WO2008108744A9

WO2008108744A9 - Device for deicing an air-cooler for the refrigerated showcase of shop equipment

Info

Publication number: WO2008108744A9
Application number: PCT/UA2008/000007
Authority: WO
Inventors: Oleg Antonenko; Oleksandr Dvornitsyn; Oleksandr Gudyma
Original assignee: Obshchestvo S Ogranichennoi Ot
Priority date: 2007-03-06
Filing date: 2008-02-29
Publication date: 2009-01-08
Also published as: EP2119986A4; WO2008108744A1; UA25036U; WO2008108744A8; EP2119986A1; EA012195B1; EA200801846A1

Abstract

The invention relates to refrigeration engineering, in particular to systems for deicing refrigerated showcases provided with direct cooling units, preferably to low-temperature refrigeration shop facilities with antifreezing heat carriers. The inventive device comprises a heat storage with an antifreezing heat carrier, a pump for circulating said antifreezing heat carrier and a recuperative heat exchanger which are connected to each other and elements for supplying heat to the heat exchange surface of a showcase evaporator, to the showcase bottom and to a drainage pipeline. The heat supply elements are embodied in the form of two sections, the first of which is arranged in the air-cooler evaporator and contacts the heat exchange surface thereof, whilst the second section is mounted in the showcase bottom near the drainage pipeline. The two sections being interconnected by means of the heat storage. Said device reduces a deicing time and energy consumption.

Description

COMMERCIAL REFRIGERATING AIR COOLER THAWING DEVICE

The field of technology.

The invention relates to refrigeration, in particular to devices for thawing an air cooler of a direct cooling system for refrigerated display cases, preferably low-temperature commercial refrigeration equipment with low-freezing coolants.

Primary use - in large super- and hypermarkets, where thawing of air coolers of several showcases is provided for simultaneously.

Thawing a snow coat from the surface of cooling devices of low-temperature refrigerated display cases of commercial refrigeration equipment, in most cases, is carried out by electric heaters. Less common is the method of thawing with hot refrigerant, which in the vapor state is sent directly from the compressor to the evaporator tubes coated with a snow coat.

1. Tubular electric heaters are installed in the holes of the ribs, in the pipes of the air cooler or placed next to it. The method is very simple to implement, but requires significant energy costs, which is currently a serious disadvantage. In addition, the quality of thawing leaves much to be desired due to uneven heating of the evaporator (problems of thermal contact between the evaporator and the electric heater), which forces general defrosting to be carried out once a month using warm water.

2. The hot refrigerant vapor gives off its heat to the cold evaporator and therefore condenses. Liquid refrigerant can enter the compressor and cause damage. But even with minor refluxes of liquid refrigerant into the compressor crankcase, which do not harm compressor, there is a dilution of the lubricating oil located in the crankcase, and a decrease in its lubricating properties. In this case, the compressor service life is drastically reduced. To prevent this, heat is applied to the liquid using powerful electric heaters or heat accumulators. The disadvantage of this system is also the difficulty of manufacturing a heat accumulator.

3. In brine systems, a separate closed circuit with the same coolant as in the main cold-transfer circuit is used to heat the coolant. The coolant of a separate circuit is heated using a special heater (boiler) and a small centrifugal pump that pumps the hot coolant through a system of batteries to be thawed, bypassing the evaporator. Due to the good thermal contact between the surface of the batteries and the heated coolant, the defrost time is minimized. However, in systems for thawing low-temperature showcases where direct-cooled air coolers are used, it is not possible to directly use the defrosting of the air cooler by passing heated coolant through its sections. These sections are occupied by the refrigerant, and mixing the refrigerant with the coolant is unacceptable. The proposed device for defrosting the air cooler can be used not only in the cabinets of low-temperature commercial refrigeration equipment, but also in medium-temperature showcases, both with an individual refrigeration unit and with a multi-compressor central refrigeration unit. The proposed defrosting device of the air cooler can significantly reduce the thawing time (up to 6-10 minutes instead of 20-30 minutes) and reduce energy costs by using the heat of the system to heat a low-freezing coolant and relatively low power consumption of the pump. The prior art. From sources of scientific, technical and patent information, a number of methods and devices are known for thawing the heat transfer surface of cooling devices for direct and brine cooling of low-temperature commercial refrigeration equipment:

5 electric heaters, hot refrigerant vapors, low-freezing coolants, for example, salt solutions, glycol, organosilicon fluids, organofluorine fluids (see Dossat Roy J. Fundamentals of refrigeration. Transl. From English. - M .: Light and food industry, 1984. - p. 448 -

10,445; Zelikovsky I.X .. Kaplan JI. G. Small refrigeration machines and installations: a Handbook. - 3rd ed., Revised. And add. - M .: Agropromizdat. 1989. - p. 301, 473 - 482; Gogolin A.A., Kolotiy Yu.N. Thawing air coolers. M. TSNIITEIImyasomolprom. 1972; Thawing air coolers. - In collection: “Refrigeration and transport

15 M., TsNIITEIimyasomolprom, 1969, issue 8).

Analyzing analogues from the above sources, the following can be noted: thawing of low-temperature refrigerated display cases of commercial refrigeration equipment, in most cases, is carried out using hot refrigerant vapors or electric heaters. 0 The device for thawing tube-fin air coolers with hot refrigerant vapor injected by the compressor into the air cooler includes a discharge pipe with a bypass line and an electromagnetic valve. When the solenoid valve opens, hot steam, bypassing the condenser, enters the air cooler. Defrosting 5 is carried out by the hot vapor of the refrigerant, which gives its heat to the cold air cooler and condenses. This defrosting device has several disadvantages. During defrosting, the amount of hot steam supplied by the compressor is limited, as most of the liquid condenses in the evaporator and a smaller amount of refrigerant 0 is returned to the compressor for recirculation. More serious disadvantage - liquid refrigerant can enter the compressor and cause damage. To prevent this, heat is applied to the liquid using powerful electric heaters or heat accumulators. The disadvantage of this system is also the difficulty of manufacturing a heat accumulator.

To thaw frost from cooling devices in brine systems (with an intermediate coolant) with a temperature in cooling devices of about -40 ⁰ C, low-freezing coolants are used - salt solutions, glycolic, organosilicon and organofluorine fluids. Defrosting systems from the side of the intermediate coolant are mostly closed, with air coolers, of a closed type, in which the coolant does not come in contact with air. When using a low-freezing coolant for thawing, it is placed in a thermally insulated container with heating elements, and if there is a year-round heat source (hot water, steam) at the facility, instead of heating elements, coils are installed in the container with a heating medium, through which hot water or steam circulates. The coolant heated to a temperature of 30 ... 40 ⁰ C is pumped into the batteries to be thawed, or it is fed into the pipes of the air cooler (see Chervyakov CC, Kulakovsky A.I. Basics of refrigeration: Textbook. Handbook for SPTU - 2nd ed. ., revised and additional - M .: Higher school., 1988. - pp. 54, 62, as well as Kantorovich V.I., Yavnel B.K. Device, operation, installation and repair of refrigeration units Textbook: - M .: Publishing House of Trade Literature, 1960., p. 204 - 206).

To thaw frost from cooling devices in brine systems, a separate closed circuit is used with the same coolant as in the main cold-transfer circuit. The coolant of a separate circuit is heated using a special heater (boiler), and a small centrifugal pump pumps the hot coolant through a system of batteries to be thawed, bypassing the evaporator. Due to good thermal contact between the surface of the batteries and the heated coolant, the defrost time is minimized.

In systems for thawing low-temperature showcases where direct-cooling air coolers are used, it is not possible to directly use defrosting the air cooler by passing heated section through its sections. These sections are occupied by the refrigerant, and mixing the refrigerant with the coolant is unacceptable. Therefore, defrosting of low-temperature display cases is carried out by heating elements.

In low-temperature display cases thawing of finned air coolers is carried out using electric heaters (TENOV). Heated not only the heat exchange surface of the air cooler, but also the bottom of the display case and drain pipe. Tubular electric heaters are built into the holes of the ribs, in the pipes of the air cooler or placed next to them. The defrost cycle begins when the solenoid valve in the liquid pipe is closed, as a result of which the air cooler is emptied, and then the compressor stops. At the same time, the electric heating elements of the air cooler, bottom and drain pipe are switched on. The fans turn off so that warm air does not enter the cooling space. After the air cooler, bottom and drain pipe are completely thawed, the electric heaters are turned off, the electromagnetic valve on the liquid pipe opens, the compressor is turned on, the fans and the whole installation goes into cooling mode. Closest to the claimed invention is a device for thawing an air cooler of a refrigerated display case made of heating elements. Tubular electric heating elements (heating elements) are installed in special slots made in the evaporator, the same elements are installed on the bottom and near the drain pipe of the window (Zelikovsky I.X. Kaplan L.G. Small refrigeration machines and installations: Directory. - 3rd ed., Revised. And add. - M .: Agropromizdat. 1989. - p. 301).

This device is selected by us as a prototype. The prototype and the claimed invention have common features: - the presence of structural elements for supplying heat to the heat exchange surface of the evaporator of the air cooler, the bottom of the window and the drain pipe (the prototype is TENY);

- the heat supply elements are in thermal contact with the heat exchange surface of the evaporator of the air cooler, with the bottom and with the drain pipe.

The disadvantage of defrosting by heating elements is their poor thermal contact with the tubular surface of the evaporator of the air cooler (mainly, point thermal contact). In this regard, the defrost time is 20-30 minutes, despite the high heating temperature of the heating elements (150-200 ^° C). As a result, during thawing, the temperature in the cooled volume rises significantly, which, in turn, leads to a relatively long-term treatment of frozen products with warm air. In addition, there are additional costs of electricity consumed by both heating elements for heating during thawing, and a refrigeration unit for subsequent cooling of the working volume.

Disclosure of the invention.

The basis of the invention is the task to create an improved device for thawing the air cooler of the refrigerated display case of commercial equipment, in which by introducing additional units and also by performing separate heat supply sources, it is possible to reduce the time of thawing and energy consumption during thawing of the air cooler of low-temperature display cases, shelves of commercial refrigeration equipment super - and hypermarkets.

The problem is solved in a device for thawing the air cooler of a refrigerated display case of commercial equipment, including elements for supplying heat to the heat exchange surface of the air cooler evaporator, to the bottom of the display case and to the drain pipe, in that it is additionally equipped with a heat accumulator with a low-freezing coolant, a low-freezing coolant circulation pump and a recuperative heat exchanger that receives the heat of the compressed refrigerant, and the elements are made in the form of two additional sections, the first of which is installed in the evaporator of the air cooler and is in thermal contact with its heat exchange surface, and the second additional section is installed in the bottom of the window next to the drain pipe, while both additional sections are connected to the heat accumulator.

In addition, the heat transfer surface of the first additional section is structurally identical to the heat transfer surface of the air cooler evaporator.

New in the claimed invention is that the device is additionally equipped with:

- a heat accumulator with a low-freezing coolant;

- low-freezing coolant circulation pump; - a recuperative heat exchanger that senses the heat of a compressed refrigerant.

The novelty of the claimed invention also lies in the fact that the heat supply elements are made in the form of two additional sections, their location and the connection scheme between known and new nodes. From the sources of patent and scientific and technical information, thawing devices for air coolers of low-temperature showcases of commercial refrigeration equipment of super- and hypermarkets are not known, in which:

1. The elements of the heat supply for thawing the evaporator of the air cooler are made in the form of two additional sections, the first of which is installed in the evaporator, is structurally identical to the sections of the evaporator and is in thermal contact with its heat exchange surface, and the second is in the bottom of the display case and next to the drain pipe; 2. Both sections are connected by a thawing line with a heat accumulator with a low-freezing coolant;

3. The heat accumulator is connected by coolant circulation lines to a circulation pump for heating the heat carrier in a recuperative heat exchanger with compressor refrigerant vapor, and directing the heated coolant to both additional sections.

All these differences characterize the claimed thawing device with a new set of features, compared with the well-known technical solutions in science and technology, which inform the subject of the invention new properties and create a positive effect. The new properties are as follows: since one section has good thermal contact with the heat exchange surface of the evaporator, due to the structural unity, the entire evaporator warms up quickly and evenly. Heating of the heat carrier is carried out with the hot steam of the refrigerant, i.e. waste heat. The positive effect is to reduce the defrost time.

(up to 6-10 minutes) and energy costs due to the relatively low power consumption of the pump.

A brief description of the drawings.

The inventive device for thawing the air cooler of a refrigerated display case of commercial equipment is shown in the drawings, where: FIG. 1 is a schematic diagram of a device; FIG. 2 is a sectional view of a showcase.

An embodiment of the invention. The device for thawing the air cooler of the refrigerated display case of commercial equipment contains interconnected process pipelines:

- 1 - compressor, - 2 - recuperative heat exchanger,

- 3 - low-freezing coolant circulation pump,

- 4 - heat accumulator with low-freezing coolant,

- 5 - capacitor,

- 6 - receiver, - 7 - thermostatic valve,

- 8 - air cooler with fans and evaporator,

- 9 - evaporator air cooler, with a tubular finned heat exchange surface,

- 10 - the first additional section thawing the evaporator of the air cooler,

- 11 - the second additional section thawing the bottom and drain pipe showcases,

- 12, 13, 14, 15 - electromagnetic valves,

- 16 - defrosting line, - 17 - coolant circulation lines, for heating it,

- 18 - the bottom of the display case,

- 19 - drain pipe.

Usually, when automating the process of thawing the air cooler of the windows of commercial refrigeration equipment, thawing is carried out alternately at regular intervals by the signal of the electronic units in accordance with a given program. Thawing the air cooler refrigerated display cases of low-temperature commercial refrigeration equipment according to the proposed system is as follows. In cooling mode, the electronic unit (not shown in the drawing) turns on the compressor 1 of the refrigeration unit, opens the solenoid valves 12 and 15 with a continuously operating low-freezing coolant circulation pump 3. Compressed refrigerant vapor is supplied by compressor 1 to a recuperative heat exchanger 2, where the compressed refrigerant is transferred by compressor 1 to heat to the low-freezing coolant supplied by the low-freezing coolant circulation pump 3 from the heat accumulator with the low-freezing coolant 4 through the open solenoid valve 13. The heated solution from the recuperative heat exchanger 2 through the open solenoid valve 14 is returned to the heat accumulator with a low-freezing coolant 4. The refrigerant from the recuperative heat exchanger 2 is sent to the condenser 5, and then to the receiver 6. During cooling, on the tubular ribbed surface of the evaporator 9 an air cooler 8 forms a snow coat, and the bottom of the display case 18 and the drain pipe 19 are overgrown with ice.

When defrosting the air cooler 8, the electronic unit turns off the compressor 1, the fans of the air cooler 8, closes the solenoid valves 13, 14, opens the solenoid valves 12 and 15, and the heated coolant from the heat accumulator 4 through the defrost line 16 enters the first 10 and second 11 additional sections of the air cooler 8 The snow coat melts as a result of heat exchange between the evaporator 9 and the first additional section 10, due to the high thermal conductivity of the ribs of the tubular surface of the evaporator 9. The second additional Section 11 heats the bottom of the display case 18 and the drain pipe 19. Melt water from the air cooler flows into the bottom of the display window 18, connecting with the thawed water of the drain pipe 19, and is sent to the sewer. Defrost time is 6 - 10 minutes. When the temperature of the heat exchange surface of the evaporator 9, additional sections 10 and 11 to 4 .... 5 ⁰ C, the electronic unit turns off the electromagnetic valves 12, 15, turns on compressor 1, fans, opens solenoid valves 13, 14, and the showcase switches back to cooling mode. Further, the described sequence of actions is repeated. Industrial applicability.

The proposed device for thawing the air cooler of low-temperature showcases can also be used in direct cooling systems of medium-temperature commercial refrigeration equipment with both an individual refrigeration unit and a multi-compressor unit.

The defrosting device can significantly reduce the defrosting time to 6-10 minutes (compared to 20-30 minutes when defrosting with heating elements) and reduce the cost of electricity by using the internal heat of the device to heat a low-freezing coolant and relatively low power consumption of the pump.

Claims

Claim

1. A device for thawing the air cooler of a refrigerated display case of commercial equipment, including a compressor and condenser unit interconnected by technological pipelines, an air cooler with a tubular-ribbed surface, individual sources of heat supply to the heat-exchanging surface of the air cooler, the bottom of the display case, and the drain pipe, as well as electromagnetic valves, characterized in that it is additionally equipped with a heat accumulator with a low-freezing coolant, a low-circulation pump freezing coolant and a recuperative heat exchanger, and the individual sources of heat supply are made in the form of two additional sections, the first of which is installed in the evaporator of the air cooler and is in thermal contact with its heat exchange surface, and the second additional section is installed in the bottom of the window near the drain pipe, while both additional sections are connected to the heat accumulator.

2. The device according to p. 1, characterized in that the heat transfer surface of the first additional section is structurally identical to the heat transfer surface of the evaporator of the air cooler.