PL192470B1 - Evaporator arrangement - Google Patents

Abstract

The invention relates to an evaporator arrangement for cooling refrigeration chambers in a refrigerating device such as a refrigerator, a combination refrigerator and freezer or similar, comprising at least two series-connected evaporators (11, 16) which are arranged one behind the other in a single-circuit refrigeration system. One of said evaporators has a plate-type configuration (12, 17) and has a lower refrigerating capacity than the other. Both evaporators (10) are uniformly cooled by at least one refrigerant channel (13) for guiding the refrigerant. At the end of its course on the evaporator with the higher refrigerating capacity, said refrigerant channel extends into the section of the evaporator with the lower refrigerating capacity (16) that is allocated to the area of the refrigeration chamber cooled by this evaporator (16) that heats up the most (A). The refrigerant channel then extends from this area (A) across the remaining surface of the evaporator with the lower refrigerating capacity.

Description

Description of the invention

The invention relates to an evaporator system for cooling the chambers of a refrigeration appliance, such as a refrigerator, fridge-freezer or the like, with at least two evaporators arranged in series in a single-circuit cooling system, one of which has a refrigerant injection point, the evaporators being connected to each other. with at least one refrigerant channel in the cooling system.

Known evaporator systems have a refrigerant conduit at the end of its run for cooling in the evaporator with a point of injection of this refrigerant leading to the upper part of the second evaporator in the mounting position of the evaporator, which belongs to the area cooled by the evaporator, the conduit the refrigerant extends from the uppermost part through the remainder of the second evaporator, the evaporators having a different cooling capacity.

In the case of refrigeration appliances with at least two cooling zones that are thermally insulated from each other, such as a normal cooling zone and a low-temperature cooling zone below it, or a freezing zone and a normal cooling zone located beneath it, each of these is assigned according to the prior art. zones after one evaporator, which are usually formed by the segments of the evaporator plate and are arranged in tandem in a single-circuit cooling system. In a series arrangement of evaporators, it is usually the case that the evaporator with the lower refrigerating capacity is connected downstream of the evaporator with the higher capacity and the refrigerant flows vertically from the bottom to the top between the two plate segments to minimize the length of the refrigerant flow path. As a result of this flow through the downstream evaporator segment, a thermal stratification is formed in the cooling zone, as a result of which the temperature in the upper part of this zone is much higher than in the lower part. There is therefore a relatively large temperature difference between these parts of the cooling zone.

In order to avoid this type of thermal stratification within the cooling zone, it has been conceived to arrange inside the cooling zone a fan that introduces the air of the cooling zone into a circular motion. Such a technical measure unnecessarily increases not only the cost of installing the fan, but also the device consumes more energy due to the need for continuous operation of the fan.

From European patent application EP 01 78 25 226 a refrigeration appliance is known with an upstream freezing space and an underlying normal cooling space, in which the cooling of the normal cooling space takes place by means of an evaporator provided therein to such an extent that approximately approximately In the center of the evaporator, a cooling medium supply channel runs through the coolant injection point from this injection point to the lower end of the plate. Due to this course of the refrigerant channel, a so-called "cold air lake", i.e. a layer of one temperature, inevitably forms in the lower region of the refrigeration space, which in the lower region of the refrigeration space leads to the risk of freezing of the foodstuffs stored there.

The object of the invention is to improve the evaporator system by simple design measures so as to obtain at least approximately uniform temperature distribution in the cooled zone by the downstream evaporator.

An evaporator system for cooling the chambers of a refrigeration appliance, such as a refrigerator, fridge-freezer or the like, with at least two evaporators arranged in series in a single-circuit cooling system, is characterized according to the invention in that the refrigerant channel is routed from the evaporator having a higher capacity. with the point where the refrigerant is injected at the top in the position of mounting the end part of the second evaporator with the lower cooling capacity and from that end part of the evaporator with the lower cooling capacity, the channel runs through the rest of the evaporator with the lower capacity, in particular the evaporator system is designed as an evaporator plate with at least two plate segments with different cooling capacity.

Preferably, from the plate segment with the higher cooling capacity, the refrigerant channel is led from its end on the segment at least to the opposite end part of the higher-situated plate segment with the lower cooling capacity, from where it is routed at least approximately meandering through the remaining surface. plate segment with lower capacity.

PL 192 470 B1

In particularly advantageous embodiments of the subject matter of the invention it is provided that the refrigerant channel on the plate segment with the lower cooling capacity has a collector located at the end of its course on the side of the plate segment with higher capacity or on the plate section with lower cooling capacity at the end of its course on the opposite side. for a high-performance plate segment close to the extraction point there. Therefore, the path between the collector and the refrigerant suction point can be minimized, so that when the compressor stops, the refrigerant accumulating in the collector can enter the cooling circuit as soon as the refrigerant compressor is restarted.

Preferably, from the plate segment with a higher cooling capacity, the refrigerant channel is led from its end on this segment at least to the lower end part located on the side of the segment located below j in the mounting position of the plate segment with a lower cooling capacity, from where it runs at least approximately meandering by the remaining area of the plate segment with lower efficiency.

By means of the solution according to the invention, without the installation of a fan or the like increasing the cost of the refrigeration apparatus, an at least largely homogeneous temperature distribution is achieved in a refrigerating chamber, such as for example in the normal cooling zone, and thus the temperature difference in the zone is minimized. since the refrigerant channel exiting the evaporator with the injection point, such as an evaporator of a freezer or refrigeration preservative zone, is directly connected with high cooling capacity to the upper end portion of the second evaporator. Such intensive cooling of the upper part of the evaporator promotes natural convection and favors the mixing of the air in the zone cooled by the second evaporator due to the higher specific gravity of the cold air.

The design of the evaporator system in the form of an evaporator plate with at least two plate segments with different cooling capacity facilitates the installation of the evaporator system in the cooling device and at the same time stabilizes the channel routed in the system, which avoids thermal stratification in the zone cooled by the evaporator system.

Such an arrangement of evaporators in a refrigeration appliance with an upstream normal cooling zone and a downstream preservative cooling zone provides at least approximately a uniform temperature distribution in the first cooling zone, since the cold air with a higher specific gravity causes natural convection in the normal cooling zone.

Due to such a system of evaporators, preferably used in a refrigerator with a freezer and a normal cooling zone, at least largely uniform temperature distribution in the latter zone is obtained, because the refrigerant channel routed in this way causes a stronger cooling of the upper part of the normal cooling zone and the cold air with a higher specific weight causes natural convection in the cooling zone and air mixing in this zone.

The invention will be explained in more detail using an embodiment shown schematically in the attached drawing.

One figure of the drawing shows schematically an evaporator plate with two connected evaporator segments assigned to a normal cooling zone and a low temperature cooling zone.

The figure shows, for example, a Roll-Bond for a refrigeration appliance with a normal cooling zone and a cooling zone for preserving the evaporator plate 10, which has a first plate segment 11 for cooling the preserving zone, the surface of which 12 is covered in a meandering pattern at the bottom. upwards through a refrigerant channel 13, which, starting from the gland 14 on the bridge 15, is fed upstream to the plate segment 11 and runs along it first along the end of the surface 12 located lower in the mounted position and remote from the bridge 15. From this end, the refrigerant channel 13 it extends, as already mentioned, in a meandering way up to the end surface of the plate 12 on the side of the bridge 15, from where it is led via the bridge 15 to the second plate segment 16 for cooling the normal zone. After reaching the plate segment 16, it passes over its surface 17 directly to the upper end part A, opposite to the plate segment 11. From the part A, which is in the position of mounting the evaporator plate 10 at the top of a refrigeration device not shown in the drawing, the refrigerant channel 13 runs

PL 192 470B1 meandering through the rest of the surface B at the end of the plate segment 16 on the side of the plate segment 11. Here, a manifold 18 is connected to the refrigerant channel 13, from the outlet of which the refrigerant channel 13 passes again to the upper part A of the plate segment 11 and hence it is led to a suction point 19 situated on the bridge 15 connecting the two plate segments 11 and 16.

As an alternative to the above-described embodiment, the invention is also suitable for the configuration of a wire-tube evaporator for a freezer and a plate evaporator for a cooling zone, used for example in a refrigerator-freezer.

In this case, the plate evaporator assigned to the cooling zone is preferably cooled downstream of the upper cooling zone in order to at least substantially counteract the thermal stratification in the cooling zone and to promote natural convection due to the higher specific gravity of the cold air.

Claims (6)

Patent claims 1.Evaporator system for cooling the compartments of a refrigerating appliance such as a refrigerator, chiller / freezer or the like, with at least two evaporators arranged in series in a single-circuit cooling system, one of which has a refrigerant injection point, the evaporators being connected to in the cooling system with at least one refrigerant channel and the refrigerant channel at the end of its course for cooling in the evaporator with the injection point of this refrigerant is led to the upper part of the second evaporator in the mounting position of this evaporator, which belongs to the cooled zone through this evaporator, the refrigerant channel running from the uppermost part through the remainder of the second evaporator, the evaporators having a different cooling capacity, characterized in that the refrigerant channel (13) is routed from that of the higher vapor capacity with a place where the refrigerant is injected into the top end (A) of the second evaporator with a lower cooling capacity in the installed position, and from that end part (A) of the evaporator with the lower cooling capacity, the channel passes through the remaining part (B) of the evaporator with lower efficiency. 2. Evaporator system according to claim The method of claim 1, characterized in that the evaporator system is designed as an evaporator plate (10) with at least two plate segments (11, 16) with different cooling capacity. 3. Evaporator system according to claim A refrigerant conduit (13) as claimed in claim 2, characterized in that from the plate segment (11) with higher cooling capacity, the refrigerant channel (13) is guided from its end on the plate segment (11) at least near the opposite end portion (A) of the uppermost plate segment in the mounting position. (16) with a lower cooling capacity, from where it is led at least approximately meandering through the remaining surface (B) of the plate segment (16) with the lower capacity. 4. Evaporator system according to claim A method according to claim 2 or 3, characterized in that the refrigerant channel (13) on the plate segment (16) with the lower cooling capacity has a manifold (18) formed at its end portion on the side of the plate segment (11) with the higher capacity. 5. Evaporator system according to claim 1 A manifold (13) formed in the end portion (A) of its course on the side opposite to the plate segment (11) with a higher cooling capacity, according to claim 2 or 3, characterized in that the refrigerant channel (13) on the plate segment (16) with a lower cooling capacity near the suction point there (19). 6. Evaporator system according to claim 6 A refrigerant passage according to claim 2, characterized in that from the plate segment (11) with a higher cooling capacity, the refrigerant channel (13) is guided from its end on the plate segment (11) at least near a downstream end portion located on the side of the plate segment (11) in the position of mounting the plate segment (16) with a lower cooling capacity, from where it runs at least approximately meandering through the remaining surface (B) of the plate segment (16) with a lower cooling capacity