EP0547310A1 - Two-temperature household refrigeration apparatus with a single cycle - Google Patents

Abstract

In a two-temperature household refrigeration apparatus with a single cycle, with an evaporator (15) which has essentially two sections (A, B) and forms a system of continuous refrigerant ducts, and the first section (A) of which, which forms a ceiling (16), an upright wall (17) and a bottom (18) of a freezing compartment (11), is connected upstream of its second section (B) which serves as spatial evaporator in a normal refrigerating compartment (13) arranged below the freezing compartment, the refrigerant supplied into the duct system from the injection point flowing from a supply duct (23) running downwards in the upright wall of the first evaporator section into a duct (27, 28) which is laid in the meander-like bottom of the freezing compartment and which opens into an outlet duct (31) which rises in the upright wall of the first evaporator section and which in the ceiling (16) passes into a duct arrangement (36, 37) which is laid in coils and the outlet of which is connected, with a downwardly directed duct section (38) in the upright wall, to the inlet of the side section forming the spatial evaporator, the supply duct (23) and the outlet duct (31) are connected via a bypass (35) which is arranged at a distance above the bottom of the first evaporator section and which has a raised flow resistance in relation to the bridged duct arrangement. <IMAGE>

Description

The invention relates to a two-temperature single-circuit refrigerator for the household, with an evaporator which essentially has two sections and forms a system of connected refrigerant channels, the first section of which forms a ceiling, an upright wall and a bottom of a freezer compartment, as a room evaporator in one section serving below the freezer compartment is connected upstream, the refrigerant supplied from the injection point into the channel system flowing from a downward-running supply channel in the upright wall of the first evaporator section into a channel arranged in a meandering manner in the bottom of the freezer box and flowing into a channel in the upright wall of the first evaporator section leading discharge channel opens, which merges in the ceiling in a channel arrangement laid in turns, the output of which is directed downward in the upright wall with the input d it is connected to the second section forming the space evaporator.

Due to the peculiar series connection of such an evaporator construction between freezer compartment evaporator and refrigerator compartment evaporator, the freezer compartment evaporator being connected upstream of the refrigerator compartment evaporator, it can happen that even during the defrosting phase with the refrigerant compressor at a standstill, as a result of pressure differences prevailing in the refrigerant system, drops of liquid refrigerant evaporator from the refrigeration compartment evaporator to the common refrigeration compartment evaporator from the freezer compartment Connection point can be pressed. When the liquid refrigerant enters the connection point to the warmer refrigerator compartment evaporator, the refrigerant evaporates there immediately, so that the temperature at this point does not exceed the melting temperature of the ice until the refrigerant compressor starts up again. This results in permanent icing at the critical connection point, which increases over time, the removal of which would mean the cooling unit being temporarily shut down.

From DE-PS 31 34 300 an evaporator for a two-temperature single-circuit refrigerator is known, which has a freezer compartment and a section associated with its normal refrigerator compartment. The freezer evaporator upstream of the defrostable normal refrigerator compartment evaporator in the refrigerant circuit is formed from an upright wall provided with refrigerant channels and two legs bent in the same direction, which serve as a ceiling and a floor and are also equipped with refrigerant channels.

The channel structure in the bottom of this evaporator essentially has three interconnected sections, each of which is formed from two large-volume pipelines communicating with one another via transverse channels, the predominant length of which is arranged perpendicular to the free end of the bottom. One of the three sections is connected on the outlet side in the floor to two parallel duct strands that are connected to each other in the upright wall via a transverse duct and merge into a single, refrigerant duct laid in turns in the ceiling.

Due to the channel arrangement of the evaporator, when the refrigerant compressor is at a standstill, a first separation between the gaseous and liquid fractions of the refrigerant flow in the floor and in the upright wall is to take place, the large-volume pipelines in the floor serving as collectors for the liquid refrigerant. A further separation of the gaseous from the liquid refrigerant is to be achieved by the inclined arrangement of the ceiling with respect to the upright wall, the liquid refrigerant following gravity flowing back into the bottom of the freezer compartment evaporator. In the event that refrigerant flows in from the condenser, pressure is exerted on the liquid refrigerant that has accumulated in the front area of the floor due to the manufacturing process and completely fills the channels. Since the individual sections of the channel arrangement in the floor are always connected to one another only via a single line, the pressure inevitably propagates to the section connected on the outlet side to the parallel channel lines and pushes the accumulated liquid volume into the parallel channel lines arranged in the upright wall. If refrigerant flows from the condenser to the evaporator over a longer period of time, For example, as a result of the cooling of the refrigerant compressor, there is a risk that, despite the elaborate measures taken, grafts of liquid refrigerant will reach the connection point between the freezer compartment evaporator and the normal refrigeration compartment evaporator and evaporate there, so that the connection point is constantly iced up despite cyclical defrosting.

The invention has for its object to design the channel system in the freezer evaporator in refrigerators of the type mentioned so that it is ensured at all times that no liquid refrigerant reaches the connection point between the freezer evaporator and the refrigerator compartment evaporator during the downtime of the refrigerant compressor.

The object is achieved according to the invention in that the feed channel and the discharge channel are connected via a bypass arranged at a distance above the bottom of the first evaporator section, which has an increased flow resistance compared to the bridged channel arrangement.

The solution according to the invention ensures that the pressure generated by the refrigerant flowing in from the condenser to the evaporator when the refrigerant compressor is at a standstill, for example caused by the cooling refrigerant compressor, is reduced without the liquid refrigerant resting in the bottom of the freezer compartment evaporator in the bottom of the freezer compartment evaporator can have an influence, so that no liquid refrigerant reaches the connection point between the two evaporator sections even over long periods of time. Furthermore, the Cooling capacity in the cooling compartments is not affected by the bypass. In addition, standing time noises caused by air bubbles rising from the liquid refrigerant are significantly reduced.

According to a further advantageous embodiment of the object of the invention, it is provided that the bypass connecting the feed channel to the discharge channel and having a higher flow resistance is arranged in the ceiling of the first evaporator section.

A solution according to these features has the advantage that the pressure propagating from the condenser to the evaporator is diverted to the refrigerator compartment evaporator shortly after it has entered the ceiling.

According to a further advantageous embodiment of the subject matter of the invention, it is provided that the increased flow resistance of the bypass is determined by a corresponding length arranged in turns and / or in particular by a reduction in cross section.

This solution has the advantage that the parameters defining the flow resistance are simple and economical to manufacture and also have good, constant accuracy.

Without production-related, complex additional measures and within narrow tolerance limits, the channels of the bypass are sufficiently large when the flow resistance differs from the rest of the channel arrangement if, according to a preferred embodiment of the object of the invention it is provided that the channel cross sections of the bypass and the feed channel are in a ratio of 1: 3 to 1: 7, but preferably in a ratio of 1: 5.

According to a next preferred embodiment of the subject matter of the invention, it is provided that the supply channel has a main channel and at least one secondary channel running parallel thereto, the main channel being equipped with transverse channels which branch off approximately perpendicularly from it and are spaced apart from one another and which is fluidically connected to the secondary channel connect.

Such a solution has the advantage that an uneven distribution, which is essentially independent of the channel cross section of the main channel and the feed channel, occurs as a result of the inertia of the refrigerant flowing into the feed channel, so that essentially the main channel is exposed to liquid refrigerant, while the secondary channel has hardly any liquid Refrigerant leads.

According to a further preferred embodiment of the subject matter of the invention, it is provided that the discharge channel has a main channel and at least one secondary channel running parallel thereto, the main channel being equipped with transverse channels which branch off approximately perpendicularly from it and are spaced apart from one another and which is fluidically connected to the secondary channel connect.

The advantage here is that gaseous inclusions within the liquid refrigerant stream can escape with simple means, according to the laws of gravity, without these pushing grafts of liquid refrigerant in front of them.

According to a further preferred embodiment of the subject matter of the invention, it is provided that both the transverse channels of the feed channel and those of the discharge channel are at a distance from one another which is greater than the height of the upright wall, but is preferably dimensioned such that the transverse channels are in the vicinity of the transition lie on the upright wall in the floor or in the ceiling.

The solution has the advantage that both the feed channel and the discharge channel are guided in two strands over the bending zones of the U-shaped evaporator section, so that the cross section of the two channels can be reduced compared to a single channel, whereby the influence on their flow cross section by constriction is considerably reduced , and thus the transitions do not have a flow-restricting effect on the circulating refrigerant.

The channel cross sections of the supply and discharge channels are particularly expedient if, according to a preferred embodiment of the subject matter of the invention, it is provided that the main and the secondary channel of the supply and discharge channels have the same cross section.

The liquid refrigerant is significantly more difficult to enter the bypass if, according to an advantageous embodiment of the subject of the invention, that the transverse channel of the supply channel branches in the ceiling with the bypass in such a way that the refrigerant is able to enter the bypass after a sharp deflection.

According to a next preferred embodiment of the subject matter of the invention, it is provided that the main channel of the discharge channel merges downstream with its branching transverse channel in the ceiling into a collector-shaped channel section which is provided with button-like impressions and is arranged parallel to the free end of the ceiling.

The advantage of such a solution is that, in addition to a further possibility of separating the gaseous liquid refrigerant, there is also an additional collection volume for liquid plugs which may be pressed out of the ground into the ceiling and then evaporate there because of the slightly higher temperature than that in the ground and do not reach the connection point between the freezer compartment and the refrigerator compartment evaporator.

According to a further advantageous embodiment of the subject matter of the invention, it is provided that the feed channel merges into a channel piece in the area after its entry into the ground, the channel channel opening into at least two mutually parallel channels opening into the discharge channel, essentially the same cross section as the channel channel having duct sections branched, the predominant length of which is arranged parallel to the free end of the base and which cross at least in a common duct bed downstream of the branching.

A solution corresponding to these features on the one hand has a favorable effect on the segregation of the liquid and the gaseous refrigerant and on the other hand it is ensured in a simple manner that sufficient volume is available for the liquid refrigerant collecting in the ground during the standstill phase of the refrigerant compressor.

The arrangement of the feed and discharge channels in the upright wall is particularly expedient and space-saving if, according to a preferred embodiment of the object of the invention, it is provided that their channels are arranged vertically in the upright wall.

A channel system of a freezer evaporator provides additional safety in order to prevent liquid refrigerant from being able to pass from the freezer compartment evaporator into the refrigerator compartment evaporator when the refrigerant compressor is at a standstill, if, according to an advantageous embodiment of the subject matter of the invention, it is provided that the ceiling duct arrangement connected downstream of the floor arrangement is in relation to the latter has a lower capacity for liquid refrigerant, but has a larger capacity compared to the ceiling channel arrangement upstream of the floor.

Fig. 1

im Ausschnitt einen Zweitemperaturen-Einkreiskühlschrank, mit einem Gefrierfach und einem unterhalb diesem angeordneten Normalkühlfach, teilweise geschnitten, um dessen Verdampfersystem sichtbar zu machen, in raumbildlicher Darstellung,

Fig. 2

das als walzgeschweißte Platine ausgebildete Verdampfersystem des Kühlschranks entsprechend Fig. 1 in abgewickelter Darstellung,

Fig. 3

in Ansicht von oben, die mit den Ausprägungen für die Kältemittelkanäle versehene Seite des einbaufertig geformten Verdampfersystems in raumbildlicher Darstellung,

Fig. 4

in Ansicht von unten den als Gefrierfachverdampfer ausgebildeten Abschnitt des Verdampfersystems in raumbildlicher Darstellung.

The invention is explained in a description below with reference to an embodiment shown in simplified form in the drawing. Show it:

Fig. 1

in the cut-out a two-temperature single-circuit refrigerator, with a freezer compartment and a normal refrigerator compartment arranged below it, partially cut to make its evaporator system visible, in spatial representation,

Fig. 2

the developed as a roll-welded circuit board evaporator system of the refrigerator according to FIG. 1 in a developed representation,

Fig. 3

in view from above, the side of the ready-to-install shaped evaporator system provided with the characteristics for the refrigerant channels in a spatial representation,

Fig. 4

in a view from below of the section of the evaporator system designed as a freezer compartment evaporator in a spatial representation.

1, a two-temperature single-circuit refrigerator 10 is shown, which, as usual, is equipped with an overhead freezer compartment 11 and a normal refrigerator compartment 13 which is arranged underneath and is separated from this by a heat-insulating intermediate wall 12. The side walls of the normal cooling compartment 13 are provided with grooves 14 formed in the inner container of the refrigerator 10 for inserting shelves (not shown).

The refrigerator 10, which is equipped with a refrigerant compressor (not shown), is equipped with an evaporator 15 having two sections A and B and forming a system of coherent refrigerant channels, which evaporator 15 is formed by two plates connected by roller welding and receiving the refrigerant channels between them.

The section A of the evaporator 15, which is assigned to the freezer compartment 11, has a ceiling 16, an upright wall 17 serving as the rear wall and a bottom 18, which are formed from a one-piece circuit board section. Below the freezer compartment 11, in the normal cooling compartment 13, the section B downstream of section A is arranged in the refrigerant circuit of the evaporator 15 and is designed as a defrostable room evaporator.

The sections A and B of the evaporator 15 are connected to one another by a web-like connecting bridge 19 (see in particular FIGS. 2 and 3).

The evaporator 15 shown in the development in FIG. 2 from a roll-welded plate is formed by bending along the bending zones located between the individual sections and delimited by dash-dotted lines to form a U-shaped profile, particularly shown in FIG. 1 in its use, the latter both ends are open. The legs of the U-shaped profile bent in the same direction from the upright wall 17 have a slightly larger angle than 90 ° with respect to the upright wall 17 after the bending process.

In a manner known per se, the liquid refrigerant is supplied to the duct system of the evaporator 15 via a throttle tube 21 which is installed in a suction pipe 20 and is arranged in the ceiling 16 (cf. FIGS. 2 and 3 in this regard). The refrigerant flows through the ceiling 16 in a large-volume channel part 22 which runs close to the transition to the upright wall 17 and which is still in the ceiling 16, outside the bending zone, connects to a downwardly extending feed channel 23 arranged in the upright wall 17 of the first evaporator section (see also FIG. 3). The connection point between the channel part 22 and the feed channel 23, which has a main channel 24 and a secondary channel 25 running parallel thereto, is designed such that the channel routing of the channel part 22 continues seamlessly in the main channel 24. The main channel 24 and the secondary channel 25 have the same channel cross section and are connected to one another in terms of flow technology with two transverse channels 26 which branch off perpendicularly from the main channel 24 and are arranged at a distance from one another and have a short channel length. The distance between the two transverse channels 26 branching off from the main channel 24 is such that the respective branch point from the main channel 24 lies outside the bending zones of the evaporator section denoted by A in its ceiling 16 or in its bottom 18 in the vicinity of the transitions to the upright wall 17 (See Fig. 3 and Fig. 4). Outside the bending zone, in the floor 18, near its transition to the upright wall, the main channel 24 of the feed channel 23 continues seamlessly in a channel piece 27. After a relatively short path, this branches symmetrically into two channels 28, which run parallel to one another and run in a meandering manner in the bottom 18, each having the same channel cross section of the channel piece 17, the predominant length of which is arranged parallel to the free end of the bottom. Downstream after the branching, the channels 28 are briefly combined in a common channel bed 29, but then separated again. For this purpose, the channel bed 29 divides both upstream and downstream symmetrically with a channel cross section corresponding to the channels 28. The channels 28 are at their output end connected in the bottom 18 by a substantially circular connection piece 30, which is arranged outside the bending zone, to a discharge channel 31 rising vertically in the upright wall 17 of the first evaporator section.

The discharge channel 31, like the feed channel 23, has a main channel 32 and a secondary channel 33 running parallel thereto, which is arranged adjacent to the secondary channel 25 of the feed channel 23. Just like the main channel 24 of the feed channel 23, the main channel 32 of the discharge channel 31 is also equipped with transverse channels 34 which branch off perpendicularly from it, but the transverse channel arranged in the bottom 18 is formed by an annular sector of the annular connecting piece 30. The transverse channels 34 are arranged at a distance from one another which is greater than the height of the upright wall 17 and corresponds to the distance between the transverse channels 26 of the feed channel 23.

The outlet-side end of the feed channel 23 is connected to the outlet-side end of the discharge channel 31 in the ceiling 16, which is arranged directly next to it, by a bypass 35 which has an increased flow resistance and bridges the channel arrangement in the bottom 18, the bypass 35 at the junction of the transverse channels in the Auxiliary channels are connected to this. The increased flow resistance of the bypass 35 is achieved in addition to a corresponding length arranged in turns and additionally by a reduced channel cross section compared to the channels of the feed channel 23 and the discharge channel 31, the ratio of the channel cross sections between the bypass 35 and the main or secondary channels of the Feed channel 23 or the discharge channel 31 is approximately 1: 5.

Approximately at the level of the connection point of the bypass 35 to the secondary duct 33 of the discharge duct 31, the cross section of its main duct 32 widens downstream after its branching transverse duct 34 in the ceiling 16, before it is formed in a collector-like manner in a parallel to the free end of the ceiling 16 Channel section 36 merges, the volume of which is interrupted by button-like impressions 37 (see FIGS. 2 and 3).

The duct-shaped duct section 36 belongs to a duct arrangement which is laid in turns in the ceiling 16 and has the same duct cross section as the enlarged main duct 32. The outlet of the channel arrangement is connected to a channel line 38, which is directed downward on the connecting bridge 19 and is designed as a double channel across the bending zones, with the input of the section, which is not explained in more detail and forms the space evaporator and is designated by B (see also FIG 3).

When the refrigerant compressor is in operation, the design of the feed channel 23 ensures that the liquid refrigerant flows mainly in its main channel 24 and, in relation thereto, a small proportion in its secondary channel 25. As a result of this measure, the bypass 35 connected to the secondary duct 25, which is also equipped with an increased flow resistance in comparison to the duct cross sections of the feed duct 23, is only acted on with small amounts of liquid refrigerant, so that there is no loss of performance in the freezer compartment evaporator during the running time of the refrigerant compressor .

In the standstill phase of the refrigerant compressor, the pressure drop between the condenser and evaporator, which e.g. created by the cooling compressor, and which usually manifests itself in the afterflow of essentially gaseous refrigerant from the condenser to the evaporator, is reduced via the bypass 35. Due to the fact that the flow resistance for the medium flowing in the bypass 35 is lower than the resistance that the liquid accumulated in the bottom 18 of the freezer evaporator during the standstill phase of the refrigerant compressor opposes the pressure of the flowing medium during its movement, the inflowing refrigerant becomes in transferred to the backspace evaporator. The liquid refrigerant accumulated in the bottom 18 thus remains at rest.

If individual liquid fractions act on the refrigerant flow flowing from the condenser into the evaporator, these are evaporated at the latest in the channel section 36 provided with the button-like impressions, provided that this has not already been done in the feed line to the bypass 35.

Claims (13)

Two-temperature single-circuit refrigerator for the household, with an essentially two-section evaporator forming a system of connected refrigerant channels, the first section of which forms a ceiling, an upright wall and a bottom of a freezer compartment, its second, arranged as a room evaporator in a below the freezer compartment Normal cooling compartment serving section is connected upstream, wherein the refrigerant supplied from the injection point in the channel system flows from a downward in the upright wall of the first evaporator section supply channel in a meandering in the bottom of the freezer channel, which rises in an upright wall of the first evaporator section Discharge channel opens, which merges into a channel arrangement laid in turns in the ceiling, the output of which is formed by a channel line directed downwards in the upright wall with the entrance of the space evaporator Iten section is connected, characterized in that the feed channel (23) and the discharge channel (31) is connected via a bypass (35) which is arranged at a distance above the bottom (18) of the first evaporator section and which has an increased flow resistance compared to the bridged channel arrangement . Two-temperature single-circuit cooling device according to claim 1, characterized in that the bypass (35), which connects the supply channel (23) to the discharge channel (31) and has a higher flow resistance, is arranged in the ceiling (16) of the first evaporator section. Two-temperature single-circuit cooling device according to claim 1 or 2, characterized in that the increased flow resistance of the bypass (35) is determined by a corresponding length arranged in turns and / or in particular by a reduction in cross-section. Two-temperature single-circuit cooling device according to claim 3, characterized in that the channel cross sections of the bypass (35) and those of the feed channel (23) are in a ratio in the range from 1: 3 to 1: 7, but preferably in a ratio of 1: 5. Two-temperature single-circuit cooling device according to one of Claims 1 to 4, characterized in that the supply duct (23) has a main duct (24) and, to a certain extent, a secondary duct (25) running parallel thereto, the main duct (24) having and and branching approximately perpendicularly from it transverse channels (26) which are arranged at a distance from one another and connect it to the secondary channel (25) in terms of flow technology. Two-temperature single-circuit cooling device according to one of Claims 1 to 4, characterized in that the discharge duct (31) has a main duct (32) and at least one secondary duct (33) running parallel thereto, the main duct (32) being approximately vertical transverse channels (34) which branch off from it and are arranged at a distance from one another and which connect it to the secondary channel (33) in terms of flow technology. Two-temperature single-circuit cooling device according to one of claims 1 to 6, characterized in that both the transverse channels (26) of the feed channel (23) and the transverse channels (34) of the discharge channel (31) are at a distance from one another which is greater than the height of the upright Wall (17) is, but is preferably dimensioned such that the transverse channels (26, 34) are in the vicinity of the transition to the upright wall (17) in the floor (18) or in the ceiling (16). Two-temperature single-circuit cooling device according to one of claims 1 to 7, characterized in that the main channel (24 32) and the secondary channel (25, 33) of the feed channel (23) and the discharge channel (31) have the same cross section. Two-temperature single-circuit cooling device according to one of claims 1 to 8, characterized in that the transverse channel (26) of the supply channel (23) branches in the ceiling (16) with the bypass (35) such that the refrigerant after a sharp deflection in the bypass (35) is able to occur. Two-temperature single-circuit cooling device according to one of Claims 1 to 9, characterized in that the main duct (32) of the discharge duct (31) downstream of its branching transverse duct (33) in the ceiling (16) in one channel section 36 formed like a collector and provided with button-like impressions 37, which is arranged parallel to the free end of the ceiling (16). Two-temperature single-circuit cooling device according to one of claims 1 to 10, characterized in that the supply duct (23) merges into a duct section (27) in the region after its entry into the bottom (18), which is in at least two mutually parallel, the discharge duct (31) opening, each having essentially the same cross-section as the channel piece (27), the branches (28) of which the predominant length is arranged parallel to the free end of the base (18) and downstream after the branching is at least in a common channel ( 29) cross. Two-temperature single-circuit cooling device according to one of claims 1 to 11, characterized in that the supply duct (23) and the discharge duct (31) are arranged vertically in the upright wall (18). Two-temperature single-circuit cooling device according to one of claims 1 to 12, characterized in that the ceiling channel arrangement downstream of the floor channel arrangement has a lower capacity for liquid refrigerant than the latter, but has a larger capacity compared to the ceiling channel arrangement upstream of the floor (18).

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