JPS62237264A - Ice vessel level sensor - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention This invention relates to electrical circuits, and more particularly to circuits that function to detect the amount of ice accumulated in an ice container of a refrigeration system with automatic ice-making capabilities.

BACKGROUND OF THE INVENTION Many modern refrigeration systems used in industrial and residential applications include automatic ice making systems that store ice cubes in ice containers. A device for controlling the output of ice making machines of this type is required to enable replenishment of the ice being used and to prevent the machine from overproducing.

Many current designs for this type of controller use devices to weigh the ice container or paddle-shaped sensors to detect the height of the ice cube accumulation stack. Although these devices generally operate satisfactorily, it would be desirable to provide an improved ice container level sensor that controls ice making machines and operates without moving parts.

According to the invention, an ice container sensor circuit is provided which allows the amount of ice in an ice container to be detected using a beam of infrared light that is interrupted when the ice container is fully filled. This circuit automatically controls the ice maker to maintain the desired amount of ice cubes available. Although optical isolator circuits are well known, the circuit according to the present invention is well designed for its intended function and uses readily available and inexpensive components. To prevent improper operation due to transient interruption of the light beam: 1. The second circuit has a time delay function. The circuit further includes a device for preventing improper operation caused by ambient light, and a mechanism for rapid testing of the circuit during production or malfunction diagnosis in the field.

Additional benefits and advantages of this invention will be apparent to those skilled in the art to which this invention pertains from the following detailed description of the preferred embodiments taken in conjunction with the accompanying drawings and the claims. It will become clear from the description.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring specifically to FIG. 1, a refrigeration system with an automatic ice-making device having an outlet 14 is shown.

In order for the refrigeration system 10 to operate automatically, some type of device is provided to control the output of the ice making system so that the ice is ready when desired and the ice container 16 is not overfilled. It is necessary.

According to the invention, such control is provided by infrared (IR) transmitters 18 mounted on opposing walls within the ice container 16.
and an infrared sensitive photodetector 20, when the ice cube accumulation is below the line of sight between the transmitter 18 and the photodetector 20, the ice making device is activated and the ice cubes are Made. This action continues until the infrared light beam is interrupted, at which point the ice making function is stopped. Transmitter 18 and photodetector 20 are controlled by ice container sensor circuit 22. The components that make up the ice container sensor circuit 22 are described in detail below.

FIG. 2 shows the functional subdivisions of the circuit 220, and FIG. 3 is a detailed circuit diagram of the circuit showing each of the individual components. The ice container sensor circuit 22 consists of three major circuits: a power supply 24, an IR transmitter drive circuit 26, and a detector circuit 28, each of which is preferably mounted on a single PC board (printed wiring board). 34
is attached to.

As shown in FIG. 3, the power supply 24 is a step-down power transformer 30.
, which is mounted on the PC board 34 and connected to several bins on the square terminal strip 12. Power from the step-down transformer 30 is directed to a full-wave bridge rectifier 36;
Here it is converted into a DC voltage with an average value slightly greater than 12 volts. Filter capacitors 37 and 38
is used to reduce the rectified signal ripple. Additional filtering and voltage control is provided by the use of an IC (integrated circuit)@pressure regulator 40.

Diode 41 is provided to inhibit load spikes that may be generated by circuits connected to power supply 24.

IR drive circuit 26 uses the well known R555J timer 42, which, along with additional components, is used in circuit 26 as an oscillator to operate drive transistor 54. Timer 42 functions by monitoring the charge level of external timing capacitor 46. The output of timer 42 is high when capacitor 46 is being charged by the current flowing through resistor 48. diode 5
0 is provided so that charging of capacitor 46 occurs only by bias resistor 52 through resistor 48 .

When capacitor 46 reaches approximately two-sixths of the supply voltage,
The output of timer 42 goes low and the timer switches to capacitor discharge mode. The discharge of the capacitor 46 is performed by the resistor 52.
It is done through.

Because of the use of diode 50, capacitor 46 is charged very quickly and discharged much more slowly. This operation of timer 42 produces a square pulse shaped output with a very low percentage duty factor. That is, narrow positive voltage spikes are separated by relatively long pause periods.

The output of timer 42 passes through resistor 56 to control the base current of drive transistor 540. Drive transistor 54
The square pulse shaped output driving the 0 base cuts the 12 volt signal from power supply 24.

A current is passed through an IR transmitter 18, which is preferably a light emitting diode (LED) and is connected to several bins of the terminal strip 12. The LED 58 is also provided as an auxiliary IR transmitter. However, this is mounted on a PC board 34 and may be used for future applications, but is not used in connection with this invention.

Detector circuit 28 is a National Semiconductor circuit with four individual operational amplifiers (op amps).
nal Sem1 conductor) model LM6
It consists of a large number of integrated operational amplifiers (multipurpose analog amplifiers) such as 24. Photodetector 21 provides a variable resistance value within its sensing range that is dependent on its exposure. The auxiliary photodetector 20 is reserved for future use. The photodetector 21 provides a variable mainstream signal,
This signal is applied to the inverting (minus) terminal of opf 1600, which functions as current-to-voltage converter 62. Resistors 64 and 66 are connected to the non-inverting (glass) terminal of the operational amplifier 60.
A constant voltage bias source of about 8 volts is provided, set by the voltage divider given by . IR transmitter 1
Due to the fluctuations in the current through photodetector 21 caused by exposure to pulsating light from 8, operational amplifier 60 will provide a positive-only alternating voltage output signal. Feedback resistor 70 provides gain control for operational amplifier 60. Capacitor 68 acts as an ambient light level blocker 72 by removing the DC component from the output of operational amplifier 60, such as may occur due to constant or low frequency ambient light input to photodetector 21. do. Capacitor 71 and resistor 80 are provided for additional signal conditioning.

The operational amplifier 74 is an amplifier 7 of the signal from the capacitor 68.
6 and a feedback resistor 78 is used to boost this signal to the desired level. Resistors 78 and 82 adjust the input level to operational amplifier 74 to the desired magnitude. Opamps 84 and 86 are configured to provide a peak detector circuit 88 by using diodes 90 and 92, capacitor 94, and resistors 91, 93 and 95. The output of peak detector circuit 88 is a DC level with some sawtooth ripple inserted into it due to the charging of capacitor 94.

The output of peak detector circuit 88 from operational amplifier 86 is positive when the alternating signal is received by photodetector 2. When this condition occurs, voltage is supplied to the LED 96 through the resistor 97 attached to the PC board 34,
This provides an indication that ice container J6 is not full.

Opamp 96 is used as a threshold detector 98 by comparing the signal provided by opamp 86 to a reference voltage provided by a voltage divider defined by resistors 102 and 104. operational amplifier 96
provides a positive output when the difference between the signal provided by operational amplifier 86 and the reference signal is positive. Time delay circuit 10
6 is a resistor 108, a capacitor]]0 and an operational amplifier 11
The values of resistor 108 and capacitor 110 are chosen such that the signal applied to the negative terminal of operational amplifier 112 changes slowly.

When the output of the operational amplifier 96 becomes positive, the time delay circuit 10
6, the input signal to the operational amplifier 112 remains below the reference voltage for a predetermined period of time, for example about 10 seconds. Similarly, when the output of operational amplifier 96 becomes negative, operational amplifier 11
The input signal to 2 remains above the reference voltage for a predetermined period of time. When the signal applied to the negative terminal of operational amplifier 96 exceeds the reference voltage, a negative output is provided by operational amplifier 112. A resistor 113 is provided for controlling the gain of the operational amplifiers 1 and 2. A terminal 99 is provided which is connected to the negative input of the operational amplifier 96 and allows a test signal to be applied to check the operation of the circuit 22.

The signal from the output of the operational amplifier 112 is transmitted to a pair of operational amplifiers 1]4 and 116 that constitute the driver/inverter 118.
sent to. The signal from op amp 112 is split and applied to both page inputs of op amps 114 and 116, which compare this signal to a reference signal applied to resistor 104. Opamps 114 and 116 are resistors 12
2 and 124 to drive the relay drive transistor 20. Transistor 120 controls the current flowing to relay 126 that operates the ice making apparatus used with this invention. A diode 128, a capacitor 130, and a resistor [12] are provided to attenuate electrical noise generated by the operation of the high inductance relay [26].

The ice container sensor circuit 22, as previously described, continuously monitors the level of stored ice and periodically activates and deactivates the ice making device to maintain the desired ice supply level. Automatically operate the ice making device by When the light from the IR transmitter 18 hits the open light detector 21 for a time that exceeds the delay time, the ice making device is operated and ice is made. Ice container 1 for time delay function
Inadvertent operation of the ice making device in response to transient exposure of the photodetector 21 to light that may occur when ice is being removed from the ice maker 6 is prevented. When the ice container is full, the light from the IR transmitter ]8 is cut off. If the interruption of the light beam exists for a time that exceeds the delay time, the ice making device is deactivated. A time delay in shutting down the ice making system is desirable to avoid responding to transient conditions, and to allow a small amount of excess light in the ice container to reduce the cycling process of the system.

While the foregoing description constitutes preferred embodiments of the invention, it will be appreciated that the invention is susceptible to modifications, variations and changes without departing from the true scope and fair meaning of the claims.

[Brief explanation of drawings]

FIG. 1 is a pictorial diagram showing a typical automatic ice making device. FIG. 2 is a block diagram of various functional subparts of a circuit according to the invention. FIG. 3 is a detailed circuit diagram of a circuit according to the invention. In these drawings, 10 is a refrigeration device, 16 is an ice container, 18 is an optical transmitter, 20 is a photodetector, 22 is an ice container sensor circuit, 24 is a power supply, 26 is a transmitter drive circuit, and 28 is a detector circuit. , 40 is a voltage regulator, 42 is a timer, 54 is a drive transistor, 60 is an operational amplifier (current-voltage converter 62), 74 is an operational amplifier (amplifier 76), 84.86
is an operational amplifier (peak detector circuit 88), 96 is an operational amplifier (threshold detector 98), 112 is an operational amplifier (for time delay circuit 1OFt), 114.116 is an operational amplifier (driver/inverter), 120 is a relay drive transistor , 12 (i indicates a relay. (5 other people)

Claims (19)

[Claims] (1) Applicable to a refrigeration device equipped with an ice making device and an ice container for receiving ice made thereby, wherein the ice accumulated in the ice container is below a predetermined level. an electrical circuit for controlling said ice making device to cause said ice making device to make ice at a time, said light source, a light sensitive element spaced from said light source, said light source comprising: above a predetermined level, the light path between the light source and the light sensitive element is interrupted so that the light sensitive element generates a current proportional to the level of light received by it; a current-to-voltage converter device for receiving a current signal from the photo-sensing device and converting it into a voltage signal; a peak detector device for detecting peaks, a threshold detector device for passing the signal from said peak detector only if this signal exceeds a predetermined threshold; and said threshold. a time delay device that provides an output for controlling said ice-making device only after a signal from a detector device has been present for at least a first predetermined duration; said time delay device operates said ice making device when said signal from said threshold detector is present for a second predetermined duration. said time delay device maintains said output until said ice is above said predetermined level for said second predetermined duration; said time delay device said electric circuit comprising: said time delay device adapted to stop operation of said electric circuit. (2) an oscillator for driving light from said light source to produce a pulsed light output; and said current-
2. The electrical circuit of claim 1, further comprising a direct current blocking device receiving said voltage signal from a voltage converter device and passing only an alternating voltage, thereby functioning as an ambient light level blocker. 3. The electrical circuit of claim 1, wherein the light source generates light at an infrared frequency. 4. The electrical circuit of claim 1, wherein the current-to-voltage converter device comprises a first operational amplifier. (5) The electrical circuit according to claim 2, wherein said DC blocking device comprises a capacitor. 6. The electrical circuit of claim 2, further comprising an amplifier that amplifies the signal from the DC blocking device and provides an amplified signal to the peak detector device. (7) Claim 6, wherein the amplifier is a second operational amplifier.
The electrical circuit described in . (8) Visible light emission energized by a signal from said peak detector device, thereby providing an indication that said light sensitive element is receiving a signal from said light source. The electrical circuit of claim 1, further comprising a device. 9. The electrical circuit of claim 1, wherein said time delay device comprises a resistor-capacitor network. (10) The electric circuit according to claim 1, further comprising a driver/inverter that receives a signal from the time delay device and drives a drive transistor that controls the ice making device. 11. The electrical circuit of claim 10, wherein the drive transistor provides a signal to a relay that controls the ice making device. 12. The electrical circuit of claim 1, wherein the peak detector includes third and fourth operational amplifiers. 13. The electrical circuit of claim 1, wherein the threshold detector includes a fifth operational amplifier. (14) The electrical circuit of claim 9, wherein the time delay device includes a sixth operational amplifier. (15) The electric circuit according to claim 10, wherein the driver/inverter includes seventh and eighth operational amplifiers. 16. The electrical circuit of claim 1, wherein the first and second predetermined durations are substantially equal. (17) Applicable to a refrigeration device equipped with an ice making device and an ice container for receiving ice made thereby, wherein the ice accumulated in the ice container is below a predetermined level. an electrical circuit for controlling said ice-making device to cause it to make ice at a given time, comprising: a light emitting diode light source generating light at an infrared frequency; a first drive transistor; an oscillator for driving the first drive transistor to control the first drive transistor to generate a pulsed light output; a photodetector spaced from the light source; a light path between said light source and said photodetector is interrupted when said ice is above said predetermined level, said photodetector being proportional to the level of light received by said photodetector; the photodetector adapted to generate a current; a first operational amplifier operating as a current-to-voltage converter for receiving a current signal from the photodetector and converting the signal into a voltage signal; a capacitor coupled to the output of the first operational amplifier of the second operational amplifier to pass only the alternating voltage signal component and act as an ambient light level blocker; a second operational amplifier for amplifying the signal from the second operational amplifier; third and fourth operational amplifiers coupled to a pair of diodes to act as peak detectors for detecting peaks in the signal from the operational amplifier; a fifth operational amplifier, a resistor-capacitor network, and a sixth operational amplifier, acting as a threshold detector to pass the signal from the fourth operational amplifier only if it exceeds a predetermined threshold; and providing an output after the signal from the fifth operational amplifier has been present for at least a first predetermined duration, and the signal from the fifth operational amplifier has at least a second predetermined duration. a time delay device which continues to provide said output until cut off for a duration; a driver comprising a sixth operational amplifier receiving a signal from said sixth operational amplifier; controlled by said seventh operational amplifier; a relay drive transistor; and a relay coupled to the relay drive transistor, wherein the relay drive transistor is configured to cause the relay drive transistor to operate when the ice is below the predetermined level for the first predetermined duration. The relay drive transistor operates the relay and the ice making device to produce ice and when the ice is above the predetermined level for the second predetermined duration. said electrical circuit comprising said relay adapted to stop operation of said ice making device. (18) According to claim 17, further comprising an eighth operational amplifier connected in parallel with the seventh operational amplifier and operating together with the seventh operational amplifier to control the second drive transistor. electric circuit. (19) The electrical circuit of claim 17, wherein the first and second predetermined durations are substantially equal.