DE4020537A1 - Refrigeration circuit for combined refrigerator and freezer - uses blocking chokes for output and tap-off from condenser to provide different operating modes - Google Patents

Abstract

The refrigeration circuit has a compressor (10), a condenser (11) and respective evaporators (12,13) for the refrigerator and freezer compartments, with temp. regulators within the latter for switching control of the compressor (10). The condenser (11) is followed by a blocking choke (17). The condenser (11) has at least one tap-off (26,27) which can be blocked by a choke (18,19), all of the chokes (17,18,19) pref. provided by a multi-way valve. ADVANTAGE - Allows different operating modes for combined refrigeration and freezing or refrigeration or freezing alone.

Description

The invention relates to a multi-temperature cooling furniture, z. B. on a fridge-freezer, with a Refrigerant main circuit containing a compressor, a Condenser and one evaporator for each Has refrigerators, and with regulatory organs in the subjects for the temperature-dependent switching of the compressor.

Such a design is z. B. by DE-OS 35 08 805 known. The known type shows a two Temperatures refrigerator, where the freezer and the normal cooling compartment associated evaporator with one each upstream, shut-off throttle body in parallel lie to each other. The said two throttle bodies a collector upstream, in which liquid refrigerant stored in the event of heating by a get additional heating element in the refrigeration cycle can. If only the normal refrigerator or the freezer Cold request is the supply of refrigerant for that each other cold compartment blocked by the throttle body. In both cases, the additional liquid cold remains medium in the collector, which prevents the each operating evaporator flooded becomes. However, when requested by both subjects cold are the throttle bodies for the administration of the liquid Refrigerant throughout. In addition, this is done in this Case the activation of the heating element for the collector,  whereby the liquid refrigerant stored therein liquid phase in the refrigerant circuit exits and spread over both evaporators.

By DE-OS 23 50 998 is a two-temperature cooling cabinet of the type mentioned above with a single Compressor refrigeration unit has become known, whose with a Condenser, a throttle body and connection equipped refrigeration circuit at least two in Flow direction of its refrigerant in a row having switched evaporator sections. Of these Sections is the first one colder part and the second assigned to a warmer compartment. Furthermore, a is the Compressor depending on the temperature in the warmer Compartment provided intermittently switching control element, which simultaneously with the compressor circuit Heating element for a throttle body upstream Collector switches. For this is turned on Heating liquid refrigerant in the second evaporator section expelled. In this design is the colder Subject assigned a control organ when crossing a predetermined maximum temperature the compressor regardless of the switching state of the warmer compartment supplied arranged regulatory organ turns on.

The invention is based on the object for a cooling furniture of the type mentioned in a condenser system Develop with which to simple and reliable Just the one requested by the individual refrigerators Refrigerant quantity can be provided.

This object is in a refrigerated cabinet of the beginning mentioned type solved in that the condenser a shut-off throttle body is connected downstream and that  the condenser at least one with the coolant main circle connected and lockable by a throttle body Tap has.

By such a tap, the refrigerant circuit each supplied with only a portion of the refrigerant become. The refrigerant circuit can thus specifically targeted the amount of refrigerant required by each evaporator be delivered, with the taps the respective Allow a portion of the refrigerant to be supplied and wherein the throttle bodies open the respective lines or lock.

In such a design, the condenser is at the common supply of all evaporators required Refrigerant quantity designed. By the invention can either all evaporators at the same time or z. B. only one Evaporator targeted and accurate with the required cold be supplied. If z. B. only one of Evaporator should be supplied with a refrigerant, This evaporator is only needed by him and by the associated control element requested refrigerant quantity supplied by the condenser via a corresponding Tapped line. The rest of the cold means remains in the condenser. It will be each not required lines by lockable Throttle closed.

As throttle bodies z. B. solenoid valves provided his. As throttle bodies can also each with a Heater provided capillary tubes are used by heating for the passage of refrigerant in the liquid phase are shut off.  

A preferred embodiment of the invention is in that the condenser with the downstream Throttle and the evaporators connected in series. Should be only the first of the flow direction of the cold by means of in-line evaporator with that of him requested amount of refrigerant to be supplied, so will to the condenser also at a certain point tapped. This is about this tap only so much Refrigerants are introduced into the circuit, like this one first, in-line evaporator needed. For the downstream evaporator is then no refrigerant more available. Such a targeted supply of required by the respective refrigerators and ange ange demanded refrigerant quantity by tapping the Condenser is in a simple and easy way through feasible. Preferably, this type is applied to a Two-temperature refrigeration cabinets, z. B. on a fridge-freezer combination or a cooling unit with star compartment. such Refrigerators usually have a freezer compartment (TKR) with an associated evaporator and a normal refrigeration compartment (NKR) also with an associated evaporator.

In an embodiment of the invention, it is proposed

• a) that in a two-temperature refrigeration furniture said Type of liquefier has a first tap, the via a first lockable throttle body ent holding first pipeline to the entrance of a first Evaporator is connected,
• b) that the condenser has a second tap, via a second shut-off throttle body containing second pipe with the input of a connected downstream of the second evaporator and  
• c) that the taps are chosen such that through the first tap adapted to the first evaporator and by the second tap one the second Evaporator adapted refrigerant amount available can be made.

Except for the two evaporators in series Throttle body are just two more taps provided, each with piping and built-in Lockable throttle bodies with the entrance of the first and the second evaporator are connected, before the the evaporators respectively associated capillary tubes. These simple design allows a great effort Targeted adapted supply of the individual evaporator Standalone or shared operation, with ent speaking throttle bodies each open or closed become.

In an embodiment of the invention can be mentioned for the mentioned Throttle bodies are provided in each case two-way valves. This means that each individual route can be targeted. In a further embodiment, all three mentioned Throttle also by a single three-way valve with three inputs and three outputs are replaced, whereby the effort can be further reduced. Such Type allows the following operating modes: "Cool only", "Freezing only" and "Cooling and freezing". In the Only cooling function is only the evaporator of the cooling times and with the function "freezing only" becomes only the Evaporator of the freezer over the associated Tap supplied with the requested amount of coolant. In the function "Cooling and Freezing" both are in Series lying evaporator supplied with refrigerant, wherein  the refrigerant main circuit does not contain a lock, so that brought the entire amount of refrigerant in the circulation becomes.

Here are the taps associated piping blocked by the corresponding throttle bodies.

The same functions can be achieved by that in a further embodiment of the invention for the the condenser downstream throttle body and for the in the first pipe lying first throttle body in each case a two-way valve (solenoid valve) is provided and that as a throttle body in the second pipe a automatically capped by a vapor barrier capillary pipe is provided. Here then is the capillary tube automatically by a vapor barrier at the function "Cooling and freezing" as well as the function "Nur Freeze. "This vapor barrier is used at the "Cooling only" function canceled, since with closed Throttling body in the first pipeline and in the cold medium-main circuit of the condenser itself up to the taps filling the first pipeline liquid.

In a simplified version, in which only the Functions "freezing" and "cooling and freezing" possible It is suggested that the condenser be a single tap, which, bridging the the condenser downstream throttle body over a pipeline to the inlet of the condenser adjacent evaporator is connected.

An energy-optimized improvement of the refrigeration cycle can be achieved by leaving behind each tap on the condenser a check valve is arranged. This  has the effect of not depending on the mode required refrigerant is stored and under pressure compensation does not get into the evaporator. This saves Energy, since there is less refrigerant when the device starts up is transported and the operating point faster is reached. The intermediately stored refrigerant is only released when the associated throttle opens.

In the drawing, in FIGS. 1 to 4 execution examples of the article according to the invention are shown schematically.

Fig. 1 to 3 show three circuit examples for a two-temperature refrigerator, and

Fig. 4 shows in cross section a three-way valve for Verwen tion in the circuit example of FIG. 1.

Figs. 1 to 3 show schematically the refrigerating circuit of a Two-temperature refrigeration apparatus with a single compressor 10, a downstream Verflüssi ger 11 and with two series-connected evaporators 12, 13 connected to the compressor 10 and the condenser 11 in a refrigerant Main circuit in series. The evaporator 12 is associated in this example a freezer and the evaporator 13 a normal refrigeration compartment. All three circuits each have a capillary tube 14 between the condenser 11 and the evaporator 12 . Further, in all three embodiment examples in the refrigerant main circuit between the condenser 11 and the capillary tube 14 a shut-off throttle body, which is formed in Fig. 2 and 3 as a two-way solenoid valve 15 and the valve in Fig. 1 part of a one-piece three-way valve described below 16 is.

This shown in Fig. 4 three-way valve 16 has three switchable paths 17 , 18 , 19 with three inputs 17 a, 18 a, 19 a and three outputs 17 b, 18 b, 19 b. 20 with a provided with an annular groove 21 piston is referred to, which can be moved by two magnetic coils 22 , 23 against the force of two springs 24 , 25 upwards or downwards. In the position shown in Fig. 4, no magnet is energized, the valve is in the rest position, wherein the annular groove 21 is aligned with the central inputs and outputs 17 a, b. The throttle valve member disposed in the outer main refrigerant circuit is denoted in Fig. 1 at 17.

In the embodiment of FIG. 1, the control by means of the one-piece three-way valve 16 , whereby the functions "cooling only", "freezing only" and "cooling and freezing" can be performed. The condenser 11 has a first tap 26 and a second tap 27 , which are connected via a first pipe 28 and a second pipe 29 to the inputs of the evaporator 12 and 13 , respectively. The pipes 28 , 29 contain the individually closable by the control valve 16 paths 18 and 19th With 14 and 30 are the inputs of the evaporator 12 , 13 directly assigned capillary tubes called.

The following functions result (see Table 1):
With simultaneous supply of the evaporator 12 and 13 with refrigerant ("cooling and freezing"), the solenoid valve 16 is opened on its way 17 , while the paths 18 , 19 are closed. The coils 22 , 23 are not energized, so that the annular groove 21 is aligned with the inputs and outputs 17 a, b. Both evaporators 12 , 13 receive the full capacity of the refrigerant. If only the evaporator 12 for the freezer is to be supplied with refrigerant ("freezing only"), the solenoid 23 is energized and releases the path 18 while the paths 17 , 19 are closed. In this case, a part of the refrigerant charge in the condenser 11 is retained. About the tap 26 reaches sufficient refrigerant in the evaporator 12 of the freezer compartment, while the evaporator 13 of the normal refrigeration times out of lack of refrigerant is no longer supplied. Thus, the condenser is adapted to the required performance. If only the evaporator 13 of the normal refrigeration compartment to be supplied with refrigerant ("cooling only"), the coil 22 is energized and opens the path 19 , while the paths 17 , 18 are closed. Most of the refrigerant remains in the condenser 11 , so that the evaporator 13 gets the requested correct amount.

The electrical control is expediently carried out via a per se known powerful electronics. Instead of the unitary three-way valve 16 shown in FIG. 1, three individual two-way valves in the paths 17 , 18 , 19 can alternatively be provided.

The embodiment of FIG. 2 operates with two solenoid valves. The first solenoid valve 15 is located in the main refrigerant circuit, and the second solenoid valve 31 is located in the first pipe 28 , the ver as shown in FIG. 1 with a first tap 26 of the condenser 11 is prevented. The second pipe 29 , which is connected to the second tap 27 of the condenser, in this case contains only the capillary tube 30 , which can be heated by a heater 30 '.

The following functions result (see Table 2):
In the function "cooling only" both valves 15 , 31 are closed. In the "freeze only" function, the valve 15 is closed and the valve 31 is opened. In the function "cooling and freezing", the valve 15 is opened and the valve 31 is closed. In this embodiment example, the capillary tube 30 is automatically closed by a vapor barrier in the functions "cooling and freezing" and "freezing only". This vapor barrier is canceled in the function "cooling only", since with closed valves 15 , 31, the condenser 11 until the tapping point 27 liquid fills.

In the embodiment of FIG. 3, the condenser 11 includes only a tap 32 , which is connected via a pipe 33 to the input of the evaporator 12 , that is connected to the line between the valve 15 and the capillary tube 14 . This type of construction allows, according to Table 3, the "freezing only" functions in which the valve 15 is closed or the "freezing and freezing" function in which the valve 15 is open. Upon energization of the solenoid valve 15 , the evaporators 12 and 13 are supplied with refrigerant. If only the freezer compartment ( 12 ) requires power, the valve 15 closes, and refrigerant collects in the condenser 11 , so that only the evaporator 12 for the freezer compartment is supplied with refrigerant via the tap 32 and the line 33 .

This latter system can also be used on freezers be used as follows: When goods are frozen should, so far always had the entire freezer on low temperature, which is always a lot of time and energy needed. However, that would be enough To bring the freezing compartment to low temperature and the remaining room at -18 ° C. With the help of this Systems can only use the top two for freezer operation Boards are supplied with refrigerant, which is too much low evaporation temperatures in Vorgefrierfach leads. In the upper freezer would thus ideal conditions for Freezing of goods available. The condition is that the Freezer compartment slightly opposite to the rest of the room is isolated (partition). With this possibility could In the household within a short time goods were optimally shock freeze without spending much energy.

Another possibility is the use in devices with Three-star compartment. However, it must be noted that the normal refrigerator evaporator the freezer compartment Evaporator is downstream. Thus, also here could Dosing system for controlling the three-star compartment and the Normal refrigeration done, and this at ambient temperature temperatures from 32 ° C to 5 ° C.

When using vapor barriers as throttle bodies can these via heaters or via PTC semiconductors, which Temperatures up to 200 ° C reach, be built. The high temperature and the thermal stability of PTC Semiconductors leave this solution as very reliable appear. In addition, no noise occurs.

With 34 each behind a tap 26 , 27 , 32 arranged in the condenser 11 check valve is designated net.

Table 1

Table 2

Valve 15 Freezing only to Cool and freeze open

Claims (10)

1. multi-temperature refrigeration, z. As Kühl-Gefrierkombi nation, with a refrigerant main circuit having a compressor ( 10 ), a condenser ( 11 ) and an evaporator ( 12 , 13 ) for different refrigerators, and with control elements in the subjects for temperature-dependent circuit of Compressor ( 10 ), characterized in that the condenser ( 11 ) a shut-off throttle body ( 17 ; 15 ) is connected downstream, and that the condenser ( 11 ) at least one connected to the refrigerant main circuit and by a throttle organ ( 18 , 31 ) has lockable tap ( 26 , 32 ). 2. Cooling cabinet according to claim 1, characterized in that the condenser ( 11 ) with the downstream throttle member ( 15 ; 17 ) and the evaporators ( 12 , 13 ) is connected in series. 3. Refrigerator according to claim 2 in the execution of a two-temperature refrigerator, characterized

• a) that the condenser (11) has a first tap (26) via a lockable a first throttling member (18; 31) comprising first conduit (28) to the input of a first evaporator (12) is connected,
• b) that the condenser ( 11 ) has a second tap ( 27 ) which is connected via a second shut-off throttle body ( 19 ; 30 ) containing second pipe ( 29 ) to the input of a downstream second evaporator ( 13 ), and
• c) that the taps ( 26 , 27 ) are selected such that by the first tap ( 26 ) adapted to the first evaporator ( 12 ) and through the second tap ( 27 ) a the second evaporator ( 13 ) fitted refrigerant amount available is provided.

4. Refrigerator according to one of claims 1 to 3, characterized in that for the shut-off throttle members ( 17 , 18 , 19 ), a one-piece three-way valve ( 16 ) is used ( Fig. 1). 5. Refrigerator according to one of claims 1 to 3, characterized in that a respective two-way solenoid valve is provided for the throttle bodies ( Fig. 1). 6. Refrigerator according to claim 3, characterized in that for the condenser ( 11 ) in the refrigerant main circuit downstream throttle body ( 15 ) and for the in the first pipe ( 28 ) lying throttle body ( 31 ) each provided a two-way valve (solenoid valve) is and that as a throttle body in the second conduit ( 29 ) is automatically closed by a vapor barrier capillary tube ( 30 ) is provided ( Fig. 2). 7. Refrigerator according to claim 6, characterized in that the vapor barrier is built on a heater.   8. Refrigerator according to claim 6, characterized in that the vapor barrier over PCT semiconductor is constructed. 9. Refrigerator according to claim 1 or 2 in the execution of a two-temperature refrigerator, characterized in that the condenser ( 11 ) has only a single tap ( 32 ), the bypassing of the condenser ( 11 ) downstream throttle body ( 15 ), via a conduit ( 33 ) is connected to the inlet of the in-line first evaporator ( 12 ). 10. Refrigerator according to one of claims 1 to 9, characterized in that behind the taps ( 26 , 27 , 32 ) in the condenser ( 11 ) check valves ( 34 ) are arranged.