CA1169139A - Energy management system for chilled product vending machine - Google Patents

Abstract

ABSTRACT OF THE DISCLOSURE

The present invention relates to an energy conservation system for chilled-product vending machines, and more specifically, a control circuit for a convection type refrigeration system for a vending machine which dispenses chilled products such as beverage cans or bottles. The specification discloses a refrigeration system including a refrigeration compressor, a temperature sensor for detect-ing the temperature within said vending machine and turning said compressor ON and OFF to define a compressor cycle in response to the detection of predetermined temperature limits, an evaporator coil and evaporator fan means for blowing air across said evaporator coil and circulating said air throughout said vending machine. In this specification there is disclosed a means for cycling said evaporator fan ON simultaneously with said compressor for a time period at least as long as said compressor cycle; and a means for cycling said evaporator fan OFF a predetermined period of time after said compressor is turned OFF, said period of time being long enough to permit the temperature of said evaporator coil to temperature stabilize above the freezing temperature of water. The system may further comprise a cycle timer for intermittently cycling said evaporator fans ON and OFF for predetermined periods between said compressor cycles to thereby maintain an even distribution of chilled air within said machine and minimize temperature fluctuations of the chilled products.

Description

~169139 BACKGROUND OF THE INVENTION
Field of the Inventio_ The present invention relates to an energy con-servation system for chilled-product vending machines.
5- More specifically, the present invention relates to a control circuit for a convection type refrigeration system for a vending machine which dispenses chilled products such as beverage cans or bottles.
Description of the Prior Art Heretofore, in refrigeration systems of vending machines including a compressor, a condenser, evaporator coil and an evaporator fan, the compressor has been cycled ON and OFF under the control of a thermostat, and the evaporator fan, which blows air over the evaporator coil to circulate chilled air throughout the vending machine, has been run continuously even during the periods when the compressor was OFF. The unnecessary high energy usage and waste caused by the continuous running of the evaporator fan or fans, has become a problem with the current high cost of energy. One logical solution to re-ducing the consumption of energy is to cycle the evaporator fan motor ON and OFF with the compressor thus decreasing the running time of the evaporator fan. However, this approach causes several problems, the discovery of which are part of the present invention.
Firstly, if the evaporator fan is cycled off in synchronism with the turning OFF of the compressor, freeze up of the evaporator coil can occur in humid, high tempera-ture conditions. Secondly, by keeping the evaporator fan shut off during the compressor off cycles, large variations in temperature in the vending machine occur, creating large variations in temperature of the next to be vended products.
Also, during this off period of the evaporator fan, large variations of temperature occur throughout the vending machine due to lack of air flow, and temperatures sensed by the thermostat which controls the compressor cycling are less accurate than desirable. Thirdly, when vending "~

~ ~L69 13~

-2-machines are located in below freezing environments, (32F) an idyl condition of the evaporator fan may permit the chilled products to freeze. That is, when the evaporator fan is running and blowing air over the evaporator coil and throughout the vending machine, this flow of air dissipates heat generated by the evaporator fan motors thus acting as a heater to prevent the stored products from freezing. Thus, the aforementioned problems exist when the evaporator fan is permitted to cycle on and off with the compressor, even though a substantial reduction in energy consumption results.
Accordingly, a need in the art exists for a system which will reduce the consumption of energy in the refrig-eration system of a vending machine, but will at the same time solve the aforementioned problems of evaporator coil freeze up in high, humid temperature conditions; product freeze up in below freezing environmental conditions; and large variations in next to be vended products and tempera-ture distribution throughout the vending machine.

SU~D~ARY OF THE INVENTION
Accordingly, it is a primary object of the present invention to provide an energy management system for a vending machine which conserves energy but still maintains efficient and accurate cooling of the vended products within acceptable limits.
It is a further object of the present invention to provide an energy management system for a vending machine which conserves energy but precludes freeze up of the evaporator coil in high, humid temperature conditions.
It is another object of the present invention to provide an energy management system for a vending machine whereby the vended products dispensed are within acceptable and predictable temperature ranges.
It is still another object of the present invention to provide an energy management system for a vending machine wherein temperature fluctuations throughout the volume of the vending machine are kept to a minimum.

116913~

~t is yet another object of the present invention to provide an energy management system for a vending machine whereby product freeze up is precluded when the vending machine is located in below freezing environments.
These and other objects of the present invention are achieved by providing a control circuit including at least three (3) timers for cycling the evaporator fans on and off independently of the operation of the compressor of the refrigeration system. In the system of the present invention, the evaporator fan is cycled on with the compressor and continues to run during the entire com-pressor on cycle as is conventional, but by means of a first timer the evaporator fan is permitted to run for an additional delay period following the cycle OFF of the compressor. During this additional delay period of the evaporator fans, the fans continue to blo~l air over the evaporator coil until the temperature of the evapora-tor coil is sufficiently above the freezing point of water (32F, 0C), and are then c~cled off. In a typical example, this cycle off of the evaporator fan may be anywhere from two (2~ to five (5) minutes after the compressor has cut off, which enables the temperature of the evaporator coil to reach stabilization above 32F.
A second cycling timer is provided to intermit-tently cycle the evaporator fans on and off for predeter-mined short intervals following the above described delay period7 and during the time when the compressor is off.
This intermittent cycling of the evaporator fans on and off forces air through the product stacks of the vending machine to provide a relatively even distribution of temperature throughout the off period of the compressor to allow for proper and precise heat sensing of the product through the vendor thermostats. This intermittent actuation of the fans and flow of air also limits the fluctuation of drink temperature, mainta~ning them within acceptable tolerances.
A third timer is provided to preclude freezing of ~ 69 139 the vended products and/or the evaporator coil when a vending machine is disposed in a below freezing environ-ment. This timer is enabled when the thermostatic tem perature switch which controls the compressor opens, and will time out to cycle on the evaporator fans for continu-- ous operation for a predetermined period of time if the temperature switch remains open in excess of a predeter-mined period of time, for example four (4) hours. That is, by sensing the compressor off period, (the period that the temperature switch is open), the evaporator fans are cycled on for a continuous period of operation to preclude freeze up of the products when the off period of the compressor (the temperature switch open) exceeds a predetermined limit such as four (4) hours.
An additional optional timer may be provided in combination with the other timers of the present invention for turning the refrigeration system on at a predetermined time in the morning and disabling the system at a pre-determined time in the evening. This optional timer obviously would further assist in the energy conservation objectives of the present invention by shutting down all power consumption during the period that the vending machine is not in use.
The timers utilized in the control circuit of the present invention are electromechanical cam timers which are commercially available components and are hard-wired in circuit with the power source and other compon-ents of the refrigeration system in a manner to be des-cribed hereinafter. However, it should be understood that the timing functions of the present invention could be performed by a general purpose digital computer or by microprocessor technology programmed to perform the desired functions.
Thus the present invention provides, in a refrig-eration system for a chilled product vending machine including a refrigeration system for a chilled product vending machine including a refrigeration compressor, -~t , ,~..

temperature sensor means for detecting the temperature within said vending machine and turning said compressor ON and OFF to define a compressor cycle in response to the detection of predetermined temperature limits, an evaporator coil and evaporator fan means for blowing air - across said evaporator coil and circulating said air throughout said vending machine, the improvement com-prising:
means for cycling said evaporator fan means ON for a time period at least as long as said compressor cycle;
and means for cycling said evaporator fan means OFF
at a point in time after said compressor is turned OFF, said point in time being long enough after said compressor is turned OFF to permit the temperature of said evaporator coil to stabilize above the freezing temperature of water, and cycle timer means for intermittently cycling said evaporator fan means ON and OFF for predetermined periods between said compressor cycles to thereby maintain an even distribution of chilled air within said machine and minimize temperature fluctuations of the chilled products.
In another aspect the invention provides such a refrigeration system, wherein the improvement comprises:
sensor means for detecting when said compressor is cycled OFF;
timer means responsive to said sensor means for measuring the length of time that said compressor is cycled OFF and for generating an enabling signal when said length of time exceeds a predetermined duration; and circuit means responsive to said enabling signal for cycling said evaporator fan means ON continuously until said compressor turns ON.
In another embodiment the present invention provides such a refrigeration system wherein the improve-ment comprises:
detector means responsive to the temperature of 116gl39 the environment surrounding said vending machine and generating a signal when said temperature drops below a predetermined limit; and circuit means responsive to said signal for 5 - cycling said evaporator fan means ON to run continuously for a predetermined period of time.

BRIEF DESCRIPTION OF THE DRAWINGS
_ _ _ The objects and the attendant advantages of the present invention will become readily appreciated as the same become better understood by reference to the fol-lowing detailed description when considered in conjunction with the accompanying drawings in which like reference numerals designate like parts throughoutthë Figures thereof, and wherein:
Figure 1 is a cross sectional view of the inside of a typical chilled-product vending machine having a convection cooling system;
Figure 2 is an electrical schematic diagram of the control circuitry of the present invention for operating the convection cooling system within the vending machine of Figure l;
Figure 3 is a timing diagram of the electrical signals present at selected terminals of the circuit diagram of Figure 2 to be referenced hereinafter; and Figure 4 is another timing diagram of electrical signals present at other terminals in the circuit of Figure 2 to be referenced hereinafter.

DETAILED DESCRIPTION OF THE DRAWINGS
Referring in detail to Figure 1, there is generally illustrated in cut away view a typical product vending machine wherein a plurality of products such as soft drink cans or bottles are stored in product stacks PS, from which they are sequentially dispensed on demand through appropriate vend slots in the bottom of the vending machine. As illustrated in Figure 1, the vending machine thereof also includes a convection refrigeration system l~B9139 which includes the conventional components of a refrigera-tion compressor, having a fan CF and a pump CP, an evaporator coil EC, an evaporator fan motor EEM, and a thermostatic temperature switch TS (not shown), for 5 - controlling the operation of the refrigeration system in response to the temperatures sensed within the vending machine. The conventional convection refrigeration system illustrated in Figure l operates to chill the products in product stacks PS, by blowing air by means of evaporator fan motor EFM over evaporator coil EC to thereby circulate chilled air between and throughout the product stacks PS.
Air returns from the stacks as indicated by arrows AR.
In conventional prior art convection refrigeration systems of vending machines known heretofore, the compressor C is cycled on and off under control of thermostatic temperature switch TS, while the evaporator fan motor EEM runs continu-ously, even during the periods that compressor C is de-energized. This continuous running of the evaporator fan motor EFM obviously expends a lot of unnecessary electrical energy and generates heat leading to unnecessary energy waste. Accordingly, in accordance with the objects of the present invention, the control circuit of Figure 2 was designed to energize the evaporator fan motor EFM only during optimum times when its operation is clearly needed.
For example, in accordance with the present invention, the evaporator fan EFM operates continuously during the period that the compressor C is operating, operates for a predeter-mined delay period following the cycle OFF of the com-pressor in order to preclude freeze up of the evaporator coil EC, operates intermittently for predetermined periods when the compressor C is cycled OFF, and it is cycled ON
to run continuously for a period following an interval when the compressor has not operated for an extended period of time, to preclude freezing of the products in the vending machine in sub-freezing environmental locations.
Referring in detail to Figure 2, there is illus-trated an elec~rical circuit diagram of the control 11~9139 circuitry of the present invention for operating the con-vection refrigeration system illustrated in Figure 1. A
pair of main power lines PLl, PL2 are provided across which a conventional 120 volt, 601~Z power source is con-nected. Also connected in parallel between power lines PLl, PL2 are a plurality of timers E, fp, D, Cy. Because these respective timers are connected in parallel, they are effectively hardwired in OR logic with respect to evaporator fan motors EFM. Thus, each of the respective timers E, fp, D and Cy can effect a time control function over evaporator fan motors EFM to be described in more detail hereinafter.
Beginning at the top of Figure 2, the first timer E, may be a 24 hour clock controller for cycling the refrigeration system ON and OFF at predetermined times of day. That is, by means of timer E, the refrigeration system can be enabled or disabled for any specified period on a daily basis. Timer E is coupled to power line PLl through a temperature switch TS at terminal C thereof.
Included within timer E is time control switch Sl between terminals C and NC and a timer motor TMl between terminals Ll and L2. Terminal NC is also coupled to the compressor and th0 condensor fan motors of the refrigeration system of Figure 1 and terminals Ll and L2 are coupled to power lines PLl and PL2, respectively. Timer E in one embodi-ment, is a multi-pulse cam timer manufactured by Eagle Signal Corporation, and identified as "multi-pulse timer catalog number MP-l-A6-32-M~5-48".
Timer fp is provided in the control circuit of Figure 2 to energize evaporator fans EFM continuously when the compressor C of the refrigeration system has not operated for an extended period of time, for example four (4) hours or more. The failure of the compressor C to operate for such an extended period of time would normally occur when the vending machine is placed in a sub-freezing environment which eliminates the need for internal cooling of the machine. However, this sub-freezing environment ~--7 .

1169~39 also may create a problem in that the chilled products may freeze up when the machine is placed in extremely cold external environment conditions. Accordingly, the timer fp is utilized to sense these extended periods in which the compressor C does not run and turn ON the evaporator fans EFM to run continuously and thereby blow air over the products to preclude freeze up thereof.
Timer fp includes external terminals 1, 2, 3, 4 and 11.
Terminal 1 of timer fp is connected to terminal c of timer E. Terminal 2 of timer fp is externally connected to power line PL2. Terminal 3 of timer fp is connected to the terminal 5 of timer D and through ]unction FJ to fans EFM. Terminal 4 of timer fp is hardwired to terminal 11 thereof which ~n turn is coupled to power line PLl.
Timer fp includes a timer motor TM2 which is coupled at one end to a wire connecting terminals 1 and 2 thereof, and at an opposite end through a switch S2 to terminal 11.
Also provided in the wire connection between terminals 1 and 2 of timer fp is a clutch coil Cl. In addition, a switch S3 is coupled between terminals 3 and 4 of timer fp. Timer fp may, for example, be an electromechanical cam timer manufactured by Eagle Signal Corporation under the description "Cycle-Flex timer catalogue number H~58-A6-01".
Timer D is provided to maintain evaporator fans EFM ON for a predetermined time or delay period after the compressor C is~turned OFF. This delay period is necessary under some environmental conditions to preclude freeze up of the evaporator coil EC. That is, since evaporator fan motors EFM will continue to run at the end of a compressor cycle for a predetermined period of time, the temperature of the evaporator coil due to this moving air is elevated to a safe temperature above the freezing point of water before the evaporator fans EFM are turned OFF under the control of timer D. Timer D includes a plurality of external terminals numbered 1, 2, 3, 4, 5 and 11, in the same manner as the like terminals of timer fp. Timer D

1 169 1 3g is in the preferred embodiment of the present invention, similar to timer fp with the exception of the specific function it performs, the addition of terminal 5, and the manner in which it is connected in the circuit of Figure 2. Terminal 1 of timer D is connected to terminal NC of timer E. Terminal 2 of timer D is connected to power line PL2. Terminal 3 of timer D is connected to terminal L2 of timer Cy to be described hereinafter.
Terminal 4 of timer D is hardwired to terminal 11 of timer D which is in turn, coupled to power line PLl.
Terminal 5 of timer D is as stated hereinbefore, connected directly to terminal 3 of timer fp and through junction FJ to fans EFM. Timer D also includes a clutch coil C2 coupled between terminals 1 and 2 thereof, a timer motor TM3 connected between clutch coil C2 and terminal 2 at one end thereof, and an opposite end thereof coupled through a switch S4 to terminal 11. A switch S5 is also provided in timer D for completing a circuit between terminals 3 and 4 or terminals 4 and 5 as controlled by timer motor TM3 in a manner to be described hereinafter.
A cycle timer Cy is provided to intermittently energize evaporator fans EFM during periods in which the compressor C is de-energized. This is desirable in order to provide a more even temperature distribution throughout the vending machine during the off period of the compressor in order to enable more accurate temperature sensing within the vending machine during that period and a more limited fluctuation of the temperature of the chilled products in product stacks PS. Timer Cy includes a plurality of external terminals Ll, L2, 2 and 3. Terminal Ll of timer Cy is coupled to power line PL2. Terminal L2 of timer Cy as stated herein-before, is coupled directly to terminal 3 of timer D.
Terminal 2 of timer Cy is hardwired to terminal L2 of timer Cy. Terminal 3 of timer Cy is coupled through junction FJ to the evaporator fan motors of the refrigera-tion system of the present invention. A timer motor TM4 is provided within timer Cy between terminals Ll and L2 for the timed operation of a switch S6, coupled be-tween terminals 2 and 3, in a manner to be more fully described hereinafter. Timer Cy in one ~mbodiment of the present invention, is electromechanical cam timer manufactured by Eagle Signal Corporation under the description "flexopulse timer number HG-94-A6".

DESCRIPTION OF OPERATION
_ The operation of the control circuit of Figure 2 can best be understood in conjunction with the timing diagrams of Figures 3 and 4 as described hereinafter.
Referring in detail to Figure 3, waveform E
represents the output at terminal NC of timer E. Wave-form TS represents the ON-OFF state of thermostatic temperature switch TS. Waveform D represents the output at terminal 5 of timer D over the control period illus-trated in Figure 3. Waveform Cy represents the inter-mittent timing pulse output generated by timer Cy at output terminal 3 over the control period. The remaining waveform of Figure 3 labeled FAN(S) illustrates the cycle of operation of the evaporator fan motors EFM
in response to the timing controls provided by the waveforms E, TS, D and CY.
Referring in detail to Figure 4, there is illus-trated a plurality of timing waveforms illustrating thefunction of timer fp. Waveform TS represents the ON-OFF
periods of temperature switch TS. Waveform fp represents the output with respect to time at terminal 3 of timer fp and the waveform labeled FAN(S) illustrates the ON-OFF
periods of the evaporator fans EFM in response to the combined control of temperature switch TS and timer fp.
Having now generally described the content of the timing diagrams of Figures 3 and 4, the detailed opera-tion of the control circuitry of Figure 2 may now be explained by reference to Figures 2 in conjunction with Figures 3 and 4.

1 1~9 139 In normal operation the compressor C of the refrigeration system illustrated in Figure 1 is turned on in response to the closing of temperature switch TS
when the temperature within the vending machine rises above a predetermined level. However, temperature switch TS will not turn the compressor C on, unless switch Sl of timer E is closed providing a closed circuit path between power line PLl, the compressor and power line PL2~ The function of switch Sl will be - 10 explained further hereinafter. The closing of tempera-ture switch TS also provides a circuit path through clutch coil Cl of timer fp and power lines PLl and PL2.
That is, the closing of temperature switch TS energizes the clutch coil Cl. With clutch coil Cl energized, timer motor TM2 of timer fp can not rotate. Timer E is an optional 24 hour clock~controller which may be utilized to turn the refrigeration system of the present invention ON and OFF for any specified period daily. For example, as illustrated in Figure 3 by waveform E, the refrigera-tion system may be turned ON at 9:00 AM and OFF at 5:00 PM, by means of timer E. This ON-OFF period is controlled by timer E by the opening and closing of switch Sl which is controlled by timer motor TM1 in conjunction with ap-propriate timing cams. If this option is not required, switch Sl may be locked in a closed position to effective-ly short terminals C and NC and open terminals Ll and L2, thus eliminating the function of timer E. In this posi-tion, with switch Sl continuously closed, the enablement of the refrigeration system and compressor C are under the control of temperature switch TS.
The delay timer D is provided with a clutch coil C2 which is energized when temperature switch TS is closed. When clutch C2 is energized, timer motor TM3 does not run. However, at the end of a compressor cycle, when temperature switch TS opens, clutch C2 becomes de-energized timer motor TM3 begins to run, and runs until it times out. Switch S5 remains in the position shown 1~.6913~

between terminals 4 and 5 until timer motor T~13 is timed out, thus completing a circuit from power line PLl through junction FJ, to evaporator fan motors EFM. At the beginning of any cycle of operation of the compressor C, switch S5 is normally in the position shown connecting terminals 4 and 5 of timer D, and therefore, power is supplied to evaporator fan motors EFM from power line PLl via terminals 4, 5 of timer D, and junction FJ.
Timer D determines how long power is to be applied to the evaporator fan motors following the cut~off time of the compressor determined by temperature switch TS.
That is, as temperature switch TS opens, clutch coil C2 becomes de-energized permitting timer RM3 to time out, at which time switch S5 switches from terminal 5 to terminal 3, thus interrupting the supply of power to evaporator fan motors EFM. With switch S5 coupling terminals 4 and 3 of timer D together, the cycle timer Cy is enabled.
Thus, the cycle timer Cy, timer motor TM4, runs continuously following each delay period generated by timer D, until reset by the ending of another delay period. The cycle timer alternately opens and closes the contacts between terminal 2 and 3 of timer Cy at a selectable rate to create the small pulse waveform illustrated as Cy in Figure 3. Thus, as shown in the bottom waveform "FAN(S)" of Figure 3, the evaporator fans EFM intermittently cycle ON and OFF following each delay period controlled by timer D. Thus, the evaporator fan motors EFM, as illustrated in Figure 3 are turned ON
for the entire period that the compressor is turned ON, remain ON for a delay period determined by timer D, and are intermittently turned ON following each delay period and during the period preceeding the next compressor ON
time. The compressor ON and compressor OFF times are labeled CON and COFF, respectively in Figure 3. Thus, the operation of timers E, D, and Cy have now been described with reference to Figure 3.

116913g The operation of the timer fp which prevents freeze up of vended products in sub-freezing environ-ments may now be understood with reference to Figure 4 and in conjunction with Figure 2. As illustrated by the top waveform TS in Figure 4, the temperature switch TS
is closed and opens to turn the compressor OFF at the time indicated COFF in Figure 4, at which time power is removed from clutch coil Cl of timer fp. When this occurs, timer motor TM2 is permitted to rotate to begin its timing function. If the temperature switch TS
remains open for a predetermined period, for example, four (4) continuous hours, timer fp will time out closing the contacts between terminals 3 and 4 thereof by switch S3. The closure of switch S3 completes the circuit to the evaporator fan motors EFM between power lines PLl and PL2. The evaporator fans will then run continuously until such time that the temperature switch again closes which energizes clutch coil Cl to stop the operation of the timer motor. When this occurs, timer fp is automatically reset to its initial condition in readiness for subsequent actuation in response to a compressor OFF period in excess of said predetermined period of four (4~ hours. It should be understood that the period of four (4) hours is exemplary only, and that the predetermined time period selected will vary depending on the type of vending machine being controlled.
Thus, by the continuous operation of the evaporator fan motors following a long compressor OFF period indicative of sub-freezing conditions in the environment, freeze up of products in the vending machi,ne are precluded by the heating effect of the moving air circulating throughout the vending machine.
It should be understood that the system herein-before described may be modified as would occur to one of ordinary skill in the art, without departing from the spirit and scope of the present invention.

Claims (3)

CLAIMS:

1. In a refrigeration system for a chilled product vending machine including a refrigeration compressor, temperature sensor means for detecting the temperature within said vending machine and turning said compressor ON and OFF to define a com-pressor cycle in response to the detection of predetermined temperature limits, an evaporator coil and evaporator fan means for blowing air across said evaporator coil and circulating said air throughout said vending machine, the improvement comprising:
means for cycling said evaporator fan means ON for a time period at least as long as said compressor cycle; and means for cycling said evaporator fan means OFF at a point in time after said compressor is turned OFF, said point in time being long enough after said compressor is turned OFF to permit the temperature of said evaporator coil to stabilize above the freezing temperature of water; and cycle timer means for intermittently cycling said evaporator fan means ON and OFF for predetermined periods between said compressor cycles to thereby maintain an even distribution of chilled air within said machine and minimize temperature fluctuations of the chilled products.

2. The system of claim 1, further comprising:
sensor means for detecting when said compressor is cycled OFF;

timer means responsive to said sensor means for measuring the length of time that said compressor is cycled OFF

and for generating an enabling signal when said length of time exceeds a predetermined duration; and circuit means responsive to said enabling signal for cycling said evaporator fan means ON continuously until said com-pressor cycles ON.

3. The system of claim 1, further comprising:
detector means responsive to the temperature of the environment surrounding said vending machine and generating a signal when said temperature drops below a predetermined limit;
and circuit means responsive to said signal for cycling said evaporator fan means ON to run continuously for a predetermined period of time.