KR102241684B1 - Refrigeration system with single unit cooler and spare refrigeration - Google Patents

Abstract

The present invention relates to a refrigeration system with a single unit cooler and a spare refrigeration device, which is configured to enable a regular use CDU and a spare CDU connected to a single unit cooler to be selectively operated according to a sensing value through a temperature measuring sensor, thereby improving space utilization and efficiency of freezing. A refrigeration system which keeps a storage space at a low temperature comprises: a compressor for compressing a refrigerant and discharging the refrigerant in a gaseous state; a CDU unit connected to the compressor by a pipe, and including a regular use CDU and a spare CDU which circulate the refrigerant compressed by the compressor and perform heat exchange between the refrigerant and atmosphere; a unit cooler connected to one sides of the regular use CDU and the spare CDU by means of a pair of pipe parts each of which includes an input pipe and an outlet pipe and including one or more air blowing fans for cooling the inside of the storage space of the refrigeration system; one or more temperature measuring sensors fixedly installed at regular intervals on one side of the inside of the refrigeration system; and a control unit for selectively controlling the regular use CDU and the spare CDU according to a value sensed by the temperature sensors.

Description

Refrigeration system with single unit cooler and spare refrigeration}

The present invention relates to a refrigeration system equipped with a single unit cooler and a spare refrigeration device, and more particularly, a constant refrigeration device (hereinafter referred to as'always CDU') connected to one unit cooler and a spare refrigeration device. A single unit cooler and preliminary refrigeration to improve overall efficiencies such as space utilization and refrigeration efficiency by selectively operating the device (hereinafter referred to as'preliminary CDU') according to the sensing value through the temperature measurement sensor. It relates to a refrigeration system equipped with a device.

In general, a freezing warehouse is a place to establish an environment in which a low temperature is maintained, and an appropriate temperature must be kept constant at all times in order to maintain a good quality of the stored material. At this time, the temperature inside the freezer is usually maintained at a temperature below zero.

As is well known, a refrigeration device applied to such a refrigeration warehouse uses a so-called refrigeration cycle that generates cold air in the process of sequentially circulating compression, condensation, expansion, and evaporation, and the above circulation process usually compresses the refrigerant. A compressor that discharges it in a liquid state, a condenser that changes the compressed refrigerant into a state of room temperature and high pressure by exchanging heat (dissipating heat) with outside air, and an expansion valve that adiabatically expands the condensed refrigerant to phase change into a gas state at low temperature and low pressure And, an evaporator that exchanges heat (absorbs heat) with a refrigerant in a gaseous state of low temperature and low pressure and sends it back to the compressor in a state of low temperature and low pressure. In addition, the refrigerant passing through the evaporator is supplied to the compressor through an accumulator that controls the stable flow of the refrigerant.

However, since such a refrigeration device uses a general refrigeration cycle as it is, it is difficult to effectively cope with the change in the amount of storage in the freezer. In other words, when the amount of storage in the freezer warehouse increases rapidly, the number of freezers had to be increased or large-sized freezers had to be installed in order to exhibit the appropriate efficiency for the freezer. When the amount is small, there is a problem in that the refrigeration efficiency rapidly decreases, such as unnecessary refrigeration.

Korean Registered Patent Publication No. 10-1097974 (Energy-saving Refrigerated Freezer, Announcement on Dec. 22, 2011) Korean Patent Publication No. 10-1250050 (Evaporative cooling apparatus and method for cooling fluid, 2013.04.02. Announcement) Korean Patent Publication No. 10-1651328 (Refrigerator and its control method, 2016.08.25. Announcement)

The present invention was created to solve the problems of the prior art, the object of the present invention,

First, by constructing a regular CDU and a spare CDU in a refrigeration system that maintains a low temperature, and by making the spare CDU run when an abnormality occurs in the regular CDU, the temperature of the entire refrigeration space can be kept uniform at all times.

Second, to provide a refrigeration system equipped with a single unit cooler and a spare refrigeration device capable of effectively controlling refrigeration performance according to a change in storage amount or a change in temperature.

The configuration of the problem solving means of the present invention for achieving the above object,

In a refrigeration system having a storage space formed therein and maintaining a temperature of the storage space at a low temperature,

A compressor 100 installed in the storage space of the refrigeration system and compressing the supplied refrigerant and discharging it in a gaseous state of high temperature and high pressure;

It is installed in the storage space of the refrigeration system, connected to the compressor 100 by pipe, and circulates the refrigerant compressed by the compressor 100 to exchange heat with the atmosphere. A configured CDU unit 300;

Pipes are connected to one side of the regular CDU 320 and the spare CDU 340 via a pair of pipes each consisting of an inlet pipe and a discharge pipe, and a blowing fan for cooling the inside of the storage space of the refrigeration system ( Unit cooler 400 provided with one or more 440;

A temperature measuring sensor 500 fixedly installed at least one inside the refrigeration system at a predetermined interval; And

And a control unit 600 for selectively controlling the constant CDU 320 and the spare CDU 340 according to the value sensed by the temperature measurement sensor 500.

Here, the control unit 600 includes: a comparison unit 620 for comparing a set temperature set by a user and a sensing temperature sensed by the temperature measurement sensor 500; Allows power to be applied to the spare CDU 340 when the sensing temperature exceeds a set temperature based on the comparison value derived by the comparison unit 620, and power is applied to the spare CDU 340 A control controller 640 that cuts off the power of the constant CDU 320; It may include a power supply unit 660 for supplying power to the control controller 640;

In another embodiment of the present invention, when the unit cooler 400 is additionally provided, a CDU unit is provided equal to the number of unit coolers, but each constant CDU 320 constituting the CDU unit and It is preferable to connect a piping part composed of an inlet pipe and a discharge pipe in the spare CDU 340 to the unit cooler 400 in a cross structure.

In another embodiment of the present invention, the temperature measurement sensor 500 and the control unit 600 may further include a wireless communication module, and the control unit 600 is sensed by the temperature measurement sensor 500 The resulting overall data can be controlled to be transmitted to the mobile terminal of the administrator by the wireless communication module.

In addition, the unit cooler 400 includes a cylindrical blowing duct 410 having a flange formed with a fastening hole 412 outside the front end and the rear end; A bracket 420 fixedly installed inside the rear surface of the blowing duct 410; A motor 430 that is rotated in a forward direction or a reverse direction by the application of a current while installed on the bracket 420; A blowing fan 440 that discharges cool air generated while being rotated while being fixedly coupled to the tip of the rotation shaft of the motor 430 to the outside of the tip of the blowing duct 410; As a configuration for improvement, a mesh body 460 having a plurality of through holes having a honeycomb structure may be provided inside the flange.

In addition, a defrosting facility 450 for performing a defrosting operation by providing heat or hot water may be provided on one side of the inner surface of the blowing duct 410, and the defrosting facility 450 passes the flow path of the blowing duct 410 It may be made to include a damper 452 that operates in conjunction with this defrosting facility to open or close.

A refrigeration system equipped with a single unit cooler and a spare refrigeration device of the present invention having the above configuration, as described above, controls the constant CDU and the spare CDU to be selectively operated according to the temperature change of the storage space. By doing so, the temperature of the freezing space can be kept uniform at all times, and even if the operation is stopped due to an abnormality in the regular CDU, the spare CDU is immediately operated to prevent degradation of the quality of the object due to extreme temperature changes. It is possible to do so, and by operating multiple CDUs with one unit cooler, there is an effect of improving overall efficiency such as refrigeration efficiency and space utilization.

1 is a schematic diagram showing a refrigeration system equipped with a single unit cooler and a spare refrigeration device of the present invention;
2 is a schematic diagram showing a refrigeration system equipped with a single unit cooler and a spare refrigeration device according to a second embodiment of the present invention;
3 is a schematic diagram showing the control unit of the present invention,
4 is a schematic diagram showing a wireless communication module of the present invention;
5 is a flowchart showing a sequence of operating the CDU unit of the present invention;
6 is a cross-sectional view showing the unit cooler of the present invention;
7 is a cross-sectional view showing a state in which a damper is mounted on the unit cooler of FIG. 6.

The present invention is a single unit capable of improving overall efficiencies such as space utilization and refrigeration efficiency by selectively operating the constant CDU and the spare CDU connected to one unit cooler according to the sensing value through the temperature measurement sensor. It relates to a refrigeration system equipped with a unit cooler and a preliminary refrigeration device, and an embodiment thereof will be described with reference to the accompanying drawings as follows.

- under -

As shown in the drawings, in the refrigeration system of the present invention, a storage space capable of storing a storage object (dried object) that is required to be frozen is provided, and this storage space maintains a constant low temperature temperature at all times.

To this end, the refrigeration system according to the present invention includes: a compressor 100 installed in a storage space of the refrigeration system and compressing the supplied refrigerant and discharging it in a gaseous state of high temperature and high pressure; It is installed in the storage space of the refrigeration system, connected to the compressor 100 by pipe, and circulates the refrigerant compressed by the compressor 100 to exchange heat with the atmosphere. A configured CDU unit 300; Pipes are connected to one side of the regular CDU 320 and the spare CDU 340 via a pair of pipes each consisting of an inlet pipe and a discharge pipe, and a blowing fan for cooling the inside of the storage space of the refrigeration system ( A unit cooler 400 having one or more 440; A temperature measuring sensor 500 fixedly installed at least one inside the refrigeration system at a predetermined interval; And a control unit 600 for selectively controlling the constant CDU 320 and the spare CDU 340 according to the value sensed by the temperature measurement sensor 500.

In the configuration of the present invention, the compressor 100 is installed in the storage space of the refrigeration system, and compresses the supplied refrigerant and discharges it in a gaseous state of high temperature and high pressure.

That is, the compressor 100 performs a function of receiving and compressing the refrigerant stored in an accumulator, for example, and changing it into a gaseous state of high temperature and high pressure. The gaseous refrigerant may be separately provided with a separator to separate impurities such as bubbles and moisture, and the refrigerant in a state in which the impurities are separated may be delivered to the CDU unit 300.

Meanwhile, in the configuration of the present invention, the CDU unit 300 is installed in the storage space of the refrigeration system and connected to the compressor 100 by pipe, circulating the refrigerant compressed by the compressor 100 and performing heat exchange with the atmosphere. Perform.

That is, the CDU unit 300 performs heat exchange (or heat dissipation) with outside air to change the high temperature and high pressure refrigerant supplied from the compressor 100 to a state of room temperature and high pressure.

At this time, the CDU unit 300 is configured to include a regular CDU 320 and a spare CDU 340, as shown in FIG.

The constant CDU 320 is operated normally in a general environment, or a sudden temperature change occurs, for example, assuming that the set temperature is -5°C, the sensing temperature is -4°C or higher by the control unit 600. The operation is immediately stopped, and the spare CDU 340 is controlled to perform the function of the regular CDU 320 instead.

Therefore, even if an abnormality occurs due to self-defects or external environmental factors while the regular CDU 320 is in operation, the operation of the regular CDU 320 is immediately stopped and the spare CDU 340 is operated, thereby causing a sudden It is possible to prevent the deterioration of the quality of the stored material due to temperature change.

In the configuration of the present invention, the unit cooler 400 is pipe-connected to one side of the regular CDU 320 and the spare CDU 340 via a pair of piping portions composed of an inlet pipe and a discharge pipe, respectively, and the refrigeration One or more blowing fans 440 for cooling the inside of the storage space of the system are provided.

The unit cooler 400 as described above sequentially performs processes of compressing, condensing, expanding, and evaporating the refrigerant, and generates cold air using a circulating refrigeration cycle generated at this time.

In addition, the blower fan 440 of the unit cooler 400 forcibly blows air in the refrigeration system to provide the amount of heat required for evaporation of the refrigerant and at the same time cools the storage space in the refrigeration system by blowing cold air.

According to a further embodiment of the present invention, a member for dissipating an ionizer may be installed in the unit cooler 400. The ionizer kills mold or harmful bacteria that may occur in the storage space of the refrigeration system by providing a large amount of negative ions to the air volume by the blowing fan. It can be kept for a long time in a fresher condition without it.

The unit cooler 400, which is a configuration of the present invention, will be described in more detail, as shown in FIG. 6, a cylindrical blowing duct 410 having a flange formed with a fastening hole 412 at its front and rear ends; A bracket 420 fixedly installed inside the rear surface of the blowing duct 410; A motor 430 that is rotated in a forward direction or a reverse direction by the application of a current while installed on the bracket 420; It may include a blower fan 440 for discharging the cold air generated while being rotated while being fixedly coupled to the front end of the rotation shaft of the motor 430 to the outside of the front end of the blowing duct 410.

In this case, a mesh body 460 having a plurality of honeycomb-structured through holes may be provided inside the flange. According to the honeycomb structure as described above, the effect of further maximizing the blowing efficiency and the blowing area can be expected.

In addition, a defrosting facility 450 for performing a defrosting operation by providing high-temperature heat or hot water may be provided on one side of the inner surface of the blowing duct 410, and as shown in FIG. 7, the defrosting facility 450 is It may include a damper 452 that operates in conjunction with the defrosting facility to open or close the flow path of the blowing duct 410.

Meanwhile, according to the second embodiment of the present invention, as shown in FIG. 2, the unit cooler 400 may be additionally provided, and when the unit cooler is additionally provided, the number of unit coolers is the same. The CDU unit is provided in such a way that a pipe consisting of an inlet pipe and a discharge pipe is connected to the unit cooler 400 in a cross structure to each of the regular CDU 320 and the spare CDU 340 constituting the CDU unit. I can.

When configuring the unit cooler 400 and the CDU unit in a multi-type as described above, a pipe consisting of an inlet pipe and a discharge pipe in each of the regular CDU 320 and the spare CDU 340 is connected to the unit cooler 400. By connecting it in a cross-linked structure, it is possible to expect an improvement in efficiency and the like in terms of operation.

In the configuration of the present invention, at least one temperature measurement sensor 500 is installed at a predetermined interval on an inner side of the refrigeration system. When two or more temperature measuring sensors 500 are installed, it is preferable to install them to be spaced apart from each other at regular intervals so that the temperature of the entire area of the storage space can be evenly measured.

Such a temperature measuring sensor can be configured in a block or plate shape, and unlike this, it can also be configured in a rod shape.

In the configuration of the present invention, the control unit 600 selectively controls the constant CDU 320 and the spare CDU 340 according to the value sensed by the temperature measurement sensor 500.

Referring to FIG. 3, the control unit includes: a comparison unit 620 for comparing a set temperature set by a user and a sensing temperature sensed by the temperature measurement sensor 500; Allows power to be applied to the spare CDU 340 when the sensing temperature exceeds a set temperature based on the comparison value derived by the comparison unit 620, and power is applied to the spare CDU 340 A control controller 640 that cuts off the power of the constant CDU 320; It may include a power supply unit 660 for supplying power to the control controller 640;

Here, the comparison unit 620 and the control controller 640 may separately include a microcomputer. At this time, the MICOM is preferably provided by programming together when designing the MICOM.

According to another embodiment of the present invention, as shown in FIG. 4, the temperature measurement sensor 500 and the control unit 600 may further include a wireless communication module.

The wireless communication module is wirelessly connected to a portable terminal possessed by an administrator, and provides a function of controlling each device provided in the cooling system as the portable terminal.

That is, the control unit 600 may control the overall data sensed and derived by the temperature measurement sensor 500 to be transmitted to the mobile terminal of the administrator by the wireless communication module. In this case, as a wireless communication technology applied to the wireless communication module, for example, WiFi, ZigBee, UWB, Bluetooth, Z-Wave, and the like may be used.

As described above, in the refrigeration system equipped with a single unit cooler and a spare refrigeration device of the present invention, the temperature of the entire refrigeration space is always uniformly operated by selectively operating the regular CDU and the spare CDU according to the temperature change of the storage space. It can be maintained, and even if the operation is stopped due to an abnormality in the regular CDU, by immediately operating the spare CDU, it is possible to prevent deterioration of the quality of the object due to extreme temperature changes in advance. By operating two CDUs, there is an advantage of improving overall efficiency such as refrigeration efficiency and space utilization.

100: compressor 300: CDU unit
320: regular CDU 340: spare CDU
400: unit cooler 410: blowing duct
412: fastening hole 420: bracket
430: motor 440: blowing fan
450: defrosting facility 460: net
452: damper 500: temperature measuring sensor
600: control unit 620: comparison unit
640: control controller 660: power supply

Claims (6)

In a refrigeration system in which a storage space is formed inside and the temperature of the storage space is maintained at a low temperature,
A compressor 100 installed in the storage space of the refrigeration system and compressing the supplied refrigerant and discharging it in a gaseous state of high temperature and high pressure;
It is installed in the storage space of the refrigeration system and connected to the compressor 100 by piping, and circulates the refrigerant compressed by the compressor 100 to exchange heat with the atmosphere. A configured CDU unit 300;
Pipes are connected to one side of the regular CDU 320 and the spare CDU 340 via a pair of pipes each consisting of an inlet pipe and a discharge pipe, and a blowing fan for cooling the inside of the storage space of the refrigeration system ( A unit cooler 400 having one or more 440;
A temperature measurement sensor 500 fixedly installed at least one inside the refrigeration system at a predetermined interval; And
Containing a control unit 600 for selectively controlling the constant CDU 320 and the spare CDU 340 according to the value sensed by the temperature measurement sensor 500,
On one side of the blowing fan 440 of the unit cooler 400, an ionizer dissipating member providing negative ions to the air volume by the blowing fan is installed,
The unit cooler 400 includes a cylindrical blowing duct 410 having a flange formed with a fastening hole 412 outside the front end and the rear end; A bracket 420 fixedly installed inside the rear surface of the blowing duct 410; A motor 430 that is rotated in a forward direction or a reverse direction by the application of a current while installed on the bracket 420; And a blowing fan 440 for discharging the cold air generated while being rotated while being fixedly coupled to the front end of the rotation shaft of the motor 430 to the outside of the front end of the blowing duct 410, and the inside of the flange A mesh body 460 in which a number of honeycomb-structured through holes are formed is provided,
A defrosting facility 450 for performing a defrosting operation by providing heat or hot water is provided on one side of the inner surface of the blowing duct 410, and the defrosting facility 450 opens or closes the flow path of the blowing duct 410. A refrigeration system provided with a single unit cooler and a spare refrigeration device, characterized in that it comprises a damper (452) operating in conjunction with the defrosting facility. The method of claim 1,
The control unit 600 includes: a comparison unit 620 for comparing a set temperature set by a user with a sensing temperature sensed by the temperature measuring sensor 500; Allows power to be applied to the spare CDU 340 when the sensing temperature exceeds a set temperature based on the comparison value derived by the comparison unit 620, and power is applied to the spare CDU 340 A control controller 640 that cuts off the power of the constant CDU 320; A refrigeration system including a single unit cooler and a spare refrigeration device, comprising: a power supply unit 660 for supplying power to the control controller 640. The method of claim 1,
When the unit cooler 400 is additionally provided, a CDU unit is provided in the same number as the number of unit coolers, but an inlet pipe to each of the constant CDU 320 and the spare CDU 340 constituting the CDU unit And a refrigeration system provided with a single unit cooler and a preliminary refrigeration device, characterized in that connecting the piping unit composed of a discharge pipe to the unit cooler 400 in a crossover structure. The method of claim 1,
The temperature measurement sensor 500 and the control unit 600 further include a wireless communication module, and the control unit 600 transmits the overall data sensed and derived by the temperature measurement sensor 500 by the wireless communication module. A refrigeration system equipped with a single unit cooler and a spare refrigeration device, characterized in that the control is transmitted to a mobile terminal of a manager. delete delete

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