DE3300743A1 - Heat pump with a defrosting device for the evaporator - Google Patents

Abstract

In heat pumps in which heat is taken from the air, icing of the evaporator very easily occurs and reduces the efficiency of the heat pump. To eliminate this icing, the heat pump is stopped, or an additional circuit is provided, while a medium is heated in the condenser, and this heated medium is passed through the evaporator, or the heat pump is reversed. All three measures lead to an interruption of the heating system and moreover also to heat being taken out of the heating circuit. According to the invention, it is proposed to provide in a heat pump a heat source, especially an infrared emitter, arranged upstream of the evaporator in the direction of flow of the air and directed towards the evaporator. The ice is thawed from the evaporator by the emitter. At the same time, however, the medium flowing through the evaporator also takes up a considerable portion of the heat radiated to the evaporator.

Description

Heat pump with a defrosting device for the evaporator

The invention relates to a heat pump for extracting heat from the air with a defrosting device for the evaporator.

In heat pumps, where the heat is drawn through the evaporator Air is extracted, it is very easy for the evaporator to fall below the Dew point of the air. The precipitated water hits the outside of the evaporator down and freeze.

This icing up of the evaporator increases the air throughput reduces or completely prevents the vaporizer, which is equivalent to a reduction or prevention of heat exchange between the air and that in the heat pump circulating medium is.

In order to eliminate this over stand it has already been suggested that the Shut down the heat pump for a period of time that is sufficient by means of the to defrost the ice through the air passing through the evaporator. This measure has the Disadvantage that it is not possible to heat during defrosting and the shortfall after must also be applied by the heat pump after defrosting.

It has also been proposed to use one condenser and evaporator additional cycle to see by adding a medium in the condenser heated and this heated medium is then passed through the evaporator, where it is thaws the ice on the outside of the evaporator. At. this design will not all the heat extracted from the air is used for the intended purpose.

Part of this heat is needed to defrost the evaporator, so that the output of the heat pump must be greater than required for the intended purpose.

Finally, it has also been suggested that the cycle should be used for defrosting reverse the heat pump.

Here, however, the heat required for thawing must be returned to the medium be taken, which by means of the heat taken from the air via the circulatory system the heat pump has been heated up. With this design, therefore, during defrosting No heat is supplied to the medium to be heated, on the contrary, it is supplied to this Medium heat taken.

Heat pumps are generally sufficient during the frost period in the Winter months are not used to heat a house. It is generally a second Heating system, e.g. one with gas, coke or oil or the like. Fuel-operated boilers, necessary.

The object of the present invention is to provide a heat pump of the initially mentioned to create mentioned type, in the case of the defrosting of the evaporator no heat from the Heat pump system must be withdrawn.

This task is performed with a heat pump of the type mentioned at the beginning in particular solved by an in the flow direction of the air upstream of the evaporator arranged, directed at the evaporator heat source.

If the evaporator is iced up, the heat source is put into operation, until the ice has thawed from the evaporator. Then this heat source is shut down again. This heat source is rarely required during the summer months. In the winter months however, it may happen that this heat source is in operation almost continuously is.

A particularly suitable heat source is a Radiant heater, above all an infrared heater, expediently a gas-heated one. For the gas heated Infrared heater can be used with liquid gas.

A water collecting basin is arranged under the evaporator, in which the water generated during defrosting is collected. This water catchment basin should have a water drain that is led through the housing to the outside. If the heat pump is in the cellar or outside above the surface of the earth, that can Water can easily be fed into the basement drain or flow off freely. However, if the heat pump is embedded in the ground, it is possible to which is expediently tubular to connect to the sewer system.

For the sake of simplicity, the heat source should be on the air inlet nozzle be arranged of the evaporator. The heat given off by the heat source faffill then directly on the vaporizer.

It is useful to prefabricate the heat pump according to the invention in the factory. There are then the compressor, condenser and evaporator with the in the direction of flow in front of these arranged heat source as well as the compressor, condenser and evaporator connecting pipes and furthermore the drive and the fan for suction the air through the evaporator in an open housing on the side of the heat source arranged.

Has on the side of the evaporator facing away from the heat source The housing has slots or the like, through which the cooled air can exit again can. Under the evaporator is the water collecting basin with a functional ' arranged tubular water drain, which leads through the housing. The condenser is designed as a heat exchanger and has feeds through the housing for the medium to be heated and discharges for the heated medium. The water drain, the inlets and outlets are provided with corresponding connecting pieces. The heat source, in particular the gas-heated infrared heater, is also in this Embodiment provided with a lead through the housing for gas supply, which has a corresponding Has connecting piece.

Further features of the invention are in the description of the figures shown, it being noted that all individual features and all combinations of individual features are essential to the invention.

In Figures 1 and 2, the invention is exemplified by embodiments shown without being limited to these embodiments.

Fig. 1 shows a vertical section through an embodiment, with an air inlet nozzle open at the top and FIG. 2 shows an embodiment with a laterally open air inlet nozzle.

In the embodiment according to FIG. 1, the housing 6 is in the upper end a heat source 2 is arranged, in the illustrated embodiment an infrared radiator.

This infrared heater is heated via the supply line 12, which is on the side is guided through the housing 6 to the infrared radiator 2. Above the heat source 2 the housing 6 is open. A grate 13 is inserted into the opening.

The upper end of the housing 6 forms the air inlet nozzle 4. Below of the heat source 2, the evaporator 1 is arranged in the housing 6. Between the evaporator 1 and heat source 2 is a fan 14, with which the air through the The grate 13 and the heat source 2 are sucked in and pushed through the evaporator 1 will. Below the evaporator 1, the housing 6 has lateral slots 15 through which the air exits again. Below the evaporator 1 is a water collecting basin in the housing 6 3 arranged, in which the condensation water is collected. This water catchment basin 3 should be inclined to one side or, in particular, a corner. At one, preferably the deepest The 'water catchment basin'.i3 has a water drain 5, which is passed through the housing 6. Is this water drain 5 above the The water can run off freely on the ground or above the basement floor, because it then gets into the ground or into the basement drain. Is this water drain 5, however, in such a way that the water is fed directly into the sewer system, are appropriate Connection sleeves provided to which the connection line to the sewer system is connected can be. The compressor 7, the condenser, is located at the bottom of the housing 6 8 and the drive 1.6. The drive 16 is known per se, not shown Connected to compressor 7 and / or condenser 8. The evaporated in the evaporator 1, heat transfer medium is through the pipe 9 from the evaporator 1 to the '.. compressor 7 supplied and compressed here in a known manner, not shown. From the compressor 7, the heat-transferring medium passes through line 17 into condenser 8. The condenser 8 is not explained in more detail as a heat exchanger known per se.

The medium to be heated is fed through the feed line 10 and cools in the condenser the heat-transferring medium, so that this' condenses and becomes then diverted again through the discharge 11. The feed 10 and the discharge 11 have corresponding connection pieces to which the corresponding pipelines be connected. The heat transfer medium cooled in the condenser 8 is returned through line 18 to the evaporator, creating a new cycle begins.

In the embodiment according to FIG. 2, the air inlet connection piece is 4 closed at the top and open on one side. A grate 13 is inserted into the opening.

Behind the opening is the evaporator 1, which is from below is inclined away from the grate 13 at the top. Between the grate 13 and the evaporator 1 is the heat source 2 inclined in the same way, expediently an infrared emitter arranged. On the side facing away from the grate 13 is located in the wall of the Ge housing 6 has an opening 15 in the direction of flow of the air the fan 14 is located behind the evaporator 1.

The reference symbols in FIG. 2 otherwise correspond to the reference symbols in Fig. 1.

The housing 6 can be divided below the water collecting basin 3. If such a division is made, the upper part 6 and the lower part 19 arranged separately from each other and even set up in different rooms be. The connecting lines between, evaporator 1 and compressor 7 and between Condenser 8 and evaporator 1 are then correspondingly long and connect the two Housing 6 and 19 together.

In the embodiment according to FIG. 2, the Air inlet from above, if by appropriate arrangement of each Components and, if necessary, additional arrangement of baffles are taken care of is that the air is passed through the evaporator 1.

With the heat source according to the invention, a considerable amount of heat can be generated to the heat pump.

The invention therefore makes it possible to use a second heating system to refrain and especially in the case of frost in the winter months about the out of the Heat extracted from the air additionally required amount of heat via the heat source of the To supply heat pump. If the heat source is a gas-heated infrared heater, must the operator of the system only needs an additional gas tank or an additional one Provide gas connection.

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Claims (8)

Claims' eX heat pump for extracting heat from the air 1 pure defrosting device for the evaporator, g e k e n n z e 1 c h n e t d u r c h one arranged upstream of the evaporator (1) in the flow direction of the air the evaporator (1) directed heat source (2). 2. Heat pump according to claim 1, characterized in that the heat source (2) is a radiant heater. 3. Heat pump according to claim 2, characterized in that the radiant heater (2) is an infrared radiator. 4. Heat pump according to claim 3, characterized in that the infrared radiator (2) is gas heated. 5. Heat pump according to one or more of claims 1 to 4, characterized characterized in that a water collecting basin (3) is arranged under the evaporator (1) is. 6. Heat pump according to one or more of claims 1 to 5, characterized characterized in that the heat source (2) in the air inlet connection (4) of the evaporator (1) is arranged. 7. Heat pump according to claim 5, characterized in that the water collecting basin (3) has a water drain (5) through the housing (6) to the outside. 8. Heat pump according to one or more of claims 1 to 7, characterized characterized in that the compressor (7), condenser (8), evaporator (1) with the in Direction of flow in front of this arranged heat source (2) and Connect the fan (14) and the compressor (7), condenser (8) and evaporator (1) Pipelines (9,17,18) in a housing that is open on the side of the heat source (2) (6) are arranged, under the evaporator (1) a water collecting basin (3) with a appropriately tubular water drain (5) is arranged through the housing (6), the Condenser (8) is designed as a heat exchanger and guided through the housing (6) Feeds (10) for the heated medium and discharges (11) for the heated medium having.