WO2008046847A1

WO2008046847A1 - Cooling device with cold water dispenser

Info

Publication number: WO2008046847A1
Application number: PCT/EP2007/061070
Authority: WO
Inventors: Kasim Yazan; Peter Nalbach; Bernd Heger; Klaus Flinner; Adolf Feinauer; Irene Dumkow; Martin Buchstab; Marek Myszko; Craig Duncan Webster; Nathan Wrench
Original assignee: BSH Bosch und Siemens Hausgeräte GmbH
Priority date: 2006-10-19
Filing date: 2007-10-17
Publication date: 2008-04-24
Also published as: EP2082177A1; DE102006049398A1

Abstract

A cooling device has an inner cavity (3) for storing cooled goods, a water intake connection, a tap point (5) for cooled water, and a water cooler (9) arranged in a water pipe (4) between the water intake connection and the tap point (5). The water cooler (9) comprises a container for a liquid or solid heat storage medium and a water pipe section (14) guided in thermal contact with the heat storage medium.

Description

Refrigerating appliance with cold water dispenser

The present invention relates to a refrigeration device having an interior for storing refrigerated goods, in particular a domestic refrigerating or freezing device, which has a water inlet connection, a tapping point for cooled water and a water cooler arranged on a water line between water inlet connection and tapping point. Devices of this type, which can be connected to a drinking water network to supply a user with chilled water at any time and without the need to refill containers, are becoming increasingly popular.

Conventionally, the water cooler is realized as a tank which can be filled with water from the water inlet connection and which is in thermal contact with the interior space in order to cool the water contained therein. A disadvantage of such a water cooler is that, when water flows out of the tapping point, uncooled fresh water immediately flows into the tank, and when it mixes with the cold water already in the tank, it causes the temperature of the tapped water to fall begins to rise after tapping a small amount. If the inflowing water does not mix with the chilled water in the tank, the temperature of the tapped water rises abruptly as soon as the tank contents are completely replaced.

The cooling of the tank contents takes place by the air of the interior heated to the tank contents and the absorbed heat gives off to an evaporator. The heat exchange through the air of the interior is slow, especially when between the tank and the interior still an insulating layer is provided, so that in the tank nachgeströmtes fresh water takes a long time to cool.

Object of the present invention is to provide a refrigeration device that allows the tapping of larger amounts of cooled water or rapid cooling of nachströmendem fresh water.

The object is achieved by a refrigeration device with an interior for storage of refrigerated goods and with a water inlet port, a Refrigerated water tap and a arranged on a water line between the water inlet port and tap water cooler of the water cooler comprises a container for a liquid or solid heat storage medium and a guided in thermal contact with the heat storage medium water pipe section. The liquid or solid heat storage medium allows a much faster heat exchange than the air of the interior, so that water can be cooled in the flow through the water cooler to a desired drinking temperature. A tank for the water is not required.

By the heat storage medium having a melting point above 0 ⁰ C and a refrigerator of the household refrigerator is designed to freeze the heat storage medium, a small amount of the heat storage medium is sufficient to cool a large amount of water by receiving heat of fusion. The water cooler can therefore be constructed compact.

In order to allow a quick heat exchange, the water line section is preferably passed through the heat storage medium.

By descending in the direction of flow in the direction of flow in thermal communication with the heat storage medium, it can be achieved that substantially only water is present in the water conduit section during the tapping operation. As a result, the risk of freezing of the water line section is reduced, even if the heat storage medium should reach a temperature below 0 ⁰ C.

In order to accommodate a long water pipe section in a compact water cooler, the latter is preferably helical.

Furthermore, the water pipe is preferably sloping between the water cooler and the tapping point, so that at the end of a tapping process water from the water pipe section of the water cooler or the adjoining water pipe can flow completely out of the refrigerator. Such a drain is further facilitated by the fact that the water pipe is kept free from the water cooler of shut-off elements.

In order to facilitate the emptying of the water line section, a ventilation opening is preferably formed on the water line between the water inlet connection and the water cooler.

A valve suitably arranged on the ventilation opening prevents the escape of water through the ventilation opening.

Further features and advantages of the invention will become apparent from the following description of embodiments with reference to the accompanying figures. Show it:

1 shows a schematic section through an inventive refrigeration device.

2 shows an enlarged detail of the refrigeration device in section according to a first embodiment;

3 shows an enlarged section through the tap and its surroundings. and

Fig. 4 shows the same detail as Fig. 2 according to a second embodiment.

Fig. 1 shows a section through an inventive refrigerator with a body 1 and a door 2, which enclose an interior space 3 for storage of refrigerated goods. A per se known, not shown in the figure chiller comprises an evaporator for cooling the interior 3, which is arranged communicating, for example, on a rear wall of the interior 3 or in a separated chamber from the interior 3 and the interior 3 via a forced ventilation. The refrigerator may be a refrigerator or freezer.

A water pipe 4 extends from a drinking water mains connection, not shown, through the walls of the body 1, a hinge connecting the door 2 to the body 1, and the door 2 itself to a tapping point 5 which is located in a door 2 formed, outwardly open niche 6 is arranged. A check valve 8 disposed on the water pipe 4 is operable by a switch 8 disposed in the niche 6 to detect the presence of a container to be filled in the niche 6 and to release the flow of water through the check valve 7 only when a container is in the niche 6 is detected. In the illustration of Fig. 1, the switch 8 has an arm 9 which is displaced by a placed in the niche 6 container against the rear wall of the niche 6 and thereby actuates the switch 8 and the check valve 7 opens. Alternatively, a control button 10 may be provided for opening and closing the check valve 7 on the outside of the door.

Downstream of the check valve 7, the water pipe 4 enters a water cooler 9. The water cooler 9 is a container embedded in an insulating material filling the door 2, which is filled with a solution whose freezing point is just above 0 ⁰ C. The thicknesses of insulating layers 12, 13, which separate the water cooler 9 on the one hand from the interior 3 and on the other hand from the environment, are so dimensioned when the device is placed in a normal temperature room and the interior 3 is kept at a normal operating temperature, the solution freezes, but their temperature remains above 0 ⁰ C.

A portion 14 of the water pipe 4 extends within the water cooler 9 helically down to the arranged on the ceiling of the niche 6 tapping point 5. The running through the radiator 9 section 14 is integral with a downhill through the insulating layer of the door 2 to the tapping point 5 extending line section

15 formed, and both line sections 14, 15 are free of check valves or other obstacles that could hinder a free flow of water from the water cooler 9 to the niche 6.

When the check valve 7 is open, water flows through the line section 14, cools down and has, when it reaches the tap 5, substantially assumed the temperature of the solution. The solution is gradually melted by the water flowing through it, whereby the water cooler 9 is able to absorb a large amount of heat energy without warming up beyond the freezing point of the solution. Even though the solution around the coiled conduit section 14 has melted, convection of the solution maintains efficient heat exchange persist until the solution is completely thawed. Thus, a large amount of water can be tapped in a short time and at a substantially constant temperature.

The cross-section of the line sections 14, 15 can be chosen so large that when the check valve 7 closes, air at the tap 5 penetrates into the line and the water contained in the sections 14, 15 gradually drains. By the not acted upon by the pressure of the drinking water network pipe sections 14, 15 are empty when no water is tapped, it is ensured that the water is regularly replaced completely in the line 4 by using the tap. Unlike a permanently filled tank, germ growth that would affect the quality of the tapped water can be safely avoided.

Fig. 2 shows a section through a portion of the water pipe 4 between the check valve 7 and the water cooler 9 according to a first preferred embodiment of the invention. At the outlet of the check valve 7, a nozzle 16 is formed, which directs a water jet through a chamber 17 to a leading to the water cooler 9 drain opening 18 in a nozzle 16 opposite wall of the chamber 17. If, as shown in Fig. 1, the check valve 7 is embedded in the immediate vicinity of the water cooler 9 in the door 2, connects a passage 19, the chamber 17 with the interior 3. Alternatively, the passage 19 could also lead to the outside.

When water is tapped and the check valve 7 is open, the chamber 17 behaves similar to a water jet pump; Although air can be sucked through the passage 19 into the chamber 17, but there is no water from the passage 19 from. By air 7 flows after the blocking of the valve 7 through the passage 19 into the chamber 17, the water from the cooler 9 can flow quickly into a placed in the niche 6 container.

As shown in FIG. 3, the conduit portion 15 connecting the radiator 9 to the tapping point 5 slopes down and, like the conduit portion 14, is free of flow obstructions such as bottlenecks or valves that might retain water in the conduit portion 14 or 15. Thus, the line sections 14, 15 empty quickly and completely after each dispensing operation. In the embodiment of FIG. 2, it may possibly come to a backwater of water, if the flow resistance of the line sections 14, 15 is not small enough. A further developed embodiment, which prevents the escape of water in such a case, is shown in Fig. 4 in a similar to Fig. 2 section. The chamber 17 is omitted here; Instead, the passage 19 branches off from the line 4 extending directly from the check valve 7 into the water cooler 9. On protruding into the passage 19 projections 20 rests a spherical float 21, and above the float 21, a valve seat 22 is formed. As water accumulates in the conduit 4 downstream from the check valve 7, it enters the passage 19, lifts the float 21 from the projections 20 and pushes it against the valve seat 22. This obstructs the passage 19 and forces the water to flow. to flow through the radiator 9. If, after closing the check valve 7, the pressure on the line 4 decreases, the float 21 moves away from the valve seat 22, and the air flowing past the float 21 through the passage 19 facilitates complete emptying of the line sections 14, 15.

Claims

claims

1. Refrigerating appliance with an interior space (3) for storing refrigerated goods and having a water inlet connection, a tapping point (5) for cooled water and a water pipe (4) between water inlet connection and tapping point (5) arranged water cooler (9), characterized in that the water cooler (9) comprises a container for a liquid or solid heat storage medium and a water line section (14) guided in thermal contact with the heat storage medium.

2. Refrigerating appliance according to claim 1, characterized in that the heat storage medium has a melting point above 0 ⁰ C and that a refrigerator of the household refrigerator is designed to freeze the heat storage medium.

3. Refrigerating appliance according to claim 1 or 2, characterized in that the water line section (14) is passed through the heat storage medium.

4. Refrigerating appliance according to one of the preceding claims, characterized marked, that guided in thermal contact with the heat storage medium

Water line section (14) in the flow direction is sloping.

5. Refrigerating appliance according to claim 4, characterized in that the water line section (14) is helical.

6. Refrigerating appliance according to claim 4 or 5, characterized in that the water line (4, 15) between the water cooler (9) and the tapping point (5) is sloping.

7. Refrigerating appliance according to one of the preceding claims, characterized in that the water line (4) from the water cooler (9) is free of shut-off elements.

8. Refrigerating appliance according to one of the preceding claims, characterized in that on the water line (4) between the water inlet connection and the water cooler (9), a ventilation opening (19) is formed.

9. Refrigerating appliance according to claim 8, characterized by a at the ventilation opening

(19) arranged valve (21, 22).