DE10161576A1 - Universal electronic control system for absorption refrigerators has a microprocessor and memory selectively responding to multiple sensors for various parameters - Google Patents

Abstract

The microprocessor (1) has a variable memory section (2) which can be preset or user altered through an interface ((S4,S5) to respond to various sensors (S1..S6) according to the particular machine parameters or user requirements.

Description

The invention relates to a control device for a cooling device, in particular for a Absorption cooling device according to the preamble of claim 1 and a cooling device, the comprises such a control device.

It is known to provide cooling devices with a control unit, which depends controls the cooling capacity of the device from a variety of parameters. From DE 196 42 745 A1 is, for example, an accident monitoring system for one Absorption refrigerator shown, in which the temperature to different by several sensors Set the cooling unit, the fill level of the coolant reservoir and the Pressure in the cooling circuit can be measured. From the measured data you can then use the Monitoring system according to the rules of fuzzy logic to determine whether there is a leak is present in the cooling circuit. DE 199 13 896 A1 shows a monitoring system for one Refrigerator in which the power supplied to the cooling circuit changes at intervals and the temperature of the cooling medium is measured on the evaporator. The ones out the change in performance resulting temperature difference is used to determine whether a There is a defect in the cooling circuit.

It turns out to be a disadvantage of the known control devices that they do enable optimal control of the operation of the refrigerator, but not universally different cooling units can be adapted. Rather, they are Control devices by using appropriate electronic components to the required specifications of a specific cooling unit adapted. In particular, it is not possible, the temperature ranges in which the cooling unit should work for the set the appropriate use of the unit. It is only known that Temperature of a cooling unit by the user in a predetermined, no longer to control the changeable range, for example via a potentiometer.

The object of the invention is therefore to provide a control device and a cooling device to improve the way that it is flexible to different Operating conditions can be set without changing the physical components of the control device itself must be made.

This task is performed by a control device with the features of Claim 1 and achieved by a cooling device with the features of claim 16.

The control device according to the invention for a cooling device, in particular for a Absorption cooling device is provided, comprises a processor and a plurality of Sensors, the operation of the cooling device depending on the sensors determined values is controlled via the processor. The processor has one programmable memory area in which different operating data of the refrigerator are stored, the operating data being selectable, changeable and via an interface are readable. This will program the processor with the help of a Interface software allows so that the processor to specific Refrigerators and special requirements such as B. special temperature profiles, can be customized. This has the advantage of being the same processor for a variety of applications different cooling devices used for different purposes can be. Only at the end of production of the refrigerator can this be done via the interface the intended use of the cooling device provided temperature profile on the programmable memory area can be selected. Furthermore, data on the Memory area can be changed to the control device to new device specifications or adapt new purposes.

In an advantageous embodiment of the invention, the programmable Storage area also further storage sections for additional data, in particular for data for performing leakage tests to determine leaks in the cooling circuit and / or for further identification data, such as. B. the serial number of the refrigerator. This Data can also be selected, changed and read out via an interface can be stored, for example, during the manufacture of the cooling device or later be entered by service personnel.

In an advantageous embodiment, a flash EPROM is used as the memory area and / or EEPROM and / or a non-volatile RAM. An interface for wireless data transmission is preferably used as the interface, for example by radio or infrared. Through such an interface in particular, enables simple data transmission without electrical cables.

In a particularly preferred embodiment, the interface comprises a transmission and Receiver unit, via which data can be transmitted to or from the processor can be read out, the transmitter and receiver unit being able to detect when the door of the Cooling unit is opened. This creates a dual function of the interface as well as Sending and receiving unit as well as a detection unit allows, so the number the outputs and inputs on the control device can be kept low. In In a preferred embodiment, the interface is part of a light barrier. Such a light barrier preferably has an optical transmitter, an optical one Receiver and a reflector, the reflector when the door is closed Cooling unit reflects a signal emitted by the transmitter towards the receiver. It can about that a display can also be provided which signals whether the refrigerator door is open has been.

In a further embodiment, the light barrier also serves as a door sensor determines whether the refrigerator door is open or closed.

To control an absorption cooling device, the invention has Control device preferably a sensor for determining the evaporator temperature and / or a sensor for determining the temperature in the cold room and / or a sensor for Determine the temperature of the stove of the absorption cooling unit. As a result, a Accident monitoring and optimal control of the heating output of the cooling unit, for example with the methods according to those mentioned in the introduction to the description Publications.

In a further embodiment of the invention, the control device is equipped with a Interior lighting of the refrigerator can be coupled, so that the interior lighting from defects of the cooling circuit determined by the control device can be displayed. In addition, a time switching element can be provided in the control device, which indicates the duty cycle of the interior lighting when the door of the refrigerator is opened limited a predetermined time. The interior lighting itself preferably comprises one energy-saving and long-lasting LED lighting.

The control of the operation of the refrigerator is preferably carried out using the rules of Fuzzy logic accomplished, as already in the in the introduction mentioned publication is made.

In a further preferred embodiment, the control device is such configured that they with a central control unit for monitoring and controlling a A variety of cooling devices can be coupled. The cooling units are with the central one Control unit, for example by means of a wired network, e.g. B. Ethernet or PLC (Power Line Communication), networked. But you can also use a wireless network be networked, e.g. B. via wireless LAN or Bluetooth (Bluetooth Special Interest Group SIG). This is especially true when using the refrigerator as a hotel refrigerator advantageous, because this enables central monitoring of the operation of the cooling devices. In particular, it can be displayed in the central control unit from which Refrigerators were removed from the hotel's beverages, allowing staff to replenish them Drinks only need to go to those hotel rooms whose refrigerators are in accordance information from the central control unit has been opened by the hotel guest. About that In addition, the central control unit can quickly determine whether a refrigerator is in the Hotel room is open. Such an open refrigerator can then through the Service personnel should be closed to avoid unnecessary energy consumption.

Further features, advantages and details of the invention will become clear from the following detailed description of a preferred exemplary embodiment with reference to the attached FIG. 1, which shows a block diagram of a control device according to the invention for an absorption refrigerator.

The control device shown in FIG. 1 comprises a microprocessor 1 on which a memory area 2 in the form of a flash EPROM is provided. The flash EPROM itself has further memory areas, in particular sections for storing different temperature profiles ("cold", "normal" and "warm"). Furthermore, a memory area is provided for presetting a so-called leak test, this steering test being used to check at regular time intervals whether the absorption cooling unit connected to the control device has a leak in the cooling circuit. Furthermore, a storage area is provided for the serial number S / N of the refrigerator and for the room number in which the refrigerator is installed. The microprocessor has a large number of inputs and outputs, the inputs being designated E and the outputs being designated A. The microprocessor is connected to different sensors S1-S4 via inputs E. The sensors S1-S3 are temperature sensors. The sensor S1 is used to determine the interior temperature, the sensor S2 to determine the temperature at the evaporator and the sensor S3 to determine the temperature at the stove of the absorption cooling unit. Another sensor S4 is designed as an infrared receiver, which is arranged in the region of the door of the absorption refrigerator and receives infrared light reflected by a reflector R. The infrared light reflected by the reflector comes from an infrared transmitter S5, which is connected to an output A of the microprocessor. In addition, the receiver S4 and transmitter S5 are connected to a so-called "red dot display" RD, which is designed as a red light-emitting diode and is preferably arranged on the front of the cooling device.

Receiver S4, transmitter S5 and reflector R form a light barrier, which is as follows works: When the refrigerator door is closed, the transmitter, receiver and reflector are like this arranged that an infrared signal emitted by the transmitter S5 reflects on the reflector R. and arrives at the infrared receiver S4. When you open the door, they change Positions of transmitter, receiver and reflector to each other, so that the infrared signal from Sender no longer reached the receiver. As a consequence, the RD display is activated, which causes the red LED to glow. The lighting of the LED is not caused by the Closing the fridge door finished. Rather, it has to be on the red dot display applied signal are reset by the user, for example via a switch. The signal can also be reset by the user via the infrared interface S4 or another wireless interface. The red dot display thus enables a signal that indicates to the user that the refrigerator has been opened. A such display is particularly advantageous for hotel refrigerators because Service personnel are immediately informed whether drinks have been removed from the hotel guest. Shines If the red dot display does not, the service staff knows that it is not the refrigerator has to fill up because no drinks have been removed. When the red dot lights up However, the service personnel will open the fridge and remove them Refill drinks. The staff can then redisplay the red dot be deactivated.

As previously mentioned, the infrared transmitter S5 is connected to an output of the microprocessor and the infrared receiver is connected to an input thereof. This enables communication data, for example for changing the operating mode, in particular for setting a different temperature profile, to be read into the microprocessor 1 and the EPROM 2 when the refrigerator door is open, or for the data stored on the EPROM to be read out via the transmitter S5 become. The receiver S4 and the transmitter S5 thus have a dual function. On the one hand, they are components of a light barrier to determine whether the door of the cooling device has been opened, and on the other hand they serve as an input / output interface for the microprocessor.

The programmable EPROM of the microprocessor enables one and use the same control device for different refrigerators, the EPROM according to the operating mode of the refrigerator or the design of the Refrigerators can be optimally programmed. Depending on which one Intended use of the refrigerator can end of production of the refrigerator for example, a corresponding temperature profile is set on the microprocessor become. Thus, refrigerators can be used in North America are and are to be set very cold according to the drinking habits there, the same Control units are used as for refrigerators for the European area are provided, in which according to the drinking habits there a not so cold Indoor temperature is desired. You can also use the S4 infrared receiver later by a service technician or the user another temperature profile can be set, or other data such. B. the room number in which the Refrigerator is set up to be entered.

The control device also has an interface X4, which is connected to the input and output of the light barrier is connected in parallel to a wired Enable communication. Data for diagnosis can also be sent via the X4 interface the cooling system and to change the setup of the control system or be fed.

The control device further comprises an optocoupler S6, which has an output of the microprocessor on the one hand and an interface X3 on the other. This Optocoupler is used for electrical isolation in order to connect external To enable additional devices that are used to evaluate the output of the microprocessor. An external module, for example a Alarm unit connected when the refrigerator door is open or an external red dot module connected become.

Since the microprocessor controls the performance of the absorption system depending on the data stored on the flash EPROM and the temperatures determined by the sensors, an output of the processor is connected to the heating device 3 of the absorption cooling unit for controlling the heating power. Furthermore, an output is connected to the interior lighting 4 of the refrigerator, wherein the interior lighting can be controlled by the microprocessor in such a way that the lighting illuminates when the refrigerator door is opened and goes out again automatically after a predetermined time interval. The control device is supplied by means of an AC voltage source 5 , which on the one hand supplies the interior lighting and the heating device with voltage and on the other hand is connected to an AC / DC converter 6 which supplies the control device with DC current.

Claims (17)

1. Control device for a cooling device, in particular for an absorption cooling device, comprising a processor ( 1 ) and one or more sensors (S1-S6), the operation of the cooling device being controlled as a function of the values determined by the sensors via the processor ( 1 ) characterized in that the processor ( 1 ) has a programmable memory area ( 2 ) in which different operating data, in particular different temperature profiles, are stored, the operating data being selectable, changeable and readable via an interface (S4, S5). 2. Device according to claim 1, characterized in that the programmable memory area ( 2 ) has memory sections for further data, in particular for data for performing leakage tests for determining leaks in the cooling circuit and / or for identification data for identifying the cooling device, these data being about the interface can be selected, changed and read out. 3. Device according to claim 1 or 2, characterized in that the programmable memory area ( 2 ) is a flash EPROM and / or EEPROM and / or non-volatile RAM. 4. Device according to one of the preceding claims, characterized in that the interface (S4, S5) is an interface for wireless data transmission, includes in particular by infrared or radio. 5. Device according to one of the preceding claims, characterized in that the interface comprises a transmitting and receiving unit (S4, S5), via which data can be transmitted to the processor ( 1 ) or read out therefrom, whereby by the transmitting and Receiver unit (S4, S5) can be detected when the door of the cooling device is opened. 6. The device according to claim 5, characterized in that the interface (S4, S5) is part of a light barrier. 7. The device according to claim 6, characterized in that the light barrier an optical transmitter (S5), an optical receiver (S4) and a reflector (R), with the reflector (R) on when the door of the refrigerator is closed Signal from the transmitter (S5) to the receiver (S4) reflected. 8. The device according to claim 6 or 7, characterized in that a display (RD) is provided, which signals that the door of the refrigerator is open has been. 9. Device according to one of claims 6 to 8, characterized in that the Light barrier also serves as a door sensor, which determines whether the door of the cooling device is open or closed. 10. Device according to one of the preceding claims for use in a Absorption cooling device, characterized in that a sensor (S1) for Determination of the cold room temperature and / or a sensor (S2) for determining the Evaporator temperature (S2) and / or a sensor (S3) to determine the temperature of the Cooker of the absorption cooling device is provided. 11. Device according to one of the preceding claims, characterized in that the device can be coupled to an interior lighting ( 4 ) of the cooling device such that defects of the cooling circuit determined by the control device can be displayed via the interior lighting ( 4 ). 12. The device according to claim 11, characterized in that a timer is provided to limit the duty cycle of the interior lighting ( 4 ) when opening the door of the refrigerator. 13. The apparatus according to claim 11 or 12, characterized in that the Indoor lighting includes LED lighting. 14. Device according to one of the preceding claims, characterized in that that the device works according to rules of fuzzy logic. 15. Device according to one of the preceding claims, characterized in that the device with a central control and monitoring unit for Control and monitoring of a variety of cooling devices can be coupled. 16. The apparatus according to claim 15, characterized in that the central control and monitoring unit with the refrigerators via a wired and / or wireless network is networked. 17. Cooling device, in particular absorption cooling device, comprising a Control device according to one of the preceding claims.