DE10352742A1 - Refrigeration appliance with improved condensate removal - Google Patents

Abstract

To support the evaporation of condensation, a refrigeration device is provided with a to a collecting device (10, 11) connected to the condensate atomizer (14) for the condensed water.

Description

The The present invention relates to a refrigerator equipped with means for evaporation from in the device accumulating condensation water is equipped.

traditionally, is the condensation that is in a refrigerator at an interior cooling Evaporator accumulates over one Pipeline into an evaporation tray outside the refrigeration unit interior derived there to evaporate and released into the ambient air to become. The evaporation tray is usually on a compressor mounted on the refrigerator, so as to waste heat, the the compressor generates in operation, in the accumulated condensed water initiate and thus promote its evaporation.

The Optimization of energy consumption in modern refrigeration appliances has led to the waste heat emitted by the compressor under unfavorable circumstances is no longer sufficient to eliminate the accumulating condensation. For this there are there are different reasons e.g. an improved insulation of the refrigerator, which cause the Switch-on times of the compressor to an ever smaller proportion of take the total operating time of the refrigerator, or even improvements to the design of the compressor itself, improve its efficiency and thus its evaporation of condensed water available standing waste heat output reduce. Nevertheless, the accumulating during defrosting of the evaporator Being able to catch melted water in the evaporation tray is their capacity considerably increased.

There are also it refrigerators such as self-defrosting freezers or no-frost refrigerators, at Condensation only in bursts, but in larger quantities accrues, when the evaporator is specifically defrosted. To the amounts of condensed water, which may be incurred in such a refrigeration device, under all circumstances to be able to record is a big one Evaporation tray required, the space required at given Outside dimensions of the Refrigerating device at a charge the usable interior goes.

task The invention is therefore to provide a refrigeration device, with which it is possible is, even larger quantities of accumulating condensation space-saving and with minimal energy consumption to eliminate.

The Task is solved by that to a present in the refrigerator Collection device for the condensation is an atomizer is connected, which serves the condensation in the form of finest droplets into the ambient air. These droplets withdraw from theirs complete Evaporation required thermal energy of Ambient air and therefore do not burden the energy balance of the refrigerator.

This atomizer is preferably over arranged a collecting tray, which is able, generated by the atomizer To catch drops that are too big to evaporate immediately.

The Collection device is also preferably to a by a compressor heated Evaporation tray connected. Conveniently, this evaporation tray be arranged as a buffer from which the atomizer with Water is supplied.

A Such evaporation tray can expediently simultaneously above-mentioned drip tray for from the atomizer form generated drops.

one According to a first embodiment of the invention, the atomizer comprises a Atomizer nozzle and one Pump to press of condensed water through the atomizer nozzle.

there it may be an electrically driven pump, in particular a pump with a linearly movable piston and one in one Coil slidable solenoid for driving the piston.

The Pump can also be opened or closing a door be driven by the refrigerator, in which case a direct mechanical coupling of the pump to the movement of the door is suitable for driving the pump.

one According to a further embodiment of the invention, for atomizing the Condensed water a high-frequency oscillator, in particular an ultrasonic transducer, be used.

Is appropriate also a sensor for detecting a collected amount of condensed water and a controller that operates the atomizer whenever the detected collected condensed water quantity exceeds a limit value.

Further Features and advantages of the invention will become apparent from the following Description of exemplary embodiments with reference to the attached Characters. Show it:

1 a schematic section through an inventive refrigerator;

2 a schematic section through a pump sprayer of the refrigerator 1 ; and

3 a detail of a refrigerator according to the invention with an ultrasonic atomizer.

This in 1 schematically shown in section refrigeration device comprises a heat-insulating housing with a body 1 and a door hinged to it 2 that have an interior 3 enclose. At the back of the through a plurality of shelves 4 in compartments divided interior 3 is an evaporator 5 arranged. The evaporator 5 is shown here as a plate-shaped body between one's interior 3 confining wall of insulating tank of corpus 1 and a thermal insulation material 6 is inserted. A refrigerant circuit extends from a high pressure outlet of a compressor 7 via an outside at the back of the body 1 attached liquefier 8th and the evaporator 5 to a suction port of the compressor 7 , The compressor 7 is in a ground level niche 9 at the back of the body 1 below the evaporator 5 accommodated.

Humidity from the interior 3 , which by the evaporator 5 cooled wall condenses, collects at the bottom of this wall in a gutter 10 and reaches from there through a through the thermal insulation material 6 guided drain pipe 11 an evaporation tray 12 that on the compressor 7 is mounted to be heated by its waste heat.

An intake manifold 13 a pump sprayer 14 dives into the evaporation tray 12 one. The structure of the pump sprayer is described below with reference to 2 explained in more detail. It creates above the evaporation tray 12 From this aspirated condensation a fine mist whose droplets evaporate quickly due to their small size. They are in the niche 9 generated humidity is flushed away by an air flow, which, driven by that of the condenser 8th in a fireplace between the back wall of the carcass 1 and an opposite, not shown furniture or building wall, first by one along the underside of the body 1 guided intake duct 15 , then through the niche 9 and finally over the fireplace into the open.

2 shows an example of a possible construction of the pump sprayer 14 , The intake manifold 13 flows into a pumping chamber 16 in which a piston 17 is movable back and forth. When the piston 17 is at rest, a check valve is closed, which is shown here as a ball 18 that of a leaf spring 19 against a valve seat 20 at the inlet of the pumping chamber 16 is kept pressed.

In the flask 17 extends a line 21 from the pumping chamber 16 to an atomizer chamber 22 , in which incoming condensation is strongly swirled before it passes through a fine nozzle opening into the open air and there to a mist 23 atomized.

The piston 17 is with the help of a magnet 25 displaceable, which in a current acted upon coil 24 is kept movable. If the coil 24 with current in a suitable direction is applied, so that the magnet 25 the piston 17 into the pumping chamber 16 into it, pushing to the right in the figure, becomes a high pressure in the pumping chamber 16 constructed, which causes water to flow through the pipe 21 flows and is atomized.

If the magnet 25 is moved to the left, drives a compression spring 26 , shown here as a coil spring surrounding the pumping chamber, the piston 17 to the outside, so that the check valve opens and fresh water through the intake manifold 13 is sucked. This is how it works with every movement cycle of the magnet 25 one the stroke of the piston 17 corresponding amount of water atomized.

A modification, not shown, according to the piston 17 and the magnet 25 rigidly connected or even formed in one piece. In this modification, the compression spring 26 omitted because of the magnet 25 also capable of the movement of the piston 17 from the pumping chamber 16 to drive out. At the movement of the piston 17 into the pumping chamber 16 Therefore, it needs no counterforce of the compression spring 26 to be overcome, and the pressure in the pumping chamber 16 can be constructed, is the same design and energization of the coil 24 increased.

It may be provided a control circuit, in each case after a predetermined period of time, the coil 24 energized to one or more cycles of motion of the magnet 25 drive. According to a further development, this control circuit also detects or controls the operation of the compressor 7 and actuates the pump at the end of the predetermined period each time only when the compressor is in operation or has already run for a certain amount of time to ensure that the atomized water is soon dissipated by the above-mentioned air flow.

The control circuit can also respond to a movement of the door 2 be coupled to detect them and, instead of after the predetermined period of time, in each case after a given first number of door opening or closing operations a second given number of movement cycles of the magnet 25 drive.

As another alternative, a water level sensor on the evaporation tray 12 be provided, which provides a signal indicating whether the water level in the shell 12 exceeds a predetermined limit or not, and the control circuit drives so long back and forth movements of the magnet 25 how the detected water level is above the limit.

According to another modification, the coil can 24 and the magnet 25 be replaced by a lever mechanism, which is in response to a movement of the door 2 coupled and, for example, through the intake passage 15 can extend. This is how a user drives the door every time he opens and closes 2 at the same time a cycle of movement of the piston 17 at.

3 schematically shows a section through a on a compressor 7 mounted evaporation tray 12 according to a second embodiment of the invention. On the surface 27 in the shell 12 collected water is an annular float 28 , the one ultrasonic generator 29 at a fixed, short distance below the water surface 27 holds. The ultrasound generator 29 is of a known type, as z. B. is commonly used in humidifiers. It acts as a nebulizer, giving off ultrasonic energy to the water above it, causing a mist of fine drops from that of the annular float 28 surrounded water surface rises.

The unit of swimmers 28 and ultrasound generator 29 is at one with a switch 30 connected swivel arm 31 held. When the water level rises above a given threshold, the switch closes 31 and supplies the ultrasound generator 29 with energy until the water level has fallen below the limit again. So long as the water level is low, so only the waste heat of the compressor 7 used to evaporate the collected condensation. Only when the water level reaches a critical level, the ultrasonic generator 29 switched on to support the evaporation and overflow the evaporation tray 12 excluded.

The swimmer 28 , the swivel arm 31 and the switch 30 form a water level sensor, which - without ultrasonic generator - also as the above in conjunction with 2 mentioned water level sensor can be used.

Claims (9)

Refrigerating appliance with a collecting device ( 10 . 11 ) for condensed water, characterized in that to the collecting device ( 10 . 11 ) an atomizer ( 14 ; 29 ) is connected to the condensation water. Refrigerating appliance according to claim 1, characterized in that the atomiser ( 14 ) over a drip tray ( 12 ) is arranged Refrigerating appliance according to claim 1, characterized in that to the collecting device ( 10 . 11 ) further by a compressor ( 7 ) heated evaporator shell ( 12 ) connected. Refrigerating appliance according to claim 2 and claim 3, characterized in that the drip tray ( 12 ) and the evaporator shell ( 12 ) are identical. Refrigerating appliance according to one of the preceding claims, characterized in that the atomiser ( 14 ) an atomizing nozzle and a pump ( 16 . 17 . 25 ) for pressing the condensed water through the atomizer nozzle. Refrigerating appliance according to claim 5, characterized in that the pump ( 16 . 17 . 25 ) a linearly movable piston ( 17 ) and one in a coil ( 24 ) displaceable lifting magnets ( 25 ) for driving the piston ( 17 ). Refrigerating appliance according to claim 5, characterized in that the pump by opening and / or closing a door ( 2 ) of the refrigerator is driven. Refrigerating appliance according to one of claims 1 to 4, characterized in that the atomizer ( 29 ) is formed by a high-frequency oscillator. Refrigerating appliance according to one of the preceding claims, characterized by a sensor ( 28 . 30 . 31 ) for detecting a collected condensed water amount and a control device for operating the atomizer ( 14 ; 29 ) when the detected amount of condensed water exceeds a limit.