FI79171B - GLASDOERR OCH GAONGJAERNSKONSTRUKTION AVSETT ATT ANVAENDAS I DEN. - Google Patents

Description

79171

The present invention relates to a glass door for use in refrigeration and freezing compartments and to a hinge structure suitable for such a glass door.

Grocery stores have increasingly switched to using glass-door refrigerators and freezers. The customer then sees the products in the cabinet through the glass door and after deciding which product he wants from the cabinet, the customer opens the door, takes the product from the cabinet and closes the door.

Such previously known glass doors in use usually comprise an aluminum U-profile frame fitted with two or three glass panes, of which at least the pane away from the refrigeration and freezing compartment and the refrigeration and freezing compartment side are tempered glass which can withstand ordinary mechanical stresses. A spacer or gasket is fitted between the boxes.

In order to prevent frost on the front glass pane remote from the cooling and freezing space, this front glass pane is heated in known glass doors. This is accomplished by forming an electrically conductive layer, such as a tin oxide layer or a tin oxide-silver-tin oxide layer, inside the front panel. Electrodes, e.g. silver electrodes, are formed on this electrically conductive layer by a so-called screen printing method, and these electrodes are connected to the mains voltage. The electrodes are usually placed at the top and bottom of the glass pane so that they are visible when viewed through the door. This degrades the appearance of the glass door, but a much more serious drawback is that if the screen breaks, e.g. when a shopping cart hits it, there is a risk that the customer or any other person who directly or 2 79171 touches the electrode will receive an electric shock.

In the previously known heated glass solution, the electrical wires are often attached to the electrodes by soldering, whereby the connection is not very good and the electrical wire may even become detached, moreover, the electrical contact in such a connection is not always very good.

It is also known to attach the resistance wire or wires to the inner surface of the aluminum profile frame, e.g. with fasteners or by attaching them, so that no moisture condenses on the frame.

Because the glass door is exposed to very large temperature differences, the pressure variations in the space between the glass panes are also very large. This places great demands on the sealing between the panes and also on the sealing between the frame and the glass panes, the latter of which is also important in terms of the required heating power and thus the electricity consumption. The space between the glass panes is usually filled with a shielding gas, usually argon or krypton gas, and if this gas can escape, e.g. due to poor gas tightness, this has a destructive effect on the electrically conductive layer and thus also on the life of the glass door.

Glass doors with two or three or even four panes of glass (the typical thickness of one pane is about 3-4 mm) are very heavy compared to conventional doors and this places special demands on the hinge structure of the door. In known heated glass doors, it is difficult and often impossible to change the handle of the door, due to e.g. that the electrical wires which are led out of the door frame structure via the upper hinge come to a lower hinge when the door is changed, from where they cannot be pulled to the upper hinge without dismantling the entire door.

The object of the present invention is to provide a glass door for use in a cooling and freezing room, which has a simple structure and which avoids the disadvantages and shortcomings of previously known glass doors and has a long service life.

It is a further object of the invention to provide a distribution hinge for a distribution door intended for use in refrigeration and freezing rooms, which can withstand even high loads and which enables the door handle to be changed in a simple manner.

The main features of the invention appear from the appended claims.

The invention will now be described in more detail in the form of preferred embodiments with reference to the accompanying drawings, in which Figure 1 shows a front view of a glass door according to the invention, Figure 2 shows on an enlarged scale a horizontal section along the line II-II 3A along line 3-3, Fig. 4 shows a vertical section of a hinge structure according to the invention mounted on a glass door according to the invention, Fig. 5 shows a detail of Fig. 4 seen from above, and Fig. 6 shows the hinge structure according to Fig. 4 parts separately.

Figure 1 shows a glass door according to the invention seen from the front and provided with a lower hinge 10 and an upper hinge 11. The frame of the glass door is marked with reference number 1.

Figure 2 shows a horizontal section of a glass door, which shows the structure of the frame profile 1 and the installation of glass panes 2 and 3 thereon.

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The open door according to the kitchen comprises a front glass pane 2 facing away from the cooling and freezing compartment and a rear glass pane 3 facing the cooling and freezing compartment. -muovia. This spacer may be filled with desiccant.

The front panel 2 is made to be heated so that the inner surface of the panel is coated with an electrically conductive layer 4, which may be, for example, a tin oxide or a 3-layer tin oxide-silver-tin oxide layer. This electrically conductive layer 4 is connected in the left and right parts of the screen near the end portions of the screen to electrodes Θ and 9, which are connected to the mains voltage. As shown in Fig. 2, the electrodes 8 and 9 are placed in the space 12 between the spacer 5 and the end portions of the panes, so that in the event of the glass panes breaking, there is no risk of the customer or any other person receiving an electric shock from the electrodes.

The electrodes 8 and 9 can be formed on the electrically conductive layer 4, e.g. by a screen printing method using silver paste. Tempering of the glass can be performed either before or after screen printing.

The glass panes 2 and 3 are surrounded at their edges by a U-profile strip 6, which is preferably made of soft PVC plastic. The space 12 between the intermediate strip 5 and the U-profile strip 6 is preferably filled with an insulating filling mass, such as a two-component polysulphide mass. There must be a shielding gas between the glass panes 2 and 3, eg arg ° n_ or krypton gas. The U-profile 6 considerably improves the gas tightness when the pressure varies inside and outside the glass panes 2 and 3 and at the same time acts as an electrical insulator. The U-profile 6 can be shaped in such a way that air gaps 20 are formed between the U-profile strip 6 and the glass panes 2 and 3 79, which improve the thermal insulation properties of the structure.

The aluminum frame profile 1 forms the front part and the side part of the frame structure and has a hexagonal, through-opening 13 for the hinge structure. In addition, grooves 21 are formed in the opening 13 for the pivot spring of the hinge structure. Attached to the frame profile 1 is a clamping strip 7, which forms the rear part of the frame structure and is preferably made of hard PVC plastic. This clamping strip 7 is in direct contact with the cold air of the cooling and freezing compartment and its thermal insulation properties are excellent compared to e.g. aluminum. In order to improve the insulating properties of the clamping strip 7, air ducts 14 are further formed in it. The clamping strip 7 has a projection 15 and the aluminum profile 1 has a groove 16 for receiving this projection, respectively. The clamping strip 7 can be fastened to the aluminum profile 1 with screws (not shown in the figures) which are screwed into the above-mentioned groove 16.

A resistor wire 17 is arranged at the bottom of the groove 16 in the aluminum frame profile 1. This resistor wire 17 is located close to the geometric center of the aluminum profile 1, so that heat is evenly distributed on the outer surfaces of the aluminum profile 1, preventing moisture from condensing on these outer surfaces.

The clamping strip 7 together with the aluminum frame profile 1 forms a U-shaped inner surface against which the U-profile strip 6 rests.

A bellows seal 18 with a magnet 19 is further attached to the clamping strip 7 to keep the glass door tightly and tightly closed.

Figure 3A shows, on an enlarged scale, a horizontal section from the lower left corner of the glass pane 2 shown in Figure 1. Figures 3A and 3B show diagrammatically how the electrode 6 79171 Θ is connected to a copper wire 22, which in turn is attached to an electrical wire (not shown in the figures) in a conventional manner, for example by means of a crimp connector. A groove 23 is formed in the electrically conductive surface 4 of the glass pane 2, e.g. with a diamond blade, in which a copper wire 22 is mounted. A screen printing is then performed using silver paste, which silver paste also fills the groove 23. Finally, hardening is performed, whereby the silver paste is vitrified on the surface of the glass. In this way, very good electrical conductivity is obtained and the copper wire 22 remains firmly attached to the groove 23.

The mounting tip described above in Figures 3A and 3B can also be realized by replacing the copper wire with a copper pin which is embedded in the surface of the glass in a certain recess.

The fastening methods described above also provide the advantage that when the glass breaks for some reason, the fracture occurs at a groove 23 or recess made in the glass surface, whereby the electrode also breaks at this point, making electrical contact with the electrically conductive layer 4 of the glass pane 2.

Figure 4 shows a hinge structure according to the invention mounted on a door. The hinge structure comprises a lower hinge 10 and an upper hinge 11. Figure 5 shows the structure of the lower hinge seen from above and Figure 6 shows the parts of the hinge structure according to the invention separately.

As indicated above, the frame profile 1 of a glass door according to the invention has a hexagonal through-opening 13, which further has grooves 21 for the hook-like end portion 35 of the rod-shaped pivot spring 34. A hexagonal lower hinge piece 24 and a hexagonal upper hinge piece 25 are arranged in this hexagonal opening the hinge pieces 24, 25 rotate with the door.

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The lower hinge piece 24 is rotatably mounted on a support piece 26 attached to a door frame structure or other support structure such as a floor. The hinge piece 24 has a cylindrical hole 2Θ into which a plastic sleeve 33 is fitted. The plastic sleeve 33 is in turn fitted with a cylindrical part 31 of the clamping member 30 of the pivot spring 34, which forms a hinge pin. The actual clamping member 30 is formed by a helical wheel 32 (curved globoid wheel). The lower end of the pivot spring 34 is flattened and inserted into a hole 46 in the clamping member 30, the lower part of which is slit-like, whereby the lower end of the pivot spring 34 moves only with the helical wheel 32.

The helical wheel 32 is fitted in a bore 38 in the support body 26. The support body 26 further has a bore 42 for a cylindrical clamping screw 43 (Fig. 5>, the teeth of which are suitable for the helical wheel teeth. The clamping screw 43 can tighten or loosen the swivel spring 34.

The support piece 26 also has a second bore 39 which is actuated if the door handle is changed.

A recess 40 is formed in the upper surface of the support member 26, and the hinge piece 24 has a protruding stop portion 36 which operates in this recess. The shape of the stop portion 36 determines the turning angle of the door, which is preferably about 100.

A locking lever 44 rotatable about a vertical axis is arranged in the recess 40 of the support part 26. The stop part 36 has a notch 45. When the door is open, the locking lever 44 can be turned so that its end is in the notch 45, whereby the door remains open, e.g. when filling a refrigerator or freezer. The door is closed by turning the locking lever 44 away from the notch 45, whereby the door closes automatically under the action of a spring force.

8 79171

The upper ear ana body 25 is rotatably mounted on an upper support body 27 attached to a door frame structure or other support structure. Also, the upper hinge body 25 has a protruding stop portion 37 which operates in a recess 41 in the support body 27. The hinge body 25 has a cylindrical hole 29 through which the electrical wires of the above-mentioned electrodes and the tow wire are drawn and passed through the support body 27.

The hinge structure according to the invention makes it possible to change the handiness of the door in a simple manner. In this case, the procedure is such that the electrical wires routed through the upper hinge 11 are disconnected from the attachment points outside the door structure and the support pieces 26 and 27 are removed. The lower hinge structure (parts 26, 30, 33, 24 and 34) is pulled out of the opening 13, whereby the hook 35 engages the electrical wires, whereby they are brought out at the lower hinge. Next, the upper hinge structure (parts 27 and 25) is pulled out of the opening 13. The door is then turned 180 ° and the ear hinge fields are placed in place and finally the support pieces 26 and 27 are fixed in place. When changing the handle of the door, the tightening screw 43 is also moved from the bore 42 to the bore 39.

Only a few preferred embodiments of the invention have been described above and it is clear that they can be modified within the scope of the claims.

Claims (14)

79171 g A glass door for use in refrigeration and frosting compartments, comprising a frame <1> and two or more glass panes <2, 3), the front glass pane (2) away from the refrigeration and freezing compartment being heated by an electrically conductive layer (4) inside the pane. ) in contact with electrodes (Θ, 9), which in turn are connected to a voltage source, and between the panes <2, 3) of which a spacer strip or strips (5) are arranged, characterized in that the glass panes (2, 3) are surrounded at its edges by a plastic U-profile strip (6), that the frame consists of a light metal profile strip <1> forming the front and side of the frame, and that a light plastic clamping strip (7) is attached to the light metal profile <1>, which together with the light metal profile (1) forms a U-shaped inner surface against which the U-profile strip (6) rests, and that the electrodes (8, 9) are fixed to the box (2) at a point between the intermediate strip (5) and the end edge of the box <2). Glass door according to Claim 1, characterized in that the electrodes (8, 9) are connected to the electrical conductors by means of copper wires <22) or pins which, at the electrodes, are embedded in grooves (23) or recesses in the screen surface (4). Glass door according to Claim 1 or 2, characterized in that the intermediate strip (5) is arranged at a distance from the end portions of the panes <2, 3). Glass door according to one of the preceding claims, characterized in that the space (12) between the intermediate strip (5) and the U-profile strip <6> is filled with sealing compound. Glass door according to one of the preceding claims, characterized in that the frame profile (1>) is heated by means of a resistance wire (17) or wires fitted to this profile. Glass door according to one of the preceding claims, characterized in that there are air gaps (20) between the U-profile strip <6) and the glass panes (2, 3). Glass door according to one of the preceding claims, characterized in that the clamping strip (7) is an air duct (14). Glass door according to one of the preceding claims, characterized in that the frame profile <1) has a vertical through-opening (13) in the hinge-side part for the hinge structure and electrical cables. g. Hinge structure for use in a glass door according to any one of the preceding claims, comprising a lower hinge (10) and an upper hinge (11), characterized in that the hinge structure comprises a lower support member (26) and an upper support member (27) attached to the door frame or other support structure a rotatable lower hinge piece (24) and an upper hinge piece (25) fitted in vertical openings (13) in the lower and upper part of the door frame structure (1) and rotatably mounted on said support members (26, 27) and a pivot spring (34) for automatically closing the door . Hinge structure according to claim 9, characterized in that at least the second hinge piece (24) has a through hole (28) and that the pivot spring (34) is arranged through said hole (28) so that its other end (35) is fitted in a frame structure. an opening (13, 21) rotating with the door and the other end being attached to a tension spring (30) of the pivot spring fitted in a bore (38) in the support member (26). Hinge structure according to Claim 10, characterized in that the clamping element (30) is formed by a helical wheel (32) and that the pivot spring (34) can be clamped cylindrically by means of a clamping screw (43) fitted in a horizontal bore in the support member (26). <39, 42) and whose teeth fit the sprocket <32> tooth support. Hinge structure according to Claim 11, characterized in that the helical wheel <32> has an axial cylindrical part (31) which extends into the hole <28) in the hinge body <24) and which forms a hinge pin. Hinge structure according to one of Claims 9 to 12, characterized in that the door-side part of the support element (26, 27) has a recess (40, 41) and in that the hinge body (24, 25) has a projecting stop part (36, 37) which acts in this recess and determines the turning angle of the door. Hinge structure according to Claim 13, characterized in that a rotatable locking lever <44) is arranged in the recess <40) in the support element (26), and in that the stop part (36) has a notch <45) for the locking lever <44) . 79171