RU169552U1 - Refrigeration unit - Google Patents

Abstract

The utility model relates to stand-alone refrigeration units (monoblocks) intended for connection to a refrigerating chamber. Monoblock refrigerators are ready-to-use freezing units designed for cooling and further maintaining the required temperature of the internal volume of the refrigerating chamber. A refrigeration unit, characterized in that it contains a housing with an aggregate compartment and an evaporator chamber mounted underneath it, separated from the aggregate compartment by a thermally insulated horizontal wall, a condenser, a condenser fan and a compressor are installed in series in the aggregate compartment, an evaporator and an evaporator fan are installed in the evaporator chamber wherein the compressor, condenser, evaporator are interconnected by a pipeline with refrigerant, the aggregate compartment contains a channel for intake ear from the environment and air outlet channel, and in the lower part of the evaporator chamber formed discharge passage for discharging cold air from the evaporator chamber into the cooling chamber and an inlet passage for supplying hot air from the refrigeration compartment to the evaporator chamber. 10 s.p. f-ly, 7 ill.

Description

The utility model relates to stand-alone refrigeration units (monoblocks) intended for connection to a refrigerating chamber. Monoblock refrigerators are ready-to-use freezing units designed for cooling and further maintaining the required temperature of the internal volume of the refrigerating chamber.

The prior art refrigeration apparatus comprising a cooled internal cavity and a refrigeration circuit for circulating refrigerant. The refrigeration circuit comprises an evaporator, a compressor and a condenser with a blower for cooling the condenser and / or compressor and with a controller. To prevent heating of refrigerated or frozen products during the defrosting process, the evaporator in devices with an automatic defrosting system is usually located in a chamber isolated from the cooled internal cavity. During the normal cooling phase, air exchange between the internal cavity and the evaporator chamber is carried out by an air recirculation system. This camera is usually located on the back wall of the refrigerator, one of its sides slopes obliquely down. Moisture that settles out of the air automatically thaws out, or if necessary, and the liquid that forms flows down at the same place in the chamber, from where it enters the collection tray located in the engine compartment through the back wall. In the tray, the liquid evaporates due to the heat of the compressor. The cooled internal cavity is surrounded by an insulating material. The insulating material is surrounded by an outer shell, which contains a cover, a bottom and two side walls. The upper part of the internal cavity is divided by a partition above which the evaporator chamber is located. In the chamber of the evaporator is an evaporator, a heating device and a fan. In addition, an inlet and an outlet are provided in the partition. At the bottom of the refrigerator is a rectangular engine compartment. The engine compartment on the sides and top is limited by insulating material, and from below - by a partition. The partition runs parallel to the bottom and at a slight distance from it and is equipped with holes through which air can circulate. The partition, together with the intermediate jumper and the bottom, forms the supply duct and exhaust duct. A capacitor, a blower and a compressor are fixedly mounted on the partition (RU 2472082, 01/10/2013).

Known household refrigerator containing a thermally insulated cabinet with refrigeration and freezer compartments and a refrigeration unit. The refrigeration unit is designed as a monoblock installed under the cabinet and includes a compressor, a condenser, an evaporator and a fan in communication with the air channels along the rear wall of the cabinet, with refrigeration and freezer compartments. The evaporator and fan are housed in a thermally insulated casing connected to the cabinet through a sealing element. Sections are installed with the formation of an air cavity under them. The evaporator is located under the air ducts of the cabinet. The compressor is located in front of the monoblock, the evaporator and fan are on its back, and the condenser is horizontally in the lower part of the monoblock under the compressor and the heat-insulated casing. The fan supplies air to the compartments through the air channels through the windows, from the cooled compartments the air enters the evaporator section through the air channels through the windows. Passing from top to bottom through the section, air enters the cavity, then passes from bottom to top into the section, the air cooled in the evaporator is again supplied by the fan to the compartments. In the process, the evaporator is covered with a “snow coat”. Removing the "snow coat" is carried out automatically by hot refrigerant vapor (SU 1684574, 10/15/1991).

The disadvantage of such structures is that the refrigeration system is integrated directly into the body (cabinet) of the refrigeration unit, and therefore its maintenance and repair are carried out directly inside the refrigerator, which is time-consuming because it causes inconvenience due to the limited space of the room where the refrigerator is installed inaccessibility to individual nodes fixed in the housing. In addition, in case of damage to the case, you have to dispose of the entire refrigerator with the refrigeration system.

The closest analogue to the claimed utility model is a cooling cassette for a refrigerated display case containing a cabinet with an internal refrigerated space for placing products. The cassette contains a box-shaped case, the inner space of which has a first section connected by an air flow to the cooled interior of the cabinet, and a second section isolated from the first section and connected by a fluid flow to the surrounding space outside the cabinet, the evaporator assembly located in the first sections, a condenser assembly located in said second section, a compressor connected by a refrigerant stream to said evaporator assembly and said condenser assembly for circulating and refrigerant through said evaporator assembly and said condenser assembly, a dividing panel dividing the interior of the inside of said housing into said first and second sections, a condensate collecting pan merging from said evaporator assembly located in the outlet channel generally below said evaporator assembly, wherein said dividing panel has a front part and a rear part, and the front part is located passing obliquely downward from the upper front region of the inner spaces to the rear and forms a converging channel and the rear portion is passing under said first section with clearance above said base panel and forms a discharge channel. The condensate evaporator is connected to the condensate tray with a drain, the aggregate compartment contains a condenser connected to the condenser fan and a compressor installed between them, and the evaporator chamber contains an evaporator connected to the fan, and the evaporator chamber communicates with the chamber of the refrigeration apparatus through an air channel from which warm air enters, and an exhaust channel through which cold air enters the shelves with products (RU 2007138619, 04/27/2009).

In the device known from the closest analogue, the aggregate section and the evaporator section are separated by a partially inclined partition, which complicates the distribution of air flows in it. In particular, in the aggregate compartment it is difficult to blow off the condenser and compressor, and in the evaporator compartment the air flow follows a channel having several bends and contractions, which complicates the “cold removal” from the evaporator and requires the installation of a more powerful fan. For the operation of this design, heat exchangers (evaporator and condenser) with an increased heat exchange area are required, which leads to increased energy consumption during its operation.

In addition, the cooling cartridge, known from the closest analogue, is designed to be installed in the lower part of the refrigeration unit, as a result of which the monoblock requires efficient use of an evaporator and an evaporator fan with more power for the unit to operate efficiently, which also ensures high energy consumption during operation.

The technical problem of the claimed utility model is the creation of a more advanced and efficient monoblock design for installation in the upper part of the cooled case (cabinet, showcase, etc.).

The technical result of the claimed utility model is to reduce energy consumption, which is achieved by reducing the loss of power of air flows and increasing the efficiency of heat transfer processes in the refrigeration unit.

The technical result is achieved by performing a refrigeration unit comprising a housing with an aggregate compartment and an evaporator chamber mounted beneath it, separated from the aggregate compartment by a thermally insulated horizontal wall, a condenser, a condenser fan and a compressor are installed in series in the aggregate compartment, an evaporator and an evaporator fan are installed in the evaporator chamber, the compressor, condenser, evaporator are interconnected by a pipeline with a refrigerant, the aggregate compartment contains a channel for environmental air intake and an air exhaust channel, and in the lower part of the evaporator chamber, an exhaust channel is made for exhausting cold air from the evaporator chamber to the refrigerating chamber and an inlet channel for supplying warm air from the refrigerating chamber to the evaporator chamber

The proposed design of the refrigeration unit is placed in a single housing (i.e. mounted in a single unit) and consists of a compressor, condenser, and evaporator interconnected pipeline. Thus, all components of the refrigeration system are functionally interconnected and cannot be used separately from each other.

Due to the fact that the refrigeration unit contains a housing in which the aggregate compartment and the evaporator chamber are arranged horizontally one above the other, separated by a horizontal wall, the air flow power losses are minimized. With horizontal division of compartments, the aggregate section has more free space. This embodiment of the refrigeration unit eliminates turbulence and loss of air flow power. Thus, the horizontal separation of the “hot” and “cold” compartments makes it possible to maximize the use of air flow power when blowing the condenser, thereby increasing the efficiency of heat exchange processes in the refrigeration system and, therefore, the overall refrigeration system’s efficiency while ensuring the overall dimensions of the unit, which reduces energy consumption and increases the performance of the refrigeration unit.

Due to the implementation of the exhaust channel for the removal of cold air into the chamber of the refrigeration apparatus and the inlet channel for supplying warm air to the chamber of the evaporator, communicating with the chamber of the evaporator directly in the lower part of the refrigeration unit, it is possible to install it on the upper part of the refrigerating chamber. This embodiment of the refrigeration unit leads to the fact that during its operation heavier cold air goes down, as a result of which much less energy is required for air circulation in the refrigerating chamber. Therefore, with this embodiment, a reduction in energy consumption and an increase in the performance of the refrigeration unit are achieved.

In the particular case, the air intake channel can be made in front of the aggregate compartment, next to the condenser, and the air exhaust channel is made in its rear part, which ensures the passage of air pumped by the condenser fan into the aggregate compartment, its subsequent passage through the condenser, blowing direct-flow compressor, and exit through the rear of the body of the aggregate compartment. The channels of the aggregate compartment for air intake from the environment and air exhaust may additionally contain grilles. In this case, the most efficient direct-flow blowing of the condenser and compressor is achieved, which allows to reduce energy consumption during its operation. In addition, this embodiment allows to reduce the dimensions of the used elements of the refrigeration system (condenser, compressor, evaporator), and accordingly, the dimensions of the device itself and its cost.

The refrigeration unit can be made removable, in the form of a replaceable cartridge (replaceable cartridge, monoblock), which makes it possible to quickly install it in any case of the refrigeration unit. In this case, it is universal, because it can be disconnected from the refrigerated volume for repair and service activities or removed and installed in another refrigerating cabinet with a similar volume. This embodiment provides the ability to quickly disconnect it from the cooled volume of the refrigeration unit to simplify the repair and service activities (increase the maintainability of the unit). In case of damage to the housing of the refrigerator, the refrigeration unit (cartridge) can simply be installed in another case, which reduces the labor costs for repairing the refrigerator. In addition, the refrigeration unit can be installed in various cases of the refrigeration apparatus without being tied to their specific sizes.

The fixing of the housing of the refrigeration unit to the upper panel of the housing of the refrigeration apparatus is carried out by eccentrics (or other fixing devices).

The refrigeration unit may further comprise a device (means) for removing condensate generated during thawing of the evaporator, which includes a tray for collecting melt water, installed in isolation, in front of the evaporator chamber, below the evaporator installation level to allow water to drain off the drain pipe connecting the evaporator chamber with the tray and the evaporator itself, and the evaporator, made in the form of a tube of metal or alloy (e.g., copper, aluminum or steel), connected to the compressor and heated I am in hot vapor refrigerant. Due to this embodiment, heating and evaporation of condensate during defrost occurs. In this case, the tray with the evaporator tube inside it can be located under the condenser and behind the heat-insulated wall below the evaporator.

The body of the device can be made of integral polyurethane foam, which provides an increase in heat-insulating properties. Integrated PPU has full heat-insulating properties, as well as mechanical strength, which allows it to install all the constituent structures (compressor, heat exchangers, etc.) into it without the use of additional reinforcing elements, in contrast to the known structures where metal parts are the power elements of the case.

The evaporator fan can preferably be made tangential, which ensures air circulation in the refrigeration chamber, uniform blowing of the evaporator, without the "blind spots" that appear when using, for example, compact axial fans.

A removable electronic control unit for operating the compressor, condenser fan and evaporator fan, which is a command element of the system, can be fixed on the device case.

The refrigeration unit may include an evaporator sensor installed in the upper third of the evaporator chamber and an air supply volume sensor installed near the inlet channel for supplying warm air to the evaporator chamber, and an electronic control unit is connected to these sensors.

The control unit can be connected to the evaporator sensor and to the air supply volume sensor. The control unit forcibly turns off the compressor after a certain time interval. After turning off the compressor, warm air from the refrigerator is supplied to the evaporator, and it begins to thaw. After the compressor is turned on by electronic units, water from the tray begins to evaporate, as the evaporator starts working again (metal tube connected to the compressor).

All structural elements of the system are installed in the housing, preferably in specialized seats, and are rigidly fixed to the housing by appropriate locking elements. In particular, the evaporator can be mounted on a niche attached to the side walls of the chamber, while it is preferably located in the center of the lower compartment and is not in contact with the walls. The compressor can preferably be mounted in the central part of the aggregate compartment on the platform with bolts so that it does not come into contact with the walls of the compartment, which ensures a more complete airflow.

A light panel connected to the control unit can be installed on the front wall of the housing.

Next, the solution is illustrated by reference to the figures, which depict the following.

In FIG. 1 - refrigeration unit.

In FIG. 2 is a diagram of the operation of a refrigeration unit.

In FIG. 3 is a diagram of the operation of a refrigeration unit with an additional divider and a “frieze” panel installed in the refrigeration apparatus.

In FIG. 4 is a diagram of reverse defrost.

In FIG. 5 is a diagram of a condensate evaporator.

In FIG. 6 is a diagram of the installation of the electronic control unit in the unit body.

In FIG. 7 is a diagram of the installation of sensors.

The device is a self-contained refrigeration unit designed for cooling food and drinks. The device is installed in the upper part of the refrigerator. The body of the device is made of integral polyurethane foam with appropriate seats for mounting the internal components of the device. The device contains two horizontal sections of the housing isolated from each other: an aggregate compartment 1 and an evaporator chamber 2, between which a horizontal insulated wall 3 is installed, and contains a condensate evaporator 4 connected to the condensate tray 5 with a drain, and the aggregate compartment 1 contains a condenser 6, connected to the condenser fan 7, and a compressor 8 installed between them, and the evaporator chamber 2 comprises an evaporator 9 connected to the tangential fan of the evaporator 10, while in the lower part of the chambers The evaporator 2 has an inlet channel 11 of warm air through which the intake of warm air, and an outlet channel 12 of cold air. A light panel 17 can be installed on the front wall of the housing. The device includes an evaporator sensor 18 and a volume sensor 19 (Fig. 1, 2).

The operation of the claimed device in a particular case is as follows.

The refrigeration unit is a single closed system consisting of several elements interconnected by pipelines, namely a compressor, a condenser, an evaporator and a control controller, in which refrigerant gas circulates. The fan 7 of the condenser 6 pumps air into the aggregate compartment 1 through the air intake duct. Further, the air passes through the condenser and compressor, cooling them, and leaves through the back of the aggregate compartment 1.

Compressor 8 delivers refrigerant vapor to condenser 6, which in condenser 6 condenses into liquid, which is already supplied to evaporator 2, where the liquid is converted into steam with heat taken from the refrigerating chamber.

The fan 7 of the condenser 6 creates the flow necessary to cool the hot vapors, the steam condenses (goes into the liquid phase).

After passing through the compressor 8 and the condenser 6, the liquid refrigerant is supplied to the evaporator 2, where it “boils” under the action of the throttling device, turning into steam, which causes the cooling effect.

The air is taken from the refrigerating chamber and the air cooled in the evaporator is returned to the refrigerating chamber through the front and rear intake openings made in the lower part of the evaporator chamber.

The fan 10 of the evaporator 9 pumps air into the chamber of the evaporator through the air inlet from the refrigeration chamber. The air flow created by the fan 10 of the evaporator 9 provides cooling of the air passing along the lamellas (ribs) of the evaporator 9 and the removal of cold air through the exhaust channel into the refrigerating chamber. In the refrigerating chamber, the air stream enters the air channel 12, is directed along the rear wall of the chamber and is fed horizontally along the shelves with products through the perforation on the air panel 13, cooling them. Further, air from the refrigerating chamber enters the evaporator chamber through frontal perforation of the air intake (inlet 11), is supplied to the evaporator 9 and is again cooled.

Next, the liquid refrigerant (gas) from the evaporator again enters the compressor 8 and the cycle repeats.

When a divider 14 and a frieze panel 15 are installed in the refrigerator, an additional flow appears at the outlet of the air channel, forming an air curtain on the front of the shelves with the product (Fig. 3).

Evaporator defrost

In the process of operation of the evaporator, the formation of “glaciation” occurs on the lamellas and tubes of the evaporator 9. The defrost process is organized by the reversal of hot steam (reverse defrost). This method of thawing is based on the supply of hot refrigerant vapor from the discharge line of the pipeline to evaporator 2. So, if with “passive” thawing and thawing using electric heaters, the snow coat on the evaporator 2 melts, then when thawing with hot steam it lags behind in whole pieces, since heat enters through the walls of the evaporator 2. This technique is quick and efficient, because the defrost time is reduced by two to three times. The temperature in the volume of the refrigerator does not increase, which reduces energy consumption. A schematic diagram of reverse defrost is shown in FIG. four.

Condensate removal

The next characteristic difference of this model is the condensate evaporator device (Fig. 5). The evaporator, which is a hot "discharge" tube coming from the compressor, is located at the bottom of the device under the condenser. There is free space (cavity) between the condenser and the evaporator. The evaporator is located behind a thermally insulated wall above the evaporator and has a condensate tray with a drain in communication with the evaporator tank.

After a defrost cycle, water from the condensate tray enters the evaporator tank, where it turns into steam due to the hot tube. Steam trapped in the air stream passing through the condenser is removed from the device and dissipated.

The standard scheme assumes that melt water from the evaporator flows by gravity into a bath installed either on the compressor or under it, and then evaporates either due to heat from the compressor or a special tube. However, in the claimed design, in which the cold compartment with the evaporator is installed under the hot compartment with the compressor and the condenser, water cannot drain by gravity into the hot compartment, and therefore the claimed refrigeration unit is designed to allow melt water to flow into a special tray (condensate evaporator) , which is installed below the cold compartment, and evaporation occurs due to the removal of the tube from the discharge line (i.e., the part of the route along which “hot” steam passes from the compressor to the condenser, since this The temperature is the hottest in the system (90 °); it is used as a heating element, in particular, for evaporating thawed condensate).

Control

The electronic control unit is integrated in the front into a special seat in the device housing and can be easily removed for servicing. The unit has the appropriate switching for connecting lighting on the light panel and in the cabinet of the refrigerator. The refrigeration unit is controlled by an electronic microprocessor with two controlled temperature sensors and a display with quick programming buttons. The sensor installation diagram is shown in FIG. 6. The evaporator sensor 18 allows you to program the control of the evaporator fans and the evaporator defrost cycle. It is installed in the upper third of the evaporator 50 mm from the inlet of the throttling device (expansion valve / capillary tube). The volume sensor 19 controls the operation of the refrigeration unit. It is installed in the zone of intake of "warm" air from the volume of the refrigerator.

The dimensions of both the claimed device and the heat exchange equipment may vary depending on the size of the cabinet to be cooled.

Thus, the claimed device is more efficient and economical in operation due to its design, which provides the ability to install electrical components with lower power consumption and heat exchange equipment with a smaller volume and overall dimensions, which reduces its cost and is an advantage over existing similar devices.

Claims (11)

1. The refrigeration unit, characterized in that it contains a housing with an aggregate compartment and an evaporator chamber installed underneath it, separated from the aggregate compartment by a thermally insulated horizontal wall, a condenser, a condenser fan and a compressor are installed in series in the aggregate compartment, an evaporator and an evaporator fan are installed in the evaporator chamber, the compressor, condenser, evaporator are interconnected by a pipeline with refrigerant, the aggregate compartment contains a channel for air intake from the surrounding There is also an air exhaust channel, and in the lower part of the evaporator chamber an exhaust channel is made for exhausting cold air from the evaporator chamber to the refrigerating chamber and an inlet channel for supplying warm air from the refrigerating chamber to the evaporator chamber. 2. The refrigeration unit according to claim 1, characterized in that the air intake channel is made in front of the aggregate compartment, in front of the condenser, and the air exhaust channel is made in its rear part behind the compressor. 3. The refrigeration unit according to claim 2, characterized in that the channels for intake of air from the environment and air exhaust contain grids. 4. The refrigeration unit according to claim 1, characterized in that it is removable. 5. The refrigeration unit according to claim 1, characterized in that it further comprises a device for removing condensate generated during thawing of the evaporator, which includes a tray for collecting melt water, which is installed in isolation in front of the evaporator chamber, below the evaporator installation level connecting the chamber an evaporator with a tray, and an evaporator made in the form of a metal tube connected to a compressor. 6. The refrigeration unit according to claim 1, characterized in that the casing is made of integral polyurethane foam. 7. The refrigeration unit according to claim 1, characterized in that the evaporator fan is made tangential. 8. The refrigeration unit according to claim 4, characterized in that a removable electronic control unit for controlling the compressor, condenser fan and evaporator fan is fixed to the housing. 9. The refrigeration unit according to claim 8, characterized in that it comprises an evaporator sensor installed in the upper third of the evaporator chamber and an air supply volume sensor installed near the inlet channel for supplying warm air to the evaporator chamber, and an electronic unit is connected to said sensors management. 10. The refrigeration unit according to claim 1, characterized in that the compressor is installed in the central lower part of the aggregate compartment on the platform. 11. The refrigeration unit according to claim 1, characterized in that the evaporator is installed in the central part of the evaporator chamber on a niche attached to the side walls of the chamber.

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