RU2375651C2 - Refrigerating unit with water distributor - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: refrigerating unit (1) is equipped by a distributor (6) of cooled water supplied by a hydraulic circuit (4, 12) which is connected to the water supply system external in respect to the unit, usually to the drinking water supply system. The unit comprises a first electromagnetic valve (12) set in the hydraulic circuit, a second electromagnetic valve (63) set in the distributor and an electronic control system (13). The electronic control system (13) is designed for the actuation of the electromagnetic valves (12, 63) in order to control the water flow in the distributor and to define the quantity of the output water.

EFFECT: simple and efficient solution related to the hydraulic system of a refrigerating unit equipped by a cooled water distributor.

20 cl, 4 dwg

Description

The present invention relates to a refrigerator according to the preamble of paragraph 1.

Said refrigeration apparatus is provided with a chilled water distributor; the latter is equipped with a hydraulic circuit that is internal to the apparatus, the hydraulic circuit is connected to a water supply system that is external to the apparatus, usually such a source is a drinking water supply system.

The following description will always refer to home-use refrigerators without strictly limiting them to the present invention.

Refrigerators with such symptoms have been widespread in the United States for decades; in fact, most refrigerators in the US market are equipped with dispensers that distribute both chilled water and ice, and in some cases some chilled drinks; such valves are rather cumbersome. Such refrigerators have two doors installed side by side, and are very bulky; the distributor is attached to one of the doors and protrudes noticeably inward from the door; outside the refrigerator, there is a deep cavity in the door to place, for example, a glass into which channels go for distributing water and ice; therefore, there is no significant protrusion.

In Europe, refrigerators with an integrated distributor have been widely used only recently.

The European market requires significantly different products, that is, significantly less bulky products (60 or 70 cm wide) that ensure the distribution of only chilled water; moreover, such products should have a low cost and, therefore, should use simple but effective technical solutions.

The main objective of the present invention is to provide a simple and effective solution related to the hydraulic system of a refrigeration apparatus equipped with a chilled water distributor.

In particular, the specific objective of the present invention is to provide a simple but effective solution related to the hydraulic circuit of the refrigerator for domestic use, and mainly adapted for the European market.

The tasks are achieved by means of a refrigeration apparatus having the features described in detail in independent clause 1.

Only two solenoid valves and a simple electronic control system can easily and efficiently control and determine the flow of water throughout the hydraulic system of the refrigeration unit.

Additional embodiments of the present invention are described in detail in the dependent claims.

The present invention will become clearer from the following description and from the attached drawings, where:

figure 1 shows a schematic section of a refrigeration apparatus according to the present invention,

figure 2 shows a section of a solenoid valve located in the apparatus of figure 1,

figure 3 shows a section and views in perspective view of the electromagnetic valve of figure 2, and

figure 4 shows a diagram of the hydraulic system of the apparatus of figure 1.

Both the description and the drawings are to be considered as non-limiting examples of the invention.

Figure 1 shows a schematic sectional view of a home-use refrigerator according to the present invention, indicated generally by the reference numeral 1.

The refrigerator contains a compartment 2 located on the base 11; in the illustration, the compartment walls are very thick to show the presence of a thick layer of thermal insulation material; basically, the thickness of the insulating material depends on the type of chamber (in practice, on the operating temperatures of the chamber) and, of course, on the type of insulation used; this is a common feature widely known to those skilled in the art.

The refrigerator comprises two cooling chambers, generally indicated at 10; chamber 10A is used for fresh food and is located in the upper part of compartment 2, and chamber 10B is used for frozen food and is located in the lower part of compartment 2.

There are two doors, generally designated 3, to close the cooling chambers 10; in particular, there is an upper door 3A for the chamber 10A and a lower door 3B for the chamber 10B.

The refrigerator 1 is equipped with a chilled water distributor, shown generally at 6, which is mounted on the refrigerator door; in the illustrated embodiment, the distributor is mounted on the upper door 3A.

The chilled water dispenser of the refrigerator according to the embodiment of FIG. 1 is connected to a public water supply system. Water is supplied to the refrigerator 1 from the water supply through a pipe; this figure shows only a small part of the pipe; the water supply pipe is connected to the inlet of the first electromagnetic valve 12; the outlet of the electromagnetic valve 12 is connected to the pipe shown at 4. In the figure, the connection of the distributor 6 to the water supply is shown as a single tubular element (which is both simple and effective, and therefore preferred); other embodiments of the present invention may, however, comprise several interconnected tubular elements.

The pipe 4 exits the cavity in the lower section of compartment 2 (also containing the electromagnetic valve 12) and then passes through the rear wall of compartment 2, passes through the insulating material to the upper part of compartment 2, passes through the upper wall of compartment 2, passes through the insulating material, leaves compartment 2 and enters the door 3A; the pipe 4 then passes through the insulating material of the door 3A and reaches the distributor 6.

The aforementioned cavity is also used, for example, to house a refrigerator compressor.

The distributor 6 contains a tank 61, into which water passes through the pipe 4; the tank 61 is located in the refrigerating chamber 10A, so that the water in the tank is cooled.

The distributor 6 also includes a channel 62, passing into the tank 61 through the second electromagnetic valve 63, which is used to distribute chilled water to the consumer.

The distributor 6 also includes a chilled water filter 64.

In figure 1, the tank 61 and the filter 64 are shown as a single unit, since in this preferred embodiment they are closely connected both hydraulically and mechanically.

In this embodiment, it is necessary to use means to control the flow of water into the tank 61 and means to control the distribution of water through the channel 62; these means essentially comprise electromagnetic valves 12 and 63 and an electronic control system 13 (not shown in FIG. 1); in home refrigerators, electronic systems are often mounted on the top of the refrigerator compartment.

The electronic control system of the refrigerator in figure 1 is connected to a control panel 65 (not shown in figure 1) of the distributor 6, located on the door 3A, facing outward, directly above the recess 7; said control panel comprises a button allowing the consumer to request the distribution of chilled water, and a warning lamp indicating when the filter 64 is worn out. The upper door 3A of the refrigerator according to the embodiment of FIG. 1 has a recess 7 into which a channel 62 exits; the recess 7 is open to the outside and is used to accommodate, for example, a glass 8 (without the possibility of an effective stop), filled with water leaving the channel 62.

In the embodiment of FIG. 1, the recess is shallow and therefore does not extend into the cooling chambers; thus, the recess 7 does not reduce the volume of the cooling chambers, and the door 3A has a thinner layer of thermal insulation material even in the region of the recess 7.

Doors 3A and 3B of the refrigerator are connected to the compartment by hinges, allowing the consumer to open and close the doors by turning around the vertical axis. The hinges are not shown in FIG. 1 for simplicity; Typically, various types of hinges are used in refrigerators, which are for the most part known to those skilled in the art. In the refrigerator of FIG. 1, the following elements pass between door 3A and compartment 2: a water pipe 4, an electric cable (usually two-core) for supplying energy to the distributor 6, and another electric cable (usually multi-core) for connecting the electronic control system 13 to the control panel 65 ; these connections require suitable solutions to protect the tubular elements (pipe and cables) from damage due to repeated opening and closing of door 3A; similar designs are already known in the field of refrigerators.

In general, according to the present invention, the refrigerating apparatus is provided with a chilled water distributor supplied by a hydraulic circuit adapted to be connected to a water source outside the apparatus, and comprises a first solenoid valve located in the hydraulic circuit, a second solenoid valve located in the distributor, and an electronic control system adapted to control the water flow in the circuit and the water flow in the dispenser, as well as to determine the amount of water passing through.

With reference to FIG. 1, a hydraulic circuit essentially consists of a solenoid valve 12 and a pipe 4, while a second solenoid valve corresponds to a solenoid valve 63.

Solenoid valves especially adapted to the present invention are simple solenoid valves having an open position and a closed position; the amount of water passing through the valve can be determined by calculating the valve opening time, as long as the valve size and flow rates are known. Of course, with a large number of valves available, it will be possible to determine the amount of water passing through each of them, if necessary (for example, in the case of leaks in the circuit or in the presence of water storage devices).

The hydraulic system of the refrigerator of FIG. 1 is simple, as schematically shown in FIG. 3; therefore, using only two electromagnetic valves and a simple electronic control system, it is possible to control and determine the water flow in the whole system; and any accumulation and / or leakage of water can also be determined.

Adapted to the present invention, the electronic control system can advantageously be based on a microcontroller with several additional components. Such a system can also be advantageously integrated into the electronic control system of the entire refrigerator, since it performs only a few simple operations. Electronic control systems for refrigerators have long been well known to specialists in this field of technology.

Typically, the dispenser of an apparatus according to the present invention includes a chilled water tank; this is the easiest way to supply chilled water as soon as the consumer requests it.

Advantageously, the dispenser of the apparatus according to the present invention comprises a chilled water filter; this filter is necessary because drinking water from a water source often contains unwanted, if not harmful, particles and substances (chlorine, for example, gives the water a bad taste).

Preferably, the filter is attached directly downstream of the tank (if any) so as to filter the water immediately before it is supplied to the consumer for drinking; in this case, any living organisms that may have developed in the tank due to the long accumulation time will also be filtered out.

The dispenser according to the present invention typically has a chilled water distribution channel, indicated at 62, while a second solenoid valve, indicated at 63, is installed directly upstream of the channel; in this way, any unwanted leakage from the channel can be prevented.

The first solenoid valve, indicated at 12, is preferably located at the beginning of the hydraulic circuit; its input provides connection to a water supply source, and its output is connected to the input of the distributor, preferably through a single pipe, indicated by 4; This design reduces the risk of water leaks inside the walls of the refrigerator.

Advantageously, the distribution channel extends into a recess made not very deep and located on the door of the refrigeration unit; in this case, the recess does not reduce the volume of the cooling chambers and the door may have a thinner layer of heat-insulating material even in the region of the recess.

Typically, the refrigeration apparatus according to the present invention has a dispenser control panel located on the door of the apparatus itself; preferably, the panel is located in the region of the recess; alternatively, the control panel of the dispenser may be combined with the control panel of the refrigerator.

In its simplest form, the control panel can be a button; when the consumer presses the button, water will pass from the distribution channel; it can be so designed, for example, that the distribution will continue as long as the consumer holds the button pressed, or that a fixed amount of water will be distributed (for example, 100 cm ³ , the equivalent of a small glass) each time the button is pressed.

Solenoid valves can be of the constant flow type (of course, the flow cannot be completely constant); thus, regulation and measurement of water flow will be significantly more accurate.

Good performance is obtained even when using only one constant flow solenoid valve; in this case, the solenoid valve is preferably the first one indicated by 12 in the embodiment, since it has a greater effect on the hydraulic system as a whole.

To simplify the design, the electronic control system can be adapted to determine the amount of outgoing water based on the opening and closing times of only the first solenoid valve, which is indicated in position 12; in fact, this is sufficient if there are no leaks, and if the amount of water accumulated in the tank (if any) is known and constant.

In addition, the use of valves having a substantially constant flow makes it possible to obtain a very accurate, time-based measurement of the amount of outgoing water.

Determining the amount of water leaving is usually necessary to check the operation of the hydraulic system and the distributor of the refrigeration unit.

If there is a filter, the determination of the amount of water leaving can be advantageously also used to determine the state of the filter; it is known that the effectiveness of such water filters decreases as water passes through them; the usual type of filter, for example, has a replaceable cartridge (the cartridge is designed to filter only a certain maximum amount of water).

Downstream of the first solenoid valve, indicated by 12 in the embodiment, it is necessary to provide a substantially constant pressure and substantially independent of the pressure in the water supply system; in fact, depending on the place, the pressure in the water supply system can vary significantly (even in one place the pressure can vary throughout the day); Thus, almost the entire hydraulic system can operate at a constant pressure, thereby ensuring the same characteristics regardless of the water supply system.

In particular, it is necessary to provide a substantially constant pressure downstream of the first solenoid valve, the pressure being in the range of 1 to 2 bar, preferably about 1.5 bar, at a pressure in the water supply system between 2 and 8 bar. With a lower distribution pressure of the water supply system, the hydraulic system will still work, but with reduced performance.

Such results are achieved by appropriate selection of the first solenoid valve; a particularly preferred embodiment of this choice is given below.

According to the present invention, to simplify the design, two solenoid valves may have substantially equal flow cross sections, typically between 1.6 mm and 2.0 mm.

According to the present invention, to simplify the design, the electronic control system can activate the solenoid valves substantially simultaneously (or at most slightly delay the closing of the solenoid valve 63 with respect to the solenoid valve 12); in fact, the pressure in almost the entire hydraulic system is low, and therefore there are no specific requirements for depressurizing the accumulated pressure in the system as water passes through the distribution phase. Moreover, if both solenoid valves open and close simultaneously when the consumer presses the distribution button, the distribution always starts and ends at the exact time and without delay.

A particularly advantageous type of solenoid valve for the refrigeration apparatus according to the present invention is an electromagnetic valve equipped with a device for stabilizing the water flow regardless of upstream pressure (of course, this is just reliable, but not absolute stabilization).

An example of such a valve is shown in FIG. 2; such valves, although not very often, can already be found on the market and are produced, for example, by the Italian company R.P.E.

The electromagnetic valve of FIG. 2 consists of a drive assembly 121, a valve body 122 and a flow stabilization device 123; in the example of FIG. 2 (and since it is preferred), a flow stabilization device is located at the valve outlet.

Figure 3 shows the device 123 in detail; it consists of a flexible diaphragm 123A and a rigid body 123B; the flexible diaphragm can be shaped like a spring washer and is usually made of rubber; the rigid body can be shaped like a rigid sleeve and is usually made of plastic. The washer is installed in the sleeve in order to deform under the pressure of water passing through the valve and to provide a change in the cross section of the valve outlet flow depending on the pressure upstream, that is, in the housing 122.

To simplify the design, an electromagnetic valve similar to that described can only be used at the inlet of the hydraulic circuit of the refrigerator according to the present invention; in the illustrated embodiment, it is predominantly necessary to have an electromagnetic valve 12 of this type.

The electronic control system according to the present invention can be adapted to activate solenoid valves in order to avoid any distribution of chilled water if the filter is worn out; in this way, the consumer will always drink properly filtered water.

The electronic control system can be adapted to warn the consumer when the filter is almost worn out; the consumer will thus have time to receive, for example, a new filter or a new cartridge; this is especially important if the electronic control system locks the device when the filter becomes worn out.

The above features are particularly preferred for a refrigerating apparatus comprising a fresh food chamber located in the upper part of the apparatus compartment and having its own door, and a frozen food chamber located in the lower part of the apparatus compartment and having its own door; in this case, the chilled water distributor is installed on the door of the cell for fresh products; the considered option applies exactly to such a case.

Claims (20)

1. A refrigeration apparatus (1) provided with a distributor (6) of chilled water supplied by a hydraulic circuit (4, 12) adapted to be connected to a water supply system external to the apparatus, comprising: a first electromagnetic valve (12) located in the hydraulic circuit, and the second solenoid valve (63) located in the distributor, an electronic control system (13) adapted to activate the electromagnetic valves (12, 63) in order to control the water flow in the circuit and the water flow in the distributor, and t Also, in order to determine the amount of water passing through, characterized in that the amount of water passing through the valve is determined by said electronic control system (13) by calculating the opening time of said valve, at least one of the electromagnetic valves (12, 63) equipped with a device (123) for stabilizing the water flow, preferably located in the outlet of the electromagnetic valve. 2. The refrigeration apparatus according to claim 1, wherein the dispenser (6) comprises a chilled water tank (61). 3. The refrigeration apparatus according to claim 1 or 2, wherein the distributor (6) comprises a chilled water filter (64), preferably connected directly downstream of the tank (61). 4. The refrigeration apparatus according to claim 1, wherein the distributor (6) comprises a channel (62) for distributing chilled water, the second solenoid valve (63) located directly upstream of the distribution channel (62). 5. The refrigeration apparatus according to claim 1, in which the first solenoid valve (12) is located at the beginning of the hydraulic circuit and has an inlet for connecting to the water supply system and an outlet for connecting to the inlet of the distributor (6), preferably through a single pipe (4 ) 6. The refrigerator according to claim 4, wherein the distribution channel (62) extends into a not very deep recess (7) located on the door (3A) of the refrigerator (1). 7. The refrigeration apparatus according to claim 1 or 6, which comprises a control panel (65) for the distributor (6) located on the door (3A) of the refrigeration apparatus (1), preferably in the region of the recess (7). 8. The refrigeration apparatus according to claim 1, wherein at least one of the solenoid valves (12, 63) is of a type having a substantially constant flow. 9. The refrigerator according to claim 8, in which only the first solenoid valve (12) is of a type having a substantially constant flow. 10. The refrigeration apparatus according to claim 1, in which the electronic control system (13) is adapted to determine the amount of escaping water based on the opening and closing times of only the first electromagnetic valve (12). 11. The refrigeration apparatus according to claim 3, in which the electronic control system (13) is adapted to use the amount of escaping water in order to determine the state of the filter (64). 12. The refrigeration apparatus according to claim 1, wherein an essentially constant pressure substantially independent of the pressure of the water supply system is present downstream of the first solenoid valve (12). 13. The refrigeration apparatus according to claim 12, wherein an essentially constant pressure is present downstream of the first solenoid valve (12), in the range between 1 and 2 bar, preferably about 1.5 bar, at a pressure in the water supply system between 2 and 8 bar. 14. The refrigeration apparatus according to claim 1, wherein the two solenoid valves (12, 63) have substantially equal flow cross sections, typically between 1.6 mm and 2.0 mm. 15. The refrigeration apparatus according to claim 1, wherein the electronic control system (13) is adapted to activate the electromagnetic valves (12, 63) substantially simultaneously. 16. The refrigeration apparatus according to claim 1, in which one or both of the electromagnetic valves (12, 63) are of the electromagnetic type. 17. The refrigeration apparatus according to claim 1, in which only the first solenoid valve (12) is equipped with a device (123) for stabilizing the water flow, preferably located in the outlet of the electromagnetic valve. 18. The refrigeration apparatus according to claim 3, in which the electronic control system (13) is adapted to activate the electromagnetic valves (12, 63) in order to avoid any distribution of chilled water if the filter (64) is worn out. 19. The refrigeration apparatus according to claim 3, in which the electronic control system (13) is adapted to alert the consumer when the filter (64) is almost worn out. 20. The refrigerator according to claim 1, including:
a fresh food chamber (10A) located in the upper part of the compartment (2) of the apparatus (1) and having its own door (3A), and
a chamber for frozen products (10V), located in the lower part of the compartment (2) of the apparatus (1), and having its own door (3B);
moreover, the chilled water distributor (6) is mounted on the door (3A) of the fresh food cell (10A).

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