EP0173034B1 - Circuit arrangement for the cooling cycles of at least two cold levels - Google Patents

Abstract

A circuit for the control of a refrigeration circuit for at least two refrigeration areas such as the carbonated water supply and beverage concentrate chamber of a beverage dispenser. Priority cooling of one area is achieved by use of a combinational logic circuit in conjunction with refrigeration-requirement sensors so that the CO2 water supply will be cooled first regardless of a requirement for the cooling of the concentrate chamber.

Description

The present invention relates to a cooling device with at least two cooling areas and a cooling circuit, each with an evaporator in each of the cooling areas and with a circuit arrangement for selectively switching on one of the evaporators via a valve arrangement in the cooling circuit, the circuit arrangement for each cooling area sensors and one Contains sensors downstream logic circuit, which causes a priority connection of one of the cooling circuits with regard to their cooling requirement criteria.

For loading a plurality of cooling areas, in particular two cooling areas, it has become known, for example in the case of fridge-freezer combination units (FR-A-24 94 412), to use a cooling system with a condenser and with one evaporator each assigned to the cooling areas, whereby a valve system optionally connects the evaporator part to the condensers. Compressor condensers are usually used in this context. The evaporators are preferably connected alternately to the condenser in order to achieve the best possible efficiency and to keep the manufacturing outlay low. If one of the cooling areas is to be cooled particularly - for example the freezer unit in a fridge-freezer combination - a priority circuit is used in a known manner. Only when this preferred cooling area has been sufficiently subjected to the cooling process is the further cooling area supplied when there is a need for cooling.

In a known arrangement (GB-A-20 83 928), a cooling system for two cooling areas, each with an evaporator and a temperature meter and a common condenser optionally switchable to the evaporator by valve arrangements, contains a circuit arrangement which controls the cooling circuit between the two evaporators Valve system switches in different ways depending on the initial situation. In normal operation, the cooling circuit is guided to a first evaporator until the required temperature in the assigned cooling area or the end of a predetermined period of time is reached and then redirected to the second evaporator until the required cooling temperature is reached. This sequence is repeated continuously (with previous minimum breaks). In the start phase, on the other hand, the cooling circuit is switched over after shorter, predetermined time intervals between the two evaporators until the cooling area assigned to the first evaporator has reached the required temperature. After reaching the required cooling temperature in the second cooling area, the transition to normal operation takes place.

In vending machines, in which a mixed drink can be provided by mixing carbonated water with beverage concentrates, it is necessary, or at least to a great extent, to cool the container in which the carbonated water is kept ready or the water is carbonized. The cooler the water, the greater its absorption capacity for CO ₂ gas. In addition, when mixing a beverage from beverage concentrate and poured water, the volume fraction is a multiple of the volume fraction of the beverage concentrate, so that the temperature of the carbonator is also essentially determining the temperature of the mixed beverage.

The cooling of the carbonated water has a natural limit set by the freezing point of the mixture. To increase the cooling capacity, part of the carbonated water is stored in ice form. The ice sheet that forms is evaluated as a criterion for the cooling supply.

In order to meet different requirements with regard to the removal amounts of cooled carbonized water from a storage container, it has become known (DE-A-30 16 941) that two electrodes are arranged in the storage container for detecting different thicknesses of the ice sheet formed, one of which is an electrode is assigned to a first thickness of the ice sheet to be built up in normal operation and the second electrode of the evaluation circuit is switched on when the construction of a thicker ice sheet is desired.

Due to the heat capacity of uncooled beverage concentrates and due to further disruptive influences during the mixing and dispensing process, the temperature of the mixed beverage can be higher than the desired beverage temperature. For this reason and in order to expose the stored beverage concentrates to advantageous storage conditions, it may also be necessary to cool the storage space for the beverage concentrates. On the other hand, however, it is also desirable to expand the "cooling capacity" as much as possible in the event of a relatively high expected beverage dispensing requirement, and that by precautionarily forming the strongest possible ice sheet.

The present invention is based on the object of providing a circuit arrangement for controlling cooling circuits for at least two cooling areas, in particular for the described application area, which is able to meet different cooling energy needs from a common cooling system for the two cooling areas.

A circuit arrangement for a cooling circuit with a condenser and with a plurality of evaporators, which can be connected to this condenser by means of a valve arrangement, is characterized according to the invention in that sensors for At least two cooling area criteria are assigned, of which the first is evaluated primarily for the cooling requirement criterion of the second cooling area and the second is evaluated subordinate to this by logic circuitry for the control of the valve arrangement, so that first the first cooling area criterion of the first cooling area, then the cooling area criterion of the second cooling area and then that second cooling area criterion of the first cooling area are fully satisfied.

A circuit arrangement for controlling cooling circuits constructed according to these criteria according to the invention is preferably suitable for vending machines with separate storage of carbonated water and beverage concentrates insofar as the cooling of the water supply to a predefined basic value takes priority over the cooling of the storage space for the beverage concentrates. However, if the water supply is to be subjected to additional cooling - for example in the event that provision is made for increased output of carbonated water, which is replaced by warmer fresh water, then this cooling requirement is subordinate to the cooling of the beverage concentrate storage space.

According to a preferred embodiment, the circuit arrangement according to the invention when used in vending machines is characterized in that the sensors for the provision of the cooling requirement criteria for the carbonated water are electrodes which are arranged in areas of the ice sheet being formed at different distances from the cooling device. The electrode, by means of which the highest-ranking cooling requirement within the vending machine can be ascertained, is arranged in an area in which the ice sheet that forms has a predetermined minimum thickness. The second electrode detects an additionally reinforced formation of the ice sheet. Regardless of the thickness of the ice sheet formed, however, the temperature of the carbonator is approximately the same in the area near and above freezing point.

To detect the cooling requirement in the storage room for the beverage concentrates, an electronically evaluable switching element, e.g. B. an NTC switching element can be used. A circuit arrangement constructed according to the features according to the invention will expediently be designed in such a way that all sensors for providing the refrigeration requirement criteria are linked via an OR link and can thus be evaluated for activating the refrigeration cycle. A priority must be assigned to the individual cooling demand criteria by means of a further logic logic circuit, to which the signals of the heat demand sensors are fed, the output signal of this further logic logic circuit controlling the changeover valve for the cooling circuit. If the circuit is designed in such a way that the changeover valve assumes a preferred switching position, the effort for this further logic logic circuit can be simplified. If this preferred basic position is assigned, for example, to the refrigeration area, from which the refrigeration requirement criterion for the last-ranking refrigeration area can also be tapped, then this criterion can be dispensed with in the further logic combination circuit.

An exemplary embodiment designed according to the features of the invention is described in more detail below with reference to the drawing:

The figure shows schematically a circuit structure for use in a vending machine with cooling on the one hand of the carbonated water and on the other hand of the storage room for the beverage concentrates.

The cooling circuit for the vending machine consists essentially of a compressor VD driven by a motor M, a condenser section VS, a switchover valve UPS which can be controlled by a switching magnet USM, and two evaporator sections VDS1 and VDS2 with associated throttle valves DrV1 and DrV2 for the storage tank VT for the C0 ₂ -water supply or for the VR storage room for the beverage concentrates. Sensors ES1 and ES2 for monitoring ice sheet formation in the CO ₂ water supply are arranged in the storage tank VT. Using these sensors ES1 and ES2, the different resistance value of the liquid state or the ice state between the respective sensors and the housing wall of the storage tank VT is evaluated and supplied to the differential amplifiers DV1 and DV2 as a control criterion. For the cooling requirement criterion in the storage room VR for the beverage concentrates, a temperature-dependent variable resistor TR is used, which is assigned to the differential amplifier DV3.

The sensor ES2 can only be switched on as required via a switch ZS. In normal operation for the vending machine, only the sensor ES1 and the sensor TR supply cooling requirement criteria to the evaluation circuit. If, however, increased ice sheet formation is to be formed in the storage tank VT for the carbonated water, the sensor ES2 is also connected to the evaluation circuit via the switch ZS.

The outputs of all differential amplifiers DV1, DV2, DV3 are linked via an OR logic circuit OG and control the motor M for the refrigerant compressor VD via an amplifier stage V2 and a power amplifier. This means that regardless of which of the sensors signals a need for cooling, the cooling system comes into operation.

In addition, the outputs of the differential amplifiers DV1 and DV2 are fed to an AND logic circuit UG, the output of which controls the switching magnet USM for the refrigerant switching valve UPS via an amplifier circuit V1 and a power amplifier. The output signal of the DIN differential amplifier DV1 becomes the input of the AND gate circuit UG fed inverted. The refrigerant changeover valve UPS preferably occupies the starting position in which the refrigeration cycle is conducted via the evaporator section VDS1 of the storage tank VT for the carbonated water.

If a cooling demand is signaled by the sensor ES1, this is blocked via the inverted signal at the AND logic circuit UG, so that regardless of whether there is a heat requirement criterion for the beverage concentrates from the sensor TR of the storage room VR, the switching magnet USM is not excited and that Refrigerant changeover valve UPS takes its preferred starting position. The refrigeration cycle is securely conducted via the VDS1 evaporator line. If there is no cooling requirement criterion on the part of the sensor ES1, the AND logic circuit UG is controlled by the inverted signal. A now available cooling requirement criterion from the sensor TR for the beverage concentrate storage room VR is forwarded and the switching magnet USM is excited via the amplifier V1 and the power amplifier, and thus the refrigerant switching valve UPS is switched over. This activates the evaporator section VDS2 and cools the storage room VR for the beverage concentrates. However, if there is no cooling requirement criterion on the part of the sensor TR, the refrigerant changeover valve UPS returns to its starting position. In the event that the switch ZS is closed, a refrigeration requirement criterion from the sensor ES2 is only evaluated to control the refrigerant compressor VD via its motor M, so that refrigerant is again applied to the evaporator section VDS1.

In practical application, the circuit arrangement specified as an exemplary embodiment will be part of an overall circuit for operating a beverage machine. To carry out the control logic, it is then conceivable and expedient to use a microprocessor circuit instead of discrete switching elements.

In the exemplary embodiment shown and described, the circuitry measures are implemented by functional modules, in particular in the form of logic logic elements. However, preferably in connection with other control measures, it is expedient to use a microprocessor circuit, which includes the functional modules described, when pursuing the solution according to the invention.

Claims (8)

1. Cooling device comprising at least two cooling ranges (VT, VR) and a coolant circuit each including an evaporator (VDS1, VDS2) in each of the cooling ranges (VT, VR) and comprising a switching arrangement for selective switching on one of the evaporators (VDS1, VDS2) about a valve installation in the coolant circuit (VS), whereby the switching arrangement includes sensors (ES1, ES2, TR) for each cooling range and a connection circuit (DV1, DV2, DV3, UG, OG) connected at the outlet side of said sensors which connection circuit causes a priority connection of one of the coolant circuits relatively to its criteria for the cooling requirement, characterized in that to a first cooling range (VT) are allocated sensors (ES1, ES2) for at least two criteria of cooling requirements, of which the first criterion is inter- pretes as superiority to the criterion of cooling requirement of the second cooling range (VR) and the second is interpreted as inserted after said first criterion by the connection circuit for controlling of the valve installation (USV) so that at first the first cooling - range - criterion of the first cooling range (VT), thereafter the cooling requirement criterion of the second cooling range and subsequently the second cooling - requirement - criterion of the first cooling range (VT) are satisfied completely at any case.

2. Cooling device as claimed in claim 1 for a beverage automaton with a first cooling range for water carbonated and a second cooling range for heverage concentrate, characterized in that said sensors for disposition of readiness of the cooling requirements criteria for the water carbonated are electrodes (ES1, ES2), which are arranged in the range of the ice coating formed from the cooling mechanism on that.

3. Cooling device as claimed in one of the claims 1 or 2, characterized in that as sensor a NTC switch-element is provided.

4. Cooling device as claimed in one of the claims 1 to 3 for a heverage automaton with a first cooling range for water carbonated and a second cooling range for beverage concentrate, characterized in that about a logical connecting circuit there are associated with the cooling range (VT) for the CO_s-waterstore a cooling requirement of first priority, with the cooling range (VR) for the heverage concentrates a cooling requirement of second priority and once more with the cooling range (VT) for the C0₂-waterstore a cooling requirement of third priority.

5. Cooling device as claimed in one of the claims 1 to 4, characterized in that about an OR- connection all sensors (ES1, ES2, TR) are connected for put in of the coolant circuit.

6. Cooling device as claimed in one of the claims 1 to 5, characterized in that a further logical connecting circuit (UG) is provided to which circuit signals of the cooling re- quirementsensors (ES1, ES2, TR) are leaded, whereby the output signal of this further logical connecting circuit (UG) in relation of the cooling requirement-priority engaged of that circuit drives a switch-over-valve (USV) for the coolant circuit.

7. Cooling device as claimed in claim 6, characterized in that the switch-over-valve (USV) has a favoured switchposition, which is associated to the cooling range with the cooling requirements criterion with the lowest priority.

8. Cooling device as claimed in one of the claims 1 to 7, characterized in that all circuits especially the logical connection means are integrated inside of a microprocessor circuit.

Images