IT9045728A1 - VENTILATED REFRIGERANT APPLIANCE WITH AIR FLOW DETECTOR - Google Patents

Description

Description of the industrial invention entitled: "VENTILATED REFRIGERATING EQUIPMENT WITH AIR FLOW DETECTOR DEVICE"

The present invention relates to a ventilated refrigerating appliance, of the so-called No-Frost type, comprising a device suitable for detecting the flow of air circulating inside the appliance itself. As is known, No-Frost refrigerating appliances substantially comprise an evaporator arranged in a channel along which a fan circulates a flow of air which is in a heat exchange ratio with the evaporator itself and which is used for cool at least one compartment of the appliance.

Such an evaporator is described for example in EP-A-0 313 074 and is normally associated with control means, as described for example in EP-A-0 250 909, which determine its cyclic defrosting to prevent the frost accumulated on the evaporator substantially obstructs the passage section of the air flow.

However, it is preferable that the defrost control device determines the defrosting of the evaporator only when this is actually covered by a substantial layer of frost.

For this purpose, it is known for example from IT-A-870 033 to use an air flow detector to control the formation of frost on the evaporator based on a pressure differential of the air forced by the fan through the evaporator. same. In particular, the control device responds to the resistance variations of a voltage divider comprising two thermistors which are normally heated and whose heat is dissipated by respective air flows, one of which is directly taken upstream of the evaporator, while the other flow is taken downstream of the evaporator by means of a shaped conveying pipe. When the evaporator is covered by a substantial layer of frost, the air pressure downstream of the evaporator itself decreases correspondingly and the thermistors are cooled in a different way; the consequent difference in resistance of the two thermistors is detected by a suitable electronic circuit which determines the start of a defrosting phase of the evaporator when the aforesaid difference, which is normally zero, exceeds a predetermined value.

This solution is imprecise in operation and constructively complex, since the detector device requires a certain number of critical components and is capable of detecting only localized air flows. Furthermore, the shaped conveying tube causes problems of overall dimensions and assembly of the entire control device in correspondence with the ventilated evaporator. The main object of the present invention is to provide a ventilated refrigerating appliance with an air flow detector device which is particularly simple, reliable and easy to assemble. Another object of the present invention is to provide a refrigerating appliance with an air flow detector device of the aforementioned type which is particularly versatile to be used in different operating conditions.

According to the invention, these objects are achieved in a refrigerating appliance with an air flow detecting device incorporating the characteristics of the attached claims.

The characteristics and advantages of the invention will be clarified by the following description, having only a non-limiting example, with reference to the accompanying drawings, in which:

- <■> fig. 1 schematically shows a No-Frost refrigerating appliance with an air flow detector device according to the invention;

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- fig. 2 shows a preferred embodiment of the air flow detector device with which the apparatus of fig. 1:

- figs. 3 and 4 show respective characteristic curves of the detector device according to the invention;

- fig. 5 schematically shows a perspective view of an enlarged detail of the refrigerating appliance of fig.1.

With reference to fig. 1, the refrigerating appliance according to the invention is of the so-called No-Frost type and mainly comprises at least one refrigerated compartment 23 communicating through respective inlet and outlet openings 21, 22 with a channel 20. An evaporator 19 is housed in the channel 20 of a traditional refrigeration circuit (not shown), as well as a motorized fan 24, or the like, designed to circulate a closed-circuit air flow 25 from the compartment 23 through the opening 21, through the evaporator 19 and back into the compartment 23 through opening 22.

The refrigerating appliance is also provided with an air flow detecting device 25. According to the invention, this detecting device mainly comprises, as shown in fig. 2. an air flow sensor 5 consisting of a single thermistor 6, preferably of the PTC type, associated with a single heating element 7. The thermistor 6 and the heating element 7 are arranged adjacent, in a heat exchange relationship with each other , and are preferably embedded in a thermally conductive resin.

According to an aspect of the invention, the heating element 7 is constituted by a transistor, preferably of the so-called SMD (Surface Mounting Device) type. having minimum overall dimensions in such a way that the device 5 has reduced thermal inertia, i.e. short response times.

The thermistor 6 constitutes a branch of an electrical bridge circuit having an output diagonal 8, 9 and a diagonal to which a direct supply voltage V is applied between a terminal 10 and the ground. In particular, the branches of the bridge connected between the terminal 10 and the terminals 8,9 comprise respective resistors 11, 12 of identical value, while the branches of the bridge connected between the ground and the terminals 8, 9 comprise respectively the thermistor 6 and a further one, analogous thermistor 14. Normally the bridge is substantially balanced, but preferably a fixed imbalance resistor 13 is connected in series to the thermistor 14.

The terminals 8, 9 of the output diagonal are preferably connected to respective inputs of an amplifier 15, for example comprising an integrated circuit of the type LM 353. The output 16 of the amplifier 15 drives the base of the transistor 7, the collector of which is it is connected to ground and whose emitter is driven by a constant current generator 17. Furthermore, the emitter of the transistor 7 drives with a direct output voltage Vout a user device 18, adapted for example to control the start of a timed defrosting phase of the evaporator 19 of the refrigerating appliance, in a manner known per se. , when the voltage Vout falls below a predetermined value.

For example, the user 18 can be made as described in the aforementioned IT-A-870 033.

The sensor 5 is immersed in the air flow 25 to be detected, preferably downstream of the evaporator 19, and its positioning in any point of the refrigerating appliance is facilitated by the compactness of the sensor 5 itself, consisting of a single component of reduced dimensions, which does not present any assembly problems.

As is known, the flow of air 25 which passes through the evaporator 19 is smaller the greater the increase of frost on the surface of the evaporator itself; therefore, considering that the frost tends to form on the surface of the evaporator 19 in a substantially uniform manner, it tends to reduce the degree of cooling of the sensor 5 (in particular of the thermistor 6) by the air flow 25.

In operation, the transistor 7 is normally driven with a constant current I produced by the generator 17 and dissipates a thermal power P inside the sensor 5 which is directly proportional to the aforesaid current I and to the collector-emitter voltage of the transistor itself. This power P heats the thermistor 6, which is simultaneously cooled by the air flow 25. The resistive value of the thermistor 6 would therefore tend to reach an equilibrium value which influences the balancing of the bridge 6, 11 - 14.

In particular, the thermistor 6, cooled by the air flow 25, would tend to unbalance the bridge circuit if it were not suitably heated by the transistor 7. In the absence of the imbalance resistor 13 and with a predetermined value of the current supplied by the generator 17, the bridge could actually be brought into equilibrium conditions. In reality, the presence of the resistance 13 allows to always have a certain imbalance of the bridge, even in the absence of the air flow 25, corresponding to a minimum output voltage Vout which among other things allows the transistor 7 to never be cut off. .

However, the entire detector device can be easily dimensioned in such a way that in the presence of air flow 25 the compensation of the consequent cooling of the thermistor S, operated by the heating transistor 7, is only partial, so as to obtain some increasing monotonous characteristic curves, as will be clarified later with reference to figs. 3 and 4.

Under normal operating conditions, the bridge is therefore slightly unbalanced, as already mentioned, as a function of the value of the resistance 13. In these conditions, the output 8, 9 of the bridge drives the inputs of the amplifier 15 with a voltage in response to which the The output 16 in turn drives the transistor 7 to produce an output voltage Vout higher than a predetermined value. Therefore, the user 18 remains inoperative.

When a substantial quantity of frost accumulates on the surface of the evaporator 19, such as to significantly reduce the air flow 25 which passes through the evaporator itself and strikes the sensor 5, the thermistor 6 is cooled to a lesser extent. Therefore, the resistive value of the thermistor 6 increases correspondingly, so that the voltage at the output 8, 9 of the bridge driving the inputs of the amplifier 15 decreases. This results in a decrease in the emitter-base voltage of the transistor 7 and therefore in a decrease in the output voltage Vout which drives the user 18.

When the voltage Vout falls below the predetermined value, the user 18 intervenes in a manner known per se to start a defrosting phase of the evaporator 19; at the end of the defrost the operation of the device continues as described above.

Obviously, the ventilated refrigerating appliance according to the invention can be variously set up for different uses, in which the temperature values and the general operating conditions can also be considerably different, according to the cases.

Therefore, for a precise and correct operation of the flow detector device it is important that it has a characteristic curve, representing † iva of the voltage Vout as a function of the value F of the air flow 25, which can be adjusted according to the type of application.

With reference to fig. 3, this can be obtained, according to an aspect of the invention, simply by varying the value of the fixed resistance 13, thereby varying the initial unbalance of the bridge 6, 11-14 and therefore the offset of the characteristic curve. which is substantially monotonous increasing. as said previously. In particular, according to the value of the unbalancing resistance 13 (and with the same current supplied by the generator 17) the characteristic curve of the flow detector device can be that shown in fig. 3 with C1, C2, C3, scc. Consequently, the range of operating values of the voltage Vout can be varied as required.

Moreover, thanks to the use of the transistor 7 as an element suitable for heating <1> and the thermistor 6, it is possible to simply adjust the current I supplied by the generator 17 and absorbed by the transistor itself to control the power P which it exchanges with the thermistor. 6. Consequently, it is also possible to adjust the slope of the characteristic curve, and therefore the range of the detectable flow values, which with reference to fig. 4 can be, depending on the current value I, that represented with C1, C10, C100, etc.

It therefore appears evident that the refrigerating appliance according to the invention is provided with an air flow detector device which, in addition to being particularly simple, precise and reliable, is also extremely versatile, as it can be easily and effectively adjusted according to the needs.

It should also be noted that only the sensor 5 must be positioned so as to be hit by the controlled air flow 25, while it is sufficient for the thermistor 14 to be shielded with respect to the flow itself but arranged in an adjacent position to effect a temperature compensation. in a way known in itself. On the other hand, all the other components of the air flow detector device can be arranged in any easily accessible position, even outside the refrigerating apparatus, and can therefore be easily accessible for carrying out the adjustments described above. As regards in particular the detector device 5 and the thermistor 14, they are preferably mounted in position, as shown in Figs. 1 and 5, in correspondence with the opening 21 which puts the compartment 23 in communication with the channel 20. The thermistor 14 is supported adjacent and substantially aligned with the sensor 5 and is also protected from the air flow 25 by means of a shaped screen 26, or similar.

Obviously, the ventilated refrigerating apparatus described can undergo numerous modifications falling within the scope of the invention. For example, it may comprise one or more storage compartments and / or one or more freezer compartments.

Claims (4)

CLAIMS 1. Ventilated refrigerating appliance with device for detecting the air flow circulating in at least one compartment of the apparatus, said detector device comprising a sensor normally heated by heating means and able to be cooled by said air flow, the sensor being connected in an electric control circuit adapted to produce an output signal, dependent on the degree of cooling of the sensor, which drives a user device, characterized in that said sensor (5) is immersed in said air flow (25) and consists in a thermistor (6) in a transistor (7) in a heat exchange ratio between Toro, the transistor (7) constituting said heating means and being driven with a substantially constant current (I). 2. Ventilated refrigerating appliance according to claim 1, characterized in that said transistor (7) is of the so-called SMD type and is embedded in a body of thermally conductive resin together with said thermistor (6). 3. Ventilated refrigerating appliance according to claim 1, characterized in that said electric control circuit comprises a resistive bridge circuit, two branches of which comprise respectively said thermistor (6) and a further one. a similar thermistor (14) disposed in the refrigerating appliance adjacent to said sensor (5) and associated with shielding means (26) adapted to protect it from said air flow (25). 4. Ventilated refrigerating appliance according to claim 3, characterized in that an unbalancing resistor (13) of said bridge is connected in series to said further thermistor (14).