiving groove (4) with a larger area on the groove wall of the receiving groove (4) is applied when inserting.

6. door seal profile according to one of claims 3 to 5, characterized in that the fastening base body (6) and the holding body (7; 24) are made by coextrusion.

7. Door seal profile according to one of claims 1 to 6, characterized in that the base base body (10), the at least one base sealing lip (9) and the mounting base body (6) are made of the same plastic material.