Ice bank control with voltage protection sensing

Information

  • Patent Grant
  • 6374622
  • Patent Number
    6,374,622
  • Date Filed
    Monday, April 16, 2001
    23 years ago
  • Date Issued
    Tuesday, April 23, 2002
    22 years ago
Abstract
The present invention is an apparatus and method that regulates the size of an ice bank (50) and that prevents short cycling of the compressor (30) therefor and operation thereof at undesired voltages. A microprocessor based control circuit (10) includes a circuit for sensing line voltage (14) combined with an ice bank sensing circuit (18, 20). The ice bank sensing circuit is of the conductivity sensing type wherein the electrical conductivity between two probes (P1, P2) is sensed. The microprocessor (16) continually monitors the probes (P1, P2) to determine if refrigeration is needed or not, and continually senses the line voltage to determine if that voltage is within the design limits of the refrigeration compressor (30). The voltage sensing circuit (14) can also sense if power has been interrupted where the voltage drops to zero.
Description




FIELD OF THE INVENTION




The present invention relates generally to electronic ice bank controls and to voltage sensing controls.




BACKGROUND OF THE INVENTION




Ice banks that are formed on evaporators for providing a cooling reserve, as used in the beverage dispensing industry, are well known. The size of an ice bank is typically regulated by one or more sensors placed at critical positions around an outer perimeter thereof. Conductivity sensors are known and are used in this regard to determine the presence of ice or water by virtue of the conductivity between a pair of probes. Thus, if ice forms between the probes the sensed conductivity will be relatively low, and if water is present there between, the sensed conductivity will be much greater. Therefore, if ice is sensed, the ice bank is presumed to be of adequate size and the refrigeration compressor, that is used to cool the evaporator and form ice thereon, can be shut off. Conversely, if water is sensed, the compressor is turned on to build ice until ice is again sensed. Naturally, such controls have delay times programmed therein to prevent destructive short cycling of the compressor.




It is also well understood that it can be harmful to a compressor if it is made to run at a voltage that is outside, above or below, the voltage range for which it is designed. This situation is common for beverage dispensing equipment used in remote areas where line voltage can fluctuate dramatically. Buck/Boost systems, that attempt to lower or raise the voltage, respectively, have been attempted, but without great success do to the complexity and cost thereof. Adding a voltage sensing system that can turn the compressor off if its voltage design limits are exceeded, is also a possibility. However, the cost of an additional electronic control can be unacceptable. Especially where such an additional control would need to become a standard part of all such dispensers, many of which will experience no need therefor. It is also generally too expensive to provide such voltage sensing as a custom feature. Accordingly, it would be desirable to have a cost effective control for an ice bank that both regulates the size thereof, that protects the compressor against short cycling and from operating at voltages outside its design specification.




SUMMARY OF THE INVENTION




The present invention is an apparatus and method that regulates the size of an ice bank and that prevents short cycling of the compressor and operation thereof at undesired voltages. A microprocessor based control circuit includes a circuit for sensing line voltage combined with an ice bank sensing circuit. The ice bank sensing circuit is of the conductivity sensing type wherein the electrical conductivity between two probes is sensed. Thus, the microprocessor continually monitors the probes to determine if refrigeration is needed or not, and continually senses the line voltage to determine if the voltage is within the design limits of the refrigeration compressor. The voltage sensing circuit can also sense if power has been interrupted where the voltage drops to zero.




In operation, the present invention will turn on the compressor if the ice bank sensor indicates water is present between the probes, the voltage is within operating limits and if a predetermined time delay has elapsed since the last compressor shut down. The compressor is turned off if, during operation thereof, the ice bank is of sufficient size, the voltage goes outside of design limits or there is a power failure. It can be appreciated that the voltage sensing circuit can be comprised essentially of a relatively inexpensive voltage divider circuit of a dedicated transformer. Therefore, the present invention utilizes the inexpensive combination of such a voltage sensing circuitry with a conductivity/ice sensing circuit to provide for an ice bank control that is more protective of the compressor with respect to both short cycling and operating at voltages outside the manufacturer's recommended specifications, than is found in prior art ice bank sensing controls. Since the improved control of the present invention is relatively inexpensive, it can be used as a standard item rather than as a more costly custom or add on feature.











DESCRIPTION OF THE DRAWINGS




A further understanding of the structure, function, operation, and objects and advantages of the present invention can be had by referring to the following detailed description which refers to the following figures, wherein:





FIG. 1

shows an electrical schematic of the control of the present invention.





FIG. 2

shows a schematic diagram of the present invention.





FIGS. 3A and 3B

show a flow diagram of the operational control of the present invention.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT




The control system of the present invention is seen in FIG.


1


and generally designated by the numeral


10


. Control


10


includes a power supply circuit


12


including a transformer T


1


connected to a power source, in this example, of 115VAC. Power supply


12


provides for outputs of 18VAC, 24VDC and 5VDC, where D


1


provides for the rectification of the current from AC to DC. R


4


, R


6


and C


7


comprise a voltage detection circuit


14


wherein the voltage along the 24VDC line is sensed. Circuit


14


is connected to a microprocessor


16


by pin


17


. Those of skill will understand that R


4


and R


6


function as a voltage divider circuit to bring the detected voltage changes within a range that is useful to microprocessor


16


. Of course, microprocessor


16


also includes an analog to digital converter for converting the DC signal from circuit


14


to a usable digital form. In the present example, microprocessor


16


is a Microchip model PIC16C11.




Ice bank detection probes P


1


and P


2


form part of an ice probe circuit


18


. R


22


, R


2


and Q


5


comprise a signal conditioning circuit with an input to pin


1


of microprocessor


16


. This conditioning is needed as the probe input impedance is generally too high for microprocessor


16


. Probe P


1


is connected by line L


5


to probe signal circuit


20


, and output pins


9


and


10


are connected to circuit


20


by lines L


6


and L


7


. Resistors R


7


, R


8


, R


9


and R


10


along with diode D


3


and transistors Q


1


and Q


2


provide for a 5VDC signal and a −5VDC signal to L


5


. The −5VDC is provided by power supply circuit


22


.




A clock circuit


24


is provided and connected to microprocessor


16


by input pins


15


and


16


. A power relay switching circuit


26


includes a relay


28


for operating a switch K


1


. Switch K


1


is connected to a compressor


30


. Pin


8


of microprocessor


16


is connected to circuit


26


for controlling the operation of relay


28


. Pin


6


can be used to detect the line power interruptions.




As seen in the block diagram of

FIG. 2

, control


10


is used in the context of a beverage dispensing machine


40


. As is known in the art dispenser


40


includes a water bath tank


42


containing a volume of water and an evaporator


44


. Evaporator


44


is part of a mechanical refrigeration system including compressor


30


, a plurality of refrigerant lines


45


, a condenser


46


, a condenser cooling fan


48


, and an expansion valve


49


. As is well known in the art, the refrigeration system operates to cool evaporator


44


to form an ice bank


50


thereon. Probes P


1


and P


2


are seen within dashed circle


52


in enlarged form, relative to ice bank


50


. Those of skill will appreciate that probes P


1


and P


2


are in actuality positioned at a distance from evaporator


44


to which it is desired that ice bank


52


is to grow. As is also known, a plurality of beverage lines


54


extend through bath


42


and deliver potable beverage from sources thereof, not shown, to one or more beverage dispensing valves


56


. Thus, ice bank


50


provides a cooling reserve for the heat exchange cooling of the beverages as they pass through lines


54


so that compressor


30


need not run all the time that cooling is required. A light


58


indicates when compressor


30


is running.




The general operation of electrical conductivity based ice bank controls is well known in the art. The conductivity approach takes advantage of the substantial known difference between the electrical conductivity of water and that of ice. Thus, where the sensed electrical conductivity is low due to essentially no current flow between the probes, ice is indicated as ice is a poor electrical conductor. Conversely, when current is readily conducted between the probes, then water there between is indicated as the conductivity thereof, in most conditions, is dramatically higher than that of ice. Accordingly, when a high conductivity is sensed water between the probes is indicated. As a result thereof, it is assumed that the ice bank has eroded to a point that the refrigeration system must be turned on to build the ice bank up to a size that maintains an adequate cooling reserve. Once the probes are again covered with ice, the lower conductivity is sensed and it is assumed that the ice bank has grown back to its desired size and further refrigeration can be stopped.




In the present invention, a current is passed between probes P


1


and P


2


from line L


5


by operation of circuits


18


and


20


. The present invention uses the known convention, as represented specifically by circuit


20


, of alternating the voltage there between to eliminate a net electrical plating or deposition on either probe P


1


or P


2


. Thus, microprocessor


16


serves to control that voltage switching. As described above, when the conductivity between probes P


1


and P


2


is sensed as high by microprocessor


16


, water there between is indicated and compressor


30


can be turned on. Conversely, when the sensed electrical conductivity is low, ice between probes P


1


and P


2


is indicated, and compressor


30


can be shut down.




To get a better understanding of the specific mode of operation of the present invention with respect to the control and interrelation of voltage sensing and conductivity sensing, attention is drawn to the flow diagrams


3


A and


3


B. At block


60


compressor


30


is off and at block


62


microprocessor


16


is continually reviewing the conductivity data as produced by probes P


1


and P


2


and circuit


18


. If the conductivity reading indicates that water is present, then the yes arrow is followed from block


62


to block


64


. If ice is indicated, then no further cooling is required and the system returns to compressor off block


60


. At block


64


a preset time delay is contained in the controlling software, as is known in the art to prevent the startup of compressor


30


prior to the elapse of a predetermined time period. That time period, such as three minutes, serves to protect compressor


30


from destructive short cycling. If this protective predetermined time period has timed out, then the control logic proceeds to block


66


. It can be appreciated that voltage detection circuit


14


can sense if there has been a power interruption where the sensed voltage drops to zero. Thus, the control of the present invention has a further short cycling safeguard represented by block


66


where, if power is interrupted, the above predetermined time delay is also utilized to prevent premature start up of compressor


30


. If the predetermined time period has also timed out since the last power interruption, then at block


68


, circuit


14


is used to determine if the sensed line voltage is within the recommended operating limits of compressor


30


. If the sensed voltage is within such parameters, then at this point, block


70


, compressor


30


can be turned on. After a time delay represented by block


71


, microprocessor


16


continually monitors the line voltage, whether or not there has been a power outage and whether of not probes P


1


and P


2


are indicating that cooling is still required. The foregoing monitoring is represented by blocks


72


,


74


and


76


respectively. Thus, if after the time delay of block


71


, the line voltage goes out of range, or the power is interrupted or probes P


1


and P


2


become covered with ice and no further growth of the ice bank is required, then the system herein returns to the compressor off condition of block


60


.




Those of skill will appreciate that the control of the present invention can provide for both line voltage compressor protection and ice bank sensing and management at a very minimal cost over the cost of ice bank management alone. Thus, it is cost effective that the control herein be used as a standard item rather than as a custom control only for the beverage dispensing machines thought to have the greatest likelihood of encountering voltages outside of the compressor's design limitations.



Claims
  • 1. A control for operating a beverage dispensing machine, the beverage dispensing machine having a refrigeration system including a compressor for cooling an evaporator positioned in a water bath for forming an ice bank thereon, the control comprising:a voltage sensing circuit for determining the voltage of an incoming line providing power to the compressor, an ice bank sensing system including conductivity probes positioned within the water bath and a conductivity sensing circuit for determining the conductivity between the probes and the compressor operated to provide for cooling of the evaporator for forming ice thereon when the voltage sensing circuit determines that the incoming line voltage is within design limits of the compressor, and when the ice bank sensing system determines that further formation of ice is required and when a predetermined time delay has timed out since the compressor last operated.
  • 2. The control as defined in claim 1 and the voltage sensing circuit also sensing for a power outage and not running the compressor for the predetermined time period subsequent to the sensing of a power outage.
PCT Information
Filing Document Filing Date Country Kind
PCT/US99/18366 WO 00
Publishing Document Publishing Date Country Kind
WO00/09960 2/24/2000 WO A
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3502899 Jones Mar 1970 A
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4703770 Arzberger et al. Nov 1987 A
4754609 Black Jul 1988 A
4843830 Haul Jul 1989 A
5022233 Kirschner et al. Jun 1991 A
5757667 Shannon et al. May 1998 A
5839291 Chang Nov 1998 A
6003318 Busick et al. Dec 1999 A
6220047 Vogel et al. Apr 2001 B1