DE3235642A1 - Device for electric defrost regulation for the evaporator of a refrigerating plant - Google Patents

Abstract

In the device, means for acquiring and storing the period between penultimate and ultimate defrost are provided. Means also acquire the acquisition values of the temperature difference of the air in front of and behind the evaporator, of the air humidity of the space air and of the switch-on times and period of a compressor connected to the evaporator. Connected to the means for acquiring these acquisition values are correcting means, in which tabulated correction values are assigned to the acquisition values. In the correcting means, the stored period can be converted into a corrected period. Switch-on means, which are connected to the correcting means, are triggered by these after expiry of the corrected period as of the completion of the last defrost period.

Description

Device for electrical defrost control for the

Evaporator in a refrigeration system Description: The invention relates to a device for electrical defrost control for the evaporator of a Refrigeration system according to the preamble of claim 1.

The prior art includes a number of defrosting devices those data that suggest the presence of a layer of frost on the evaporator can be evaluated in order to determine the next time of defrosting.

Such known defrosting devices can, for example, as a function can be set in motion by a time or program control. It is also known the number of switch-on processes of a compressor or a running time of the compressor, that belongs to the cooling system. In general, however, these S -; control processes inaccurate, so that too many or too few defrosting processes at incorrect defrosting times can be initiated.

In detail is in a known device for forced defrosting a timer is provided, on which the defrost times and the defrost duration manually can be set. Accordingly, these parameters cannot be set automatically change. For example, the defrost heater can be used accordingly with this device the setting every six hours for a preset duration of e.g. 45 minutes Must be switched on as a priority. - With this timer, so-called Blocking times are taken into account when defrosting is not required, such as during shop opening hours, high tariff times of electricity supply companies or to avoid overload peaks with powerful defrost heaters0 disadvantage is, however, that the set defrosting times and the defrosting duration are only very limited rough approximation with the actual Requirements in accordance can be brought to the one hand to sublimate layers of frost on the evaporator not to let it grow too much, but on the other hand not to let the heating too often or too long to trigger.

A better approximation of the real needs of defrosting allows another defrosting control belonging to the prior art, in which by two temperature sensors a temperature difference in the air flow in front of and behind the Evaporator is determined. For comparison with the actual temperature difference value, a setpoint is set manually on a transmitter, the defrost heater can be set using a separately arranged thermostats are switched off. Furthermore are with this Defrost control Means for setting minimum waiting times to be observed between the last defrost and the next expected defrost.

Defrosting processes cannot take place during these waiting times be effectively triggered. - The disadvantage of this defrost control is that the defrost only under certain conditions that are only occasionally met by chance, effectively removes the resulting layers of frost. In addition, switch-on processes can only be prevented accidentally in desired blocking times if these blocking times into the adjustable minimum waiting times between the last defrost and the next expected defrost.

Furthermore, a device for electrical defrosting control is known, in which the duration of the last defrost is measured and evaluated in order to determine At which of four possible defrosting times in a period the defrosting process is initiated. For the fourth mm possible point in time, there is a forced defrosting intended. - This measurement and evaluation of the last defrosting time also only leads to to a rough anticipated adjustment to the actual defrosting requirements.

About the deficiencies of the previously imprecise indirect triggering, which are difficult to remedy A direct triggering of the defrost is also known to avoid defrosting processes (DE-OS 30 01 019), which is responsive to the presence of a layer of frost Frost sensor for triggering a defrosting process includes. In detail is the Frost-FUhler designed as a temperature sensor and in one of the approved frost layer thickness arranged corresponding distance from an evaporator surface. The temperature sensor is connected to a control device. It switches on a defrost heater, if the Reiffuhlertemperatur falls below a reference temperature. The comparison temperature can in particular be the evaporator temperature. This defrosting device is but only with an exact triggering of the defrosting process related to the layer of frost to be expected, which arises at the point of the frost filament. In other words, this one Defrosting device is only accurate at one point, while frosting is accurate at another Place the vaporizer can only be closed. In addition, the Attachment of the frost piller itself the conditions of frost formation at this point can be changed undesirably.

In addition, this device sets a precise adjustment of the frost sensor on the wall of the evaporator ahead, so that because of this and because of the required Expenditure for the frost sensor and the evaluation of the signal generated by it larger coverage of the evaporator with several frost sensors does not seem sensible.

The object of the present invention is therefore to provide a device for electrical defrost control according to the type of indirect triggering of the defrost heater to further develop that the probable icing condition of the evaporator without the need for a large amount of errors and / or evaluation circuits can be determined exactly. The determination of the state of icing should be not limit to individual points of the evaporator, but rather this state if possible represent extensively. In addition, this facility should be a requirement to take into account desired blocking times, which allow defrosting as much as possible little affected.

This task is carried out in the characterizing part of the claim 1 specified invention solved.

According to the invention, if a Locking time is imminent, for the formation of the Jeweiffis nac: last defrosting time Completion of a defrosting process is based on the stored period of time, the occurred between the penultimate and the last defrost. This stored length of time is corrected in a way that reflects the expected extrapolated icing condition of the evaporator 0 First of all, the temperature difference is taken into account detected with two temperature sensors, one of which is a temperature sensor in the air stream is arranged in front of the evaporator and a temperature sensor behind the evaporator. With this arrangement, approximately the temperature of the total air flow is detected. By recording the compressor running time, it is taken into account that only then the Evaporator frosted up or more and more icy if heat is withdrawn from the evaporator will. The icing of the evaporator is greater, the longer the compressor run time is.

In connection with this, there is the detection of the air humidity, in particular the relative humidity of the room air, which is related to the running time of the compressor determines the icing that occurs on the evaporator. D, e terms are thereby over all switch-on times of the compressor from the last defrosting process considered. With this device is based on the time between last and penultimate defrost this time after completion corrected from the last defrost to the expected next switch-on of the defrost based on. The air humidity and the running times of the compressor are used for correction and the actual temperature difference values between the sensors are continuously determined and in the correction means compared with the values stored in tables.

According to the values of the recorded values determined from this these correction values thus formed determine the correction of the time between last and penultimate defrost and form the estimated time between the last and the next defrost. The last-mentioned period of time can therefore start out the time between the last and the penultimate defrost is both extended and can also be shortened.

Even then, there is no blocking period in the specified time interval is imminent, the next time the defrost heater for the evaporator is switched on exactly predetermined For this normal operating situation, an advantageous training the device for switching on the defrosting instead of a forced defrosting of only a few fixed defrosting times specified in claim 2. After that the next defrosting time is also waited until the one recorded The actual value of the temperature difference is equal to the optimized target value. The optimized The target value does not only depend on a manual fixed setting, but also on the Detection values of the air humidity, the duty cycle and the running time of the compressor, as well as the duration and time of the last defrost. Depending on these The set target value of the temperature difference is used to form the detection values an optimized target value constantly adapted to the respective icing situation, to trigger the defrost exactly when a predetermined icing condition is reached.

Desired blocking times during which defrosting should not take place.

can be effective without major impairment of defrosting according to claim 3 must be taken into account. The trend calculator turns this into a so-called Extrapolation time in good time before the next current defrost time determines when this defrosting time is extrapolated according to claim 1 Values is likely to occur. The defrost then immediately becomes the default one Extrapolation time triggered before the start of the blocking period if the extrapolated Defrosting time in a first blocking period highlighted from the blocking period would fall. Otherwise, if the extrapolated defrosting time ends in the remaining If the second blocking period would fall, there is initially no defrosting. It the next defrosting time from the current one is then repeated after the blocking time Acquisition values formed. - The blocking times can easily be included here correspond to the actually desired times in which the defrost heater does not should be switched on and there can still be too much icing unfavorable operating cases by bringing forward a defrosting process before the blocking time be avoided. To determine the blocking times or those between them Release times, the current time is recorded.

Particularly advantageous dimensions of the subdivision of the blocking times in the first and second blocking period sections and the extrapolation time are given in claims 5 and 6.

According to claim 8, the defrost heating is controlled by a defrost sensor signal switched off, which is compared with a defrost setpoint signal. Switching off therefore takes place independently of the determination of the defrosting time.

According to claim 9, defrosting processes can be carried out on several ^ * in one KeihlkreieiauS lying evaporators, which ever at least one Defrost heating is assigned to be optimized.

The evaporator can be provided to cool several pieces of furniture be. With the further development of the facility, the defrosting heaters become individual switched off by an assigned defrost sensor, insofar independent of one individual or joint engagement. Depending on the special requirements there is the possibility of the heaters in accordance with a predetermined master evaporator to be done or individually according to the respective requirements of the evaporator 1 which result from the values required for these.

According to claim 10, adjustable heating intensities can be used, for example with optional setting of several defrost heat amounts on one evaporator during activation the switching means are taken into account.

Indispensable means of generating error messages when limit values are exceeded by defrosting or cooling times, are in claims 11 and 12 specified.

An exemplary embodiment of the invention is described below with reference to a Block diagram described. The block diagram shows a conventional refrigeration system with an evaporator 1, with a compressor 2, which a refrigerant via a condenser 3 and a throttle point 4 promotes in the evaporator, indicated. With two temperature sensors 5 and 6, a temperature difference at an air flow part 7 - is determined, the is approximately the same as the temperature of the total air flow.

The electrical defrosting control includes a program control 8, the to means 9 for detecting the temperature difference as the actual temperature difference value and set up to record the humidity of the room air § in which the evaporator works is.

These mentioned frame values are temporarily stored in a memory 10. A part of the memory 10 is w-iterhin with a keyboard 11 in connection the values, for example limit values or setpoints, are entered in the device can be. With an output of the memory, a display device 12 is below Among other things, to display the stored temperature difference, actual values and humidity values as well as error messages if the specified cooling or defrosting times are exceeded are connected. This indicates faults, for example if the sensor is defective occur when switching means for activating the compressor or the defrost heater are disturbed or if there is not enough coolant in the circuit.

Another output of the memory leads to an S11 actual value comparator, in the setpoints set with an adjustable setpoint generator 14 for triggering cooling by switching on the compressor - indicated by block 15 - or a warning - block 16 - when limit values are exceeded. The calculated The actual value of the temperature difference is recorded in a block 17.

Following block 17 it can be seen from the drawing that through Switch-on signals from switch-on means for the condensation heating (not shown) are issued, the last defrosting time is detected by a block 19 and the Duration of the last defrost by a block 20, which is also controlled by switch-off signals, which emanate from the switch-off means 21 is controlled. In addition, in one Block 22 records the running time and the switching frequency of the compressor for formation of an optimized target value of the temperature difference are the detection values the humidity of the runtime of the compressor and the duration as of the time burst the last scan entered in a comparison table 23 via a program line 24 is controlled.

Using the detection values taken from the tables, a Computer 25 determines an optimized setpoint value for the temperature difference, which in comparison means 26 is compared with the actual temperature value and, if these values are equal, the Activation means 18 for triggering the defrosting process is activated. - The comparison table 23 can be implemented by a memory of the computer 25 and the comparison means 26 can be formed by the computer 25 at the same time.

With a lock timer 27 are lock times in which the defrost heating should not take effect, set and saved. The blocking times will be in an interrogation part of the lock timer, which detects the time, interrogated and fed into a trend calculator.

A first and a second blocking period are set in the cem trend calculator formed to 50 percent of a total blocking period and to a predetermined one The extrapolation time, in particular one hour before the next blocking period, is determined, whether based on the stored time T1 between the last and the penultimate defrost and the correction of this period of time is likely to be a defrosting time in the first or the second blocking period occurs. In the former case, immediately given a switch-on signal to the switch-on means 18, while in the second case a The switch-on signal is suppressed until the complete blocking time has elapsed and only then after the defrosting time has been determined again - control by the line 29 - the switching means 18 can be activated.

From the block diagram it can be seen that means 30 ur acquisition the time between the last and the last but one defrost is represented by a block 30 are on the output side with correction means 31 in connection stand.

23 are taken from the comparison table into the correction means evaluated detection values of the temperature difference (actual values), the air humidity and the switch-on times and duration of the compressor, with which the duration is corrected between the last and the last but one defrost.

The output of this correction means corresponds to the output of the trend calculator 28 in connection.

The means for recording the duration 30 and the correction means and the trend calculator are so effective after the end of a defrost that the time Ti stored in the means 30 between the last and the penultimate defrost . begins to expire and accordingly continuously in the correction books is corrected to the assessed detection means. The trend calculator extrapolates again at the specified extrapolation time, whether the anticipated switch-on time the defrost heater in a first o ¢: it falls into a second blocking period and in the former case, moves the time of thawing forward or postponed as described the possible time of defrosting in the second fold to the time after the blocking time has expired.

From the block diagram it can finally be seen that there is between the output of the trend computer and the Einscilaltmittel 18 adjuster 33 for the Number of heaters and means for detection 34 are arranged. - An adjuster for the home intensity for defrosting and associated detection means are not shown.

The defrost heating is switched off program-controlled - Line 24 - by a comparator 25, which acts on the Ibscha t means 21. In the comparator 25 is the actual temperature value determined in front of a defrost sensor 36 with a target temperature value compared.

In addition, the defrost heating can be switched off automatically, if a stored, fixed, predetermined limit value for the duration of the exposure is exceeded is and the switch-off 21 for the defrost heater via line 24 a corresponding Order received. This incident is, as described above, with the display means 12 reported.

Claims (12)

Claims b device for electrical defrost control for the evaporator of a refrigeration system with means for determining the next defrosting time depending on the previous defrosting time, this is no longer possible n z e i c h n e t that means (30) for detecting and storing the duration (T1) between the last but one and the last defrost, means (9, 10, 22) for the acquisition of values for the temperature difference (actual value) of the air and behind the evaporator (1), the humidity of the room air and the switch-on times and duration of a TTerdicenter (2) connected to the evaporator are provided, that with the means (9, 10, 22) for detecting the detection values, correction means (31) in which tabulated correction values for the detection values are assigned and the saved time period according to the correction values in The corrected period of time is changeable, and that with the correction means (31) Switch-on means (8) are connected in the defrost heater, which is provided by the correction means after the corrected time has elapsed from the end of the last defrosting time can be initiated. 2. Device according to claim 1, characterized in that i chnet means for recording (22) and storing the duration and time of the last defrost and the means (9, 10, 22) for detecting and storing the detection values of the air humidity and the duty cycle of the compressor with a computer (25) for calculating a optimized setpoint of the temperature difference are in connection-g that the optimized Setpoint in comparison means (26) for comparison with the recorded Temperature difference actual values can be fed in, and that with the comparison means (23) the switch-on means (18) of the defrost heater are connected. 3. Device according to claim 1 or 2, d a d u r c h g e k e n n z e i c h n e t that a preset blocking times for compressor switch-on, queryable blocking timer (27, 27a) at inputs of one with the corrected time period biased trend computer (28) is connected, the output of which is connected to the switch-on means (18) is in connection and which is designed so that, when subdivided, each Locking time according to a predetermined ratio in a first and in a second Blocking period the switch-on means in a predetermined extrapolation time triggers before the beginning of the blocking period if it has corrected a Defrosting time calculated as falling in the first blocking period, and the switch-on means (18) triggers after the locking time has elapsed if it is the time of defrosting calculated as falling in the second blocking period. 4. Device according to claim 3, d a du r c h g e k e n n z e i c h n e t that with the output of the trend computer (28) program control means (8) for Re-acquisition of the acquisition values and creation of the next defrosting time after the blocking period has expired, which can be activated when the last defrost time calculated with detii tendency calculator in the second blocking period has fallen. 5. Device according to claim 2, d a d u r c h g e k e n n z e i c That is, the first and the second blocking period are each 50 percent of the total The blocking period. 6. Device according to claim 3 or 4, d a d u r c h g e k e n n z e i c h n e t that the extrapolation time in the means (8) for program control is set to one hour before the start of the blocking period. 7, device according to claim 1 or 2, d a d u r c h e k e n n z e i c h n e t that an adjustable setpoint generator (14) for the temperature difference vine Comparison junction (23) to which the actual value signals of the temperature difference are applied is connected. 8. Device according to one of claims 1 to 7, characterized in that that a defrost sensor (36) built into the evaporator (1), a defrost setpoint adjuster and a comparison junction (25) are provided in which the difference in a defrost sensor signal and a defrost setpoint signal is formed, and that with switch-off means (21) with the defrost heater is connected. 9. Device according to one of claims 1 to 8, characterized in that that for a number of evaporators arranged in a refrigeration circuit, each with one Defrost heater a setting (33) for the number of defrost heaters and means (34) for recording the set number are provided, which the switch-on means (18) and switch-off center, .n (2S) for individual or joint activation of the defrosting heaters urd are gated for individual shutdown. 10. Device according to one of claims 1 to 9, characterized in that that intensity-adjustable defrosting heatings are in place and means of recording the intensity setting from the correction means (31) or the trend calculator (28) controlled switch-on means (18) are connected upstream. 11. Device according to one of claims 1 to 10, characterized in that that a memory of a preset maximum defrosting duration on the one hand and the Switch-on means (18) and the switch-off means (21) of the defrost heater on the other hand are connected to a limit value comparator, the output of which leads to the display device (12) is performed. 12. Device according to one of claims 1 to 11, characterized in that that a memory of a preset maximum cooling time on the one hand and switch-on as well as switch-off means for the cooling (15) on the other hand with a further limit value comparator are connected, the output of which is led to the display device (12).