ES2345235B1 - THERMAL INSULATING HOUSING WITH PASSAGE PASSAGE. - Google Patents

Abstract

Heat insulating housing with conduit passage.

An insulating housing for a cooling device
it comprises a solid outer shell (1, 2), an insulating mass surrounded by the outer shell (1, 2), and a plug connector (8) mounted in an opening (7) of the outer shell (1), which is supported in the opening (7) with plug direction oriented obliquely with respect to the normal of the upper surface (N) of the outer covering (1).

Description

Heat insulating housing with conduit passage.

The present invention relates to a housing thermal insulation, especially to a housing for a device domestic refrigeration, with a passage of conduit. Such a housing type usually comprises a solid outer coating, assembled most of the time from various elements of metal and / or plastic material, and an insulating mass surrounded by the outer coating. A passage of conduit, for example for the power supply of an interior space lighting, of a blower installed in the interior space of the appliance cooling, the transmission of signals from a sensor or the like, comprises a plug connector held in an opening of the outer covering, from which a duct extends to through the insulating ground, as an example, to another connector plug on an opposite upper surface of the housing, or directly to the user or sensor. Since the connector plug usually extends deep into the ground insulator, the insulation effect of the housing in place of plug connector is reduced, that is, there is a danger of a thermal bridge that increases the energy consumption of the device.

At the increased thermal conductivity in the surroundings of the plug connector contributes not only this one or the insulating material absent in the place occupied by him but also a conduit outlet on a rear side of the plug connector. The conduit that exits the rear side of the plug connector penetrates even more noticeably in the layer of insulating material than the same plug connector, and can even come into contact with a opposite side of the outer covering. Especially in the case of an electrical conduit, by means of the metal used in it the thermal conductivity is high. Therefore, a duct contact with the opposite upper surface of the outer coating. In fact, connectors are known plug with side cable outlet, although these are usually more complicated in configuration and assembly than a connector of comparable plug with cable outlet in the direction of Plug.

It is the task of the invention to specify a housing insulator with a passage of conduit, in which the ability to isolation is only slightly impaired through the presence of plug connector, so that a thermal conductance value desired of the complete housing is also achievable with a thickness low layer of insulating mass.

The task is solved while in a housing insulator with a solid outer coating, an insulating mass surrounded by the outer coating, and a plug connector mounted in an opening of the outer shell, the connector plug held in the opening with a plug direction oriented obliquely with respect to the normal surface upper outer shell. Through the oblique position, the penetration depth of the plug connector into the ground Insulator is reduced, and in the case of a plug connector with cable outlet in the direction of plug, the cable can also be kept away without excessively pronounced bending of a opposite upper surface of the housing.

The plug connector can be fixed directly in the opening of the outer covering. In this case, the plug connector itself must hermetically close the opening, to exclude the output of the insulating mass. However, the plug connector is preferably held in a plug connector holder that closes the opening of the outer shell. The use of the plug connector support makes it possible to use conventional plug connectors, since for these plug connectors they can be formed in the plug connector support, as necessary, anchoring contours that guarantee proper, safe support and good tightness . On the other hand, optimized contours can be formed on the plug connector support for a hermetic anchor in the outer shell, without this requiring an adaptation of the plug connector
same.

For anchoring the plug connector, by a side, and for fixing on the outer covering, on the other side, the plug connector holder preferably comprises a tubular part that houses the plug connector, oriented in the plug direction, and an obliquely oriented connecting flange with respect to the tubular piece.

The tubular piece can present at one end away from the connecting flange a bevel essentially parallel to this one, to minimize its depth of penetration in the mass insulating.

According to a first configuration, the flange of union is in contact on the side of the filling material with the outer coating. Thus, the union flange is pressed against the outer covering when the housing is foamed with the dough insulation, which favors the tightness of the contact between flange of union and external coating against the mass outlet insulating.

For fixing to the opening in one direction parallel to the top surface, the plug connector bracket it also preferably has a rod section oriented in direction of the normal upper surface, which crosses the opening of the outer covering.

For anchoring the connector support of plug in the outer coating, the stem section can be provided with at least one hitch boss that collides with the outer side of the outer coating.

To facilitate the interlocking of the projection of hitch, on one side of the stem section located in front of the hook protrusion may be formed a hook, which wraps around Hinge mode one edge of the opening.

According to an alternative configuration, the flange of union is in contact on the outer side with the coating Exterior. This solution is preferred if the passage of conduit or parts from it remain visible in the finished apparatus, since in this If the connection flange can completely cover the opening of the outer coating.

The angle between normal of the upper surface and plug address can be between 30 and 60, so Especially preferred at between 40 and 50 degrees.

Other features and advantages of the invention are extracted from the following description of embodiments referring to the attached figures. It shows:

Fig. 1 a schematic section through a wall of cooling apparatus with a passage of conduit according to a first configuration of the invention;

Fig. 2 a section analogous to figure 1 according to a perfected configuration;

Fig. 3 an intermediate phase during installation of the plug connector bracket configuration of figure 2;

Fig. 4 a side view of a support plug connector according to a third configuration of the invention; Y

Fig. 5 a section through the connector support of plug of figure 4 along the plane indicated with V-V

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Figure 1 shows a schematic section a through a wall of a refrigeration apparatus, for example, of body or door, with outer coating layers 1, 2 and a hollow space 3 formed in the middle, which in case of Finished cooling is filled with insulated mass not shown here in the form of polyurethane foam. That outer covering which separates the insulating mass from the interior space of the apparatus of refrigeration is usually embedded from material plastic material plane, while the layer between insulating mass and surroundings is formed by a sheet. In the case of Figure 1, both outer coating 1 can be found towards the inner space and the outer covering 2 towards the surroundings as in reverse.

On the outer covering 1 it is stamped a cuneiform or prism-shaped cavity 4 to form two flat surfaces 5, 6 oriented approximately below 45º with with respect to the normal of the upper surface N of the coating surrounding exterior 1. On the flat surface 5 is stamped a opening 7 in which a plug connector 8 is housed in drag shape with an essentially shaped body parallelepiped 12 and hermetically closing the opening. He plug connector 8 is represented here as a connector electric plug with a continuous multi-wire connection cable 9 inside the housing, although instead of the connection cable 9 a conduit or a flexible tube could also be provided for a medium capable of flowing, such as water or cooling medium, or a line of optical signals.

A plug connector 10, complementary to 7 wall-mounted plug connector, with contact pins 11 that engage in sockets of plug connector 8 is represented in dashed line in figure 1.

The plug connector 8 supports on its walls laterally several hooking projections 13 elastically movable inside the plug connector body 12. Mounting the plug connector 8 is produced by inserting it into the opening 7 of the flat surface 5 from the inner side. To the happen this, the hitch projections 13 are pushed back temporarily inside the plug connector body 12 and resalen again as soon as they have completely gone through the opening 7. With the help of the engagement projections 13 opposite a outer side of flat surface 5, and rigid projections 14 directed towards an inner side of the flat surface 5, the plug connector 8 is fixed in opening 7.

Rigid projections 14 could distract more than plug connector body 12 as shown in figure 1, and be fused to a nerve that runs around the body of plug connector 12, which covers the foam side complete an existing fissure eventually between the sides exterior of the plug connector body 12 and the edge of the opening 7. The hollow space 3 being pressed when foaming plug connector 7 from the insulating ground out, the nerve comes into contact with the flat surface 5 tightly, of so that an outlet of the insulating mass between the edges of the opening 7 and plug connector 8 is unlikely.

By the oblique position of the connector plug 8 next to flat surface 5, the depth of penetration of the plug connector 8 itself and, first of all, of the cable of connection 9 that comes out on its back side in the direction of plug, in the hollow space 3 it is reduced with respect to a configuration in which the plug connector 8 is sunk into the wall with plug direction parallel to the normal upper surface N. Through this, in case of wall thickness that remains likewise, the insulation capacity is improved with respect to a wall with duct passage oriented in the direction of the normal upper surface N.

However, a problem with this configuration simple is that, due to the deformations that appear when stamping or insert the cavity 4, the thickness of the outer covering in the direct surroundings of the opening 7, as well as the dimensions of the opening 7, are difficult to control accurately. For the Therefore, it is difficult to completely eliminate the danger of entering plug connector 8 and the edge of the opening 7 leave dough insulating. The configuration in Figure 2 guarantees reliability increased in this respect. The plug connector 8 and its orientation are the same as in the configuration of figure 1, however, as opposed to this, the plug connector 8 does not it is anchored directly in the outer coating 1, but with help of a plug connector holder 15 in which it comes preferably of a material injection molding piece plastic.

As the section in Figure 2 shows, the plug connector bracket 15 can be divided essentially in three areas, a tubular piece 16, which penetrates the hollow space 3 at an angle of 45º with respect to the normal surface upper N of the outer covering 1, a connecting flange 17, which on the side of the foam is in contact with the coating exterior 1, and a short shank section 18, oriented in direction of the normal upper surface, which extends to through the opening 7 of the outer covering 1. Crosswise to the plug direction of plug connector 7 an inner wall 19 is formed in the tubular part 16 with a opening, which exactly fills the body 12 of the plug connector 8. This opening can be made in injection molding with noticeably lower tolerances in relation to dimensions and wall thickness than the opening 7 of the configuration of Figure 1, and a high load capacity of the plug connector anchor 8 is reachable through a large surface contact of the connection flange 17 with the side inside of the outer covering 1 and of the stem section 18 with the inside edge of the opening 7 cut in the coating exterior 1.

To protect exit points 20 from connection cable conductors 9 on the rear side of the 8 plug connector against overload and breakage, especially during installation of plug connector 8 and bracket plug connector 15 on the outer coating 1, the piece tubular 16 is elongated in a piece beyond the back side of plug connector 8 in the hollow space 3. However, for avoid on the other hand unnecessary weak points of isolation in the hollow space 3 is dispensed with a rear corner of the tubular piece 16 directed towards the outer covering 2 and, in its instead, the tubular piece ends with a bevel 21 parallel to the 1 or 2 outer coating.

The stem section 18 that crosses the opening 7 is provided on two opposite sides of projections 22, 23. The projection 22 forms together with the connecting flange 17 a hook which, as shown in figure 3, it is fitted in the assembly of the plug connector bracket 15 on outer sheath 1 in first from its inner side on an edge of the opening 7. In this position shown in Figure 3, the opposite projection 23 shaped like hook heel is not yet pushed through of the opening 7. In this position, the connector support of plug 15 has poor freedom of movement around of an axis of rotation adjacent to the lower projection 22. To anchor the plug connector bracket 15 securely in the outer covering 1, it is therefore sufficient to turn it from the position shown in figure 3 slightly in the opposite direction to the clockwise and, when this happens, push the projection 23 through the opening 7 against a deformation resistance of the outer covering 1 and / or of the stem section 18.

During assembly, the connector bracket plug 15, as shown, can be empty or already equipped with plug connector 8 and connection cable 9.

As shown in Figure 2, the protrusions 22, 23 leave the plug connector bracket 15 still a certain clearance in the direction of the normal of the upper surface N of the outer coating 1. However, a tight contact to the foam between joint flange 17 and outer shell 1 it can be secured, for example, the connection flange 17 provided with an adhesive layer that adheres to the assembly outer coating 1, or other means of hitch, not shown, to fix the connector support of plug 15 in the position of figure 2. Under circumstances, it can also be enough if the pressure of the same insulating mass that is produces when foaming keeps the union flange 17 pressed against the outer coating 1 hermetically.

A third configuration of a conduit passage It is represented in figures 4 and 5 in the form of a side view and of a cut, respectively. In this configuration, the piece tubular 16 is inserted from the outside through the opening 7 of the outer covering 1, and its theoretical position is fixed by the contact of the connecting flange 17 with the outer side of the outer sheath 1. To ensure that the union flange 17 also remain during foaming in contact with the 1 outer coating against a dominant overpressure eventually in the hollow space 3, and close hermetically opening 7, both can be glued to each other as it has been described with reference to figures 2, 3 or, as shown in the Figures 4 and 5, can be fixed on the outer coating 1 leaf springs 24, for example spring steel or other elastic material, but resistant against an upset in direction longitudinal, which are engaged in emptyings 25 in walls sides of the tubular part 16 and, when this happens, they are loaded by bending, so that they exert on the tubular part 16 a force directed to the hollow space 3.

The oblique position of plug connector 8 is advantageous not only in relation to the thickness of the layer of isolation; from this, there is also a simplification during assembly of the device housing, since a pressure force exerted by sliding the connector of movable plug 10 acts not only in the direction of the normal upper surface, but in essentially the same thickness also parallel to the outer coating 1. In this direction, the stiffness of the outer coating 1 is noticeably higher than in the direction of the normal of the upper surface, so that the corresponding force component can be absorbed by the outer coating 1 without essential deformation. The burden of insulating ground when fitting the plug connector 10 is therefore markedly reduced with respect to a plug connector with plug direction in the direction of the normal surface higher. Therefore, the danger of isolation being compressed to fit the plug connector 10 is reduced. The reduced requirements regarding the strength of the insulating foam allow to reduce the proportion of solid matter of this, through of which the requirements for a greater improvement of the insulation capacity

Claims (13)

1. Heat-insulating housing with a solid outer shell (1, 2), an insulating mass surrounded by the outer shell (1, 2), and a plug connector (8) mounted in an opening (7) of the outer shell (1) , characterized in that the plug connector (8) is held in the opening (7) with a plug direction obliquely oriented with respect to the normal of the upper surface (N) of the outer covering (1). 2. Heat insulating housing according to claim 1, characterized in that the plug connector (8) is held in a plug connector support (15), which closes the opening (7) of the outer covering (1). 3. Heat insulating housing according to claim 2, characterized in that the plug connector support (15) comprises a tubular part (16) housing the plug connector (8), oriented in the plug direction, and a connecting flange ( 17) oriented obliquely with respect to the tubular part (16) for placement next to the outer covering (1). 4. Heat insulating housing according to claim 3, characterized in that the tubular part (16) has a bevel (21) essentially parallel to the joining flange (17) at a remote end of the connection flange (17). 5. Heat insulating housing according to claim 3 or 4, characterized in that the connecting flange (17) is in contact with the outer covering (1) on the side of the filling material. 6. Heat insulating housing according to claim 5, characterized in that the plug connector support (15) also has a rod section (18) oriented in the direction of the normal of the upper surface (N), which crosses the opening (7) of the outer covering (1). 7. Heat-insulating housing according to claim 6, characterized in that the rod section (18) has at least one engagement projection (23) that collides with the outer side of the outer covering (1). 8. Heat-insulating housing according to claim 7, characterized in that a hook (22) is formed on a side of the rod section (18) in front of the hitch projection (23) which hinges an opening edge ( 7). 9. Heat insulating housing according to claim 3 or 4, characterized in that the connecting flange (17) is in contact on the outer side with the outer covering (1). 10. Heat insulating housing according to one of the preceding claims, characterized in that the plug connector support (15) has an inner wall (19) oriented transversely to the plug direction, and because the plug connector (8) is interlocked in an opening of the inner wall (19). 11. Heat-insulating housing according to one of the preceding claims, characterized in that a conduit (9) is conducted outside the plug connector (8) in the plug direction. 12. Heat insulating housing according to one of the preceding claims, characterized in that the angle between the normal of the upper surface (N) and the plug direction is between 40 ° and 50 °. 13. Heat-insulating housing according to one of the claims set forth above, characterized in that it is a refrigeration apparatus housing, especially a domestic refrigeration apparatus housing.