CN110145917B

CN110145917B - Multi-temperature-zone refrigeration house system

Info

Publication number: CN110145917B
Application number: CN201810150806.7A
Authority: CN
Inventors: 李宁; 卢风禄; 师清木
Original assignee: China IPPR International Engineering Co Ltd
Current assignee: China IPPR International Engineering Co Ltd
Priority date: 2018-02-13
Filing date: 2018-02-13
Publication date: 2021-03-30
Anticipated expiration: 2038-02-13
Also published as: CN110145917A

Abstract

The invention discloses a multi-temperature-zone refrigeration house system, which comprises a refrigerating unit; the system comprises a first cold storage tank, a second cold storage tank, a third cold storage tank, a fourth cold storage tank, a quick freezing warehouse, a cold storage warehouse and a fresh-keeping warehouse; the refrigerating unit provides cold accumulation liquid for the first cold accumulation tank, the first cold accumulation tank is connected with the quick freezing warehouse through a first cold accumulation pipeline, the second cold accumulation tank is connected with the freezing warehouse through a second cold accumulation pipeline, the third cold accumulation tank is connected with the cold freezing warehouse through a third cold accumulation pipeline, and the fourth cold accumulation tank is connected with the fresh-keeping warehouse through a fourth cold accumulation pipeline; and the quick-freezing warehouse is connected with the second cold accumulation tank through a first liquid return pipeline, the freezing warehouse is connected with the third cold accumulation tank through a second liquid return pipeline, the cold storage warehouse is connected with the fourth cold accumulation tank through a third liquid return pipeline, and the fresh-keeping warehouse is connected with the first cold accumulation tank through a fourth liquid return pipeline. By adopting the invention, the mode conversion of each system can be flexibly carried out, and the mode conversion of each refrigeration house temperature zone can be flexibly carried out.

Description

Multi-temperature-zone refrigeration house system

Technical Field

The invention relates to a refrigeration storage system, in particular to a multi-temperature-zone refrigeration storage system.

Background

The traditional refrigeration mode of the refrigeration house is that each refrigeration house corresponds to one or more refrigeration unit, each refrigeration house corresponds to one refrigeration mode or refrigeration temperature, the temperature interval is a fixed mode, and the refrigeration mode can not be changed into other temperature areas and can not be changed into other purposes. When seasonal changes need other temperature zone banks, there is no other way except for building. Moreover, the whole refrigeration pipeline is a high-pressure pipeline, so that the investment limit is large and the later maintenance is difficult. Fig. 1A to 1E are schematic diagrams of a refrigeration storage system in the prior art, as shown in fig. 1A, a-65 to-45 ℃ ultra-low temperature/quick-freeze storage 502 is independently controlled by a refrigerating unit 500, the refrigerating unit 500 exchanges heat with the-65 to-45 ℃ ultra-low temperature/quick-freeze storage 502 through a refrigerating heat exchanger 501, and the whole area is a pressure-bearing area. As shown in figure 1B, a-25 to-18 ℃ freezer 503 is independently controlled by a refrigerating unit 500, the refrigerating unit 500 exchanges heat with the-25 to-18 ℃ freezer 503 through a refrigerating heat exchanger 501, and the whole area is a pressure-bearing area. As shown in fig. 1C, the 0-10 ℃ cold preservation 504 is independently controlled by one refrigerating unit 500, the refrigerating unit 500 exchanges heat with the 0-10 ℃ cold preservation 504 through a refrigerating heat exchanger 501, and the whole area is a pressure-bearing area. As shown in fig. 1D, the 0-15 ℃ refrigerator 505 is controlled by one refrigerating unit 500, the refrigerating unit 500 exchanges heat with the 0-15 ℃ refrigerator 505 through a refrigerating heat exchanger 501, and the whole area is a pressure-bearing area. As shown in fig. 1E, the office area 506 at 0-15 ℃ is independently controlled by one refrigeration unit, the refrigeration unit 500 exchanges heat with the office area 506 at 0-15 ℃ through the refrigeration heat exchanger 501, and the whole area is a pressure-bearing area.

It can be seen that: the existing refrigeration house system increases the cold load along with the cold loss of goods in and out, and in order to adjust the load, the refrigeration host machine needs to be frequently started, so that the refrigeration host machine runs under the severe working condition, the efficiency is low, and the service life of the refrigeration host machine is shortened due to frequent starting and stopping of the refrigeration host machine. Frequent starting of the refrigeration host machine also causes discontinuous cooling process and long cooling time, which is not beneficial to accurately controlling the temperature of the warehouse. In order to maintain the temperature of the storage, the refrigeration main machine operates in a low-load state with low energy efficiency for a long time, so that the operation efficiency of the refrigeration unit becomes low, but the refrigeration unit does not operate in an optimal efficiency state, and further the load peak-valley difference is large.

The evaporator is prone to non-uniform frost due to large temperature load change, and the system load is increased after a defrosting period. Meanwhile, the peak regulation capacity of the refrigeration house under the existing condition is weak, the compressors are all configured according to the maximum load, and the load efficiency of the refrigeration host is low due to energy regulation, such as hot gas bypass and the like, under the condition of partial load.

In addition, in the conventional technology, the temperature interval for each refrigerator is constant, and cannot be changed to a temperature interval for other purposes. When a plurality of storehouses are used, the number of refrigerating units is large, and the cost is high.

In addition, the refrigeration pipeline of the whole storage area is a high-pressure pipeline, and the range of the high-pressure pipeline is too wide, so that the high-pressure pipeline is not beneficial to fire fighting and maintenance. Once leakage occurs, the refrigerator cannot be maintained through a rapid means, and the use of the whole refrigerator is further influenced; and leakage of refrigerant is liable to cause danger.

Meanwhile, the traditional air cooling refrigeration mode has high energy consumption and cost, large dry consumption of stored commodities and no guarantee on quality. The air cooler cooling system and the automatic defrosting derived from the air cooler cooling system are the main sources of frequent and large fluctuation of the temperature of the refrigeration house.

Disclosure of Invention

The invention aims to provide a multi-temperature-zone refrigeration system to overcome the defects that the refrigeration load of a multi-warehouse multi-machine refrigeration house system is increased and the operation efficiency of a refrigeration host is low in the prior art.

In order to achieve the above object, the present invention provides a multi-temperature-zone refrigeration storage system, comprising:

a refrigeration unit;

the system comprises a first cold accumulation tank, a second cold accumulation tank, a third cold accumulation tank and a fourth cold accumulation tank;

a quick-freezing warehouse;

a freezer;

a refrigerator;

a fresh-keeping warehouse;

the refrigerator set provides cold accumulation liquid for a first cold accumulation tank, the first cold accumulation tank is connected with the quick freezer through a first cold accumulation pipeline a, the second cold accumulation tank is connected with the freezer through a second cold accumulation pipeline b, the third cold accumulation tank is connected with the refrigerator through a third cold accumulation pipeline c, and the fourth cold accumulation tank is connected with the fresh-keeping warehouse through a fourth cold accumulation pipeline d; and the quick-freezing warehouse is connected with the second cold accumulation tank through a first liquid return pipeline e, the freezing warehouse is connected with the third cold accumulation tank through a second liquid return pipeline f, the cold storage warehouse is connected with the fourth cold accumulation tank through a third liquid return pipeline g, and the fresh-keeping warehouse is connected with the first cold accumulation tank through a fourth liquid return pipeline h.

Preferably, the multi-temperature-zone refrigeration house system further comprises an office area, and the fourth cold accumulation tank is connected with the office area through a fourth cold accumulation pipeline d; the office area is connected with the first cold accumulation tank through a fourth liquid return pipeline h.

Preferably, the second cold accumulation tank is connected with the first cold accumulation tank after being converged by a fifth liquid return pipeline i and a fourth liquid return pipeline h.

Preferably, the third cold accumulation tank is connected with the first cold accumulation tank after being converged by a sixth liquid return pipeline j and the fourth liquid return pipeline h.

Preferably, the first cold accumulation pipeline a, the second cold accumulation pipeline b, the third cold accumulation pipeline c and the fourth cold accumulation pipeline d are respectively connected with a circulating pressure pump.

Preferably, the first cold storage tank is a cold storage tank at the temperature of-65 to-45 ℃; the second cold storage tank is a cold storage tank at the temperature of-35 to-18 ℃; the third cold accumulation tank is a cold accumulation tank at the temperature of-18-0 ℃; the fourth cold accumulation tank is a cold accumulation tank at the temperature of 0-15 ℃.

Preferably, the refrigeration unit comprises a main refrigeration unit and an auxiliary refrigeration unit, and the main refrigeration unit is connected with the auxiliary refrigeration unit in parallel.

Preferably, the areas where the first cold storage tank, the second cold storage tank, the third cold storage tank and the fourth cold storage tank are located are normal pressure pipeline areas.

Preferably, the number of the quick-freezing storehouses, the number of the cold storages, the number of the fresh-keeping storehouses and the number of the office areas are one or more respectively.

Preferably, the quick-freezing storage, the refrigerating storage and the fresh-keeping storage can be changed into any one of temperature zone modes of the quick-freezing storage, the refrigerating storage and the fresh-keeping storage, and when an office area is included, the office area can be changed into any one of temperature zone modes of the quick-freezing storage, the refrigerating storage and the fresh-keeping storage.

The multi-temperature-zone refrigerating system has the following technical effects:

1. mode conversion of each system can be flexibly carried out, mode conversion is flexibly carried out according to requirements of different seasons on the temperatures of different temperature zone storehouses, the system can be changed into an ultra-low temperature storehouse and a high temperature storehouse, and investment is not increased.

2. The cooling distribution can be carried out according to the requirements of each refrigeration house.

3. The cold accumulation liquid can be recycled in each refrigeration house and cold accumulation tank, and a stable cold supply mode is formed.

4. The defrosting phenomenon can not be caused.

5. The dry consumption of the stored commodities is low.

6. The multi-temperature-zone refrigeration house system does not need to be started frequently, and the energy consumption of the system is low.

7. In the emergency mode for coping with power failure, when the external network fails, only power needs to be supplied to the circulating pressure pump, and the cold storage liquid in the cold storage tank is used for circulating, so that the constant storage temperature can be ensured for a long time.

8. The large system of the whole refrigerating system is driven by one refrigerating unit.

Drawings

Fig. 1A to 1E are schematic diagrams of a prior art freezer refrigeration system;

FIG. 2 is a schematic diagram of a multi-temperature zone refrigeration system of the present invention;

fig. 3 is a schematic diagram of the change of the refrigeration storage temperature zone of the multi-temperature-zone refrigeration storage system of the invention.

Wherein, the reference numbers:

100. refrigerating unit

101. Main refrigerating unit

102. Auxiliary refrigerating unit

200. Refrigeration heat exchanger

110. First cold accumulation tank

120. Second cold accumulation tank

130. Third cold accumulation tank

140. Fourth cold accumulation tank

150. Quick-freezing warehouse

160. Refrigerator

170. Refrigerator with a door

180. Fresh-keeping storehouse

190. Office area

a. First cold accumulation pipeline

b. Second cold accumulation pipeline

c. Third cold accumulation pipeline

d. Fourth cold accumulation pipeline

e. First liquid return pipeline

f. Second liquid return pipeline

g. Third liquid return pipeline

h. Fourth liquid return pipeline

i: fifth liquid return pipeline

j: sixth liquid return pipeline

1. 20, 30, 40 circulating booster pump

Detailed Description

The multi-temperature-zone refrigeration house system provided by the invention is different from the traditional refrigeration house refrigeration mode, a single-machine multi-chamber multi-temperature-zone mode is adopted, all temperature zones can be changed into the required temperature zone mode according to the needs, namely, the freezing, refrigeration, fresh-keeping and other temperature zones can be mutually converted, and the system can be a freezing chamber, a refrigerating chamber, a fresh-keeping chamber, a part of freezing chamber, a part of refrigerating chamber, a part of fresh-keeping chamber and the like; all modes can be arbitrarily switched at any time. If an office system exists, a refrigeration mode and a heating mode can be provided for the office environment, and the usability of the system is greatly improved.

Fig. 2 is a schematic view of the multi-temperature-zone refrigeration system of the present invention, and as shown in fig. 2, the multi-temperature-zone refrigeration system of the present invention may include: a refrigerating unit 100, a first cold-storage tank 110, a second cold-storage tank 120, a third cold-storage tank 130, a fourth cold-storage tank 140, a quick-freezing warehouse 150, a freezing warehouse 160, a cold storage 170, a fresh-keeping warehouse 180, and an office area 190; the first cold storage tank 110 is a cold storage tank at-65 to-45 ℃; the second cold storage tank 120 is a cold storage tank at-35 to-18 ℃; the third cold storage tank 130 is a cold storage tank at-18 to 0 ℃; the fourth cold accumulation tank 140 is a cold accumulation tank at 0 to 15 ℃. The refrigerating unit 100 provides the first cold accumulation tank 110 with the cold accumulation liquid, and the first cold accumulation tank 110 is connected with the quick-freezing warehouse 150 through a first cold accumulation pipeline a, so that the first cold accumulation tank 110 provides the cold accumulation liquid to the quick-freezing warehouse 150 through the first cold accumulation pipeline a; the second cold accumulation tank 120 is connected with the freezer 160 through a second cold accumulation pipe b, so that the second cold accumulation tank 120 provides cold accumulation liquid to the freezer 160 through the second cold accumulation pipe b; the third cold storage tank 130 is connected to the refrigerator 170 through a third cold storage pipe c, so that the third cold storage tank 130 provides the cold storage liquid to the refrigerator 170 through the third cold storage pipe c; the fourth cold accumulation tank 140 is connected with the fresh keeping warehouse 180 and the office area 190 through a fourth cold accumulation pipeline d, so that the fourth cold accumulation tank 140 provides cold accumulation liquid for the fresh keeping warehouse 180 and the office area 190 through the fourth cold accumulation pipeline d; the quick-freezing storage 150 is connected with the second cold storage tank 120 through a first liquid return pipeline e, so that the quick-freezing storage 150 can return the cold storage liquid to the second cold storage tank 120 through the first liquid return pipeline e; the freezer 160 is connected to the third cold storage tank 130 through a second liquid return pipe f, so that the freezer 160 returns the cold storage liquid to the third cold storage tank 130 through the second liquid return pipe f; the refrigerator 170 is connected to the fourth cold storage tank 140 through a third liquid return pipe g, so that the refrigerator 170 returns the cold storage liquid to the fourth cold storage tank 140 through the third liquid return pipe g; the fresh-keeping warehouse 180 and the office area 190 are connected with the first cold storage tank 110 through a fourth liquid return pipeline h, so that the fresh-keeping warehouse 180 and the office area 190 return the cold storage liquid to the first cold storage tank 110 through the fourth liquid return pipeline h.

The office area 190 can be set as required, and when there is a cooling demand of the central air conditioner in the office area, the refrigeration storage system can contain the office area 190 and can provide low-temperature liquid to the office area 190 conveniently. The residual cold quantity after all the cold storage areas are used up can be used as the cold quantity of the central air conditioner to be provided for office areas.

In a preferred embodiment of the present invention, the first cold storage pipeline a, the second cold storage pipeline b, the third cold storage pipeline c and the fourth cold storage pipeline d are respectively connected with a circulating pressure pump. When the temperature zone needs to be accurately controlled, the temperature can be accurately controlled by adjusting the flow speed and the flow of the circulating booster pump, and the accurate temperature adjustment of + -0.1 ℃ is realized. Such as: the flow speed and the flow of the cold accumulation liquid are adjusted by adjusting the circulating pressure pump 1 on the first cold accumulation pipeline a so as to control the temperature of the quick-freezing warehouse 150; the temperature of the freezer 160 is controlled by adjusting the flow rate and the flow rate of the cold storage liquid by adjusting the circulation pressure pump 20 on the second cold storage pipe b; the temperature of the refrigerator 170 is controlled by adjusting the flow rate and the flow rate of the cold storage liquid by adjusting the circulation pressure pump 30 on the third cold storage pipe c; the flow speed and the flow of the cold storage liquid are adjusted by adjusting the circulating pressure pump 40 on the fourth cold storage pipeline d to control the temperature of the fresh-keeping warehouse 180 and the office area 190, and then all the cold storage temperature areas can be arbitrarily changed into the required temperature area modes according to the requirements, and all the temperature areas such as freezing, refrigerating, fresh keeping and the like can be mutually converted.

When the system is initially put into use, the cold accumulation liquid in the first refrigerating tank is refrigerated through the refrigerating unit, and when the temperature of the cold accumulation liquid reaches the temperature required by the first cold accumulation tank, the cold accumulation liquid enters the corresponding quick freezing chamber through the circulating pressure pump, and returns to the second cold accumulation tank through the quick freezing chamber. Similarly, when any cold storage tank reaches the required temperature, the cold storage liquid is input into the corresponding cold storage warehouse through the circulating pressure pump, and then the cold storage liquid is returned to the cold storage tank with the next high temperature through the cold storage warehouse, so that the cold storage tank to be used is filled with the cold storage liquid and reaches the required temperature.

In a preferred embodiment of the present invention, the second cold storage tank 120 can be collected by the fifth liquid return pipe i and the fourth liquid return pipe h and then connected to the first cold storage tank 110, so that the cold storage liquid in the second cold storage tank 120 can flow back to the first cold storage tank 110. The third cold storage tank 130 can be connected to the first cold storage tank 110 after being converged by the sixth liquid return pipe j and the fourth liquid return pipe h, so that the cold storage liquid in the third cold storage tank 130 can flow back to the first cold storage tank 110.

In the preferred embodiment of the present invention, the present invention can be driven by one main refrigerating unit and one auxiliary refrigerating unit. As shown in fig. 2, the refrigeration unit 100 may include a main refrigeration unit 101 and an auxiliary refrigeration unit 102, the main refrigeration unit 101 is connected in parallel with the auxiliary refrigeration unit 102, the main refrigeration unit 101 performs refrigeration at full power, when the temperature of the whole cold storage tank reaches, the main refrigeration unit 101 may be turned off when the refrigeration demand is low and the amount of return liquid is small, and the auxiliary refrigeration unit 102 may be turned on to perform refrigeration maintenance, so as to reduce the refrigeration power consumption of the system. The refrigeration unit 100 (the main refrigeration unit 101 and the auxiliary refrigeration unit 102) can exchange heat with the first cold storage tank 110 through the refrigeration heat exchanger 200. When the requirement for cold energy is not large, the refrigeration main machine is closed, the refrigeration maintaining auxiliary machine is started to maintain the temperature of the cold-carrying liquid, and the energy consumption of the whole system is maintained at an extremely low level.

Fig. 3 is a schematic diagram illustrating the replacement of the temperature zones of the refrigerator in the multi-temperature-zone refrigerator system of the present invention, as shown in fig. 3, the refrigerator in the multi-temperature-zone refrigerator system of the present invention can be divided into different temperature zones according to the requirement, such as: the temperature zones of the quick-freezing warehouse 150, the freezing warehouse 160, the cold storage 170, the fresh-keeping warehouse 180 and the office area 190 (shown as the line L in fig. 3) can be changed as required, and can be adjusted into other temperature zone ranges as required, and furthermore, the temperature zone ranges of the quick-freezing warehouse 150, the freezing warehouse 160, the cold storage 170, the fresh-keeping warehouse 180 and the office area 190 can be adjusted by keeping the original type of the cold storage, and can be changed into any one of the temperature zone modes of the quick-freezing warehouse, the fresh-keeping warehouse of the cold storage and the office area 190. Such as: the quick-freezer 150, the freezer 160, the refrigerator 170, the fresh food warehouse 180, and the office area 190 may be simultaneously changed to the quick-freezer (e.g., line L1 in fig. 3), the freezer (e.g., line L2 in fig. 3), the refrigerator (e.g., line L3 in fig. 3), or the fresh food warehouse (e.g., line L4 in fig. 3), as needed; in other words, according to different seasons or production requirements, all the refrigerators and the freezers can freely change modes at any time, when the freezers are needed, all the refrigerators can be changed into the freezers, and when the freezers are needed, all the freezers can be changed into the refrigerators, all the refrigerators can be mutually changed according to the requirements, and therefore the flexibility of the operation of the refrigerator system and the flexibility of the operation of the refrigerator system in response to sudden requirements are improved.

In the preferred embodiment of the present invention, the multi-temperature zone freezer system of the present invention uses a single refrigerating unit to refrigerate the freezer 150, the freezer 160, the refrigerator 170, the fresh-keeping warehouse 180 and the office area 190, and the types of the refrigerating temperature zones that can be realized at the same time include, but are not limited to: the system comprises an ultralow temperature tuna storeroom (below minus 60 ℃), a quick-freezing storeroom (below minus 25-45 ℃), a freezing storeroom (18-25 ℃), a cold storeroom (0-5 ℃), a fresh-keeping storeroom (below minus 5-15 ℃), a central air conditioner (cold) (10-15 ℃) in an office area and a central air conditioner (hot) (40-80 ℃), wherein the quick-freezing storeroom 150 can be converted into an ultralow temperature tuna storeroom (below minus 60 ℃) temperature region, and the central air conditioner (cold) (10-15 ℃) in the office area can be converted into a central air conditioner (hot) (40-80 ℃) temperature region as required.

In a preferred embodiment of the present invention, the areas where the first, second, third and fourth

cold accumulation tanks

110, 120, 130 and 140 are located are normal pressure pipeline areas, and only the area where the refrigeration unit is located is a pressure-bearing pipeline area, that is, the pipelines in the whole refrigeration area are normal pressure systems, and no high pressure system is provided in the refrigeration area, so that the system construction cost and the later maintenance cost are greatly reduced. The refrigeration host works at the maximum efficiency value, and the low-load state of frequent start-stop and low energy efficiency is thoroughly avoided.

The multi-temperature-zone refrigeration house system of the invention refrigerates a plurality of refrigeration houses through one refrigeration unit, and the cold storage liquid can circulate in the refrigeration houses and the cold storage tanks. The refrigeration host of the refrigeration system can accumulate cold energy by adopting a full-power working mode, and the refrigeration host only needs full load to refrigerate the first cold accumulation tank. When needed, the cold accumulation liquid is conveyed to an evaporator of the refrigeration house through the circulating pressure pump, and the return liquid enters the tank body with high temperature. The peak regulation capability of the system is strong. The evaporator has small temperature load change, is not easy to frost, and can greatly prolong the defrosting period.

In addition, the multi-temperature-zone refrigerating system of the invention refrigerates a plurality of cold storages through one refrigerating unit, and the number and the size of the driven refrigerating cold storages can be increased and decreased at any time according to needs, for example, the number of the quick-freezing storages, the number of the refrigerating cold storages, the number of the fresh-keeping storages and the number of the office areas can be respectively one or more. And all temperature area storehouses can be changed into the required temperature area range and temperature area modes at will according to requirements, namely, the temperature areas of the quick-freezing storehouses, the cold storages, the fresh-keeping storehouses and the like can be mutually converted. Moreover, any maintenance separation of the storeroom does not influence the stable operation of the whole system. The whole dangerous area of the core system is reduced from the original range of thousands of square meters and tens of thousands of square meters to dozens of hundred square meters.

Meanwhile, the multi-temperature-zone refrigeration house system can utilize solar power generation, wind power generation and peak-valley power to carry out full-power refrigeration and cold loading. The cold energy accumulated in the daytime is used for refrigerating the refrigeration house by the circulating pressure pump at night. Once the external network is powered off accidentally, a small portable generator can be used for supplying power to perform cooling circulation, and the temperature of the refrigeration house is ensured to be constant. When the power failure time of the main power supply network is longer due to an accident condition, the whole system can keep the temperature of the cold storage warehouse constant for a longer time by depending on the cold energy accumulated in the cold carrying tank.

The system adopts a top calandria mode, can provide a stable temperature field for each temperature area refrigeration house, has low energy consumption and small dry consumption, and can constantly provide continuous cold supply for the refrigeration house system.

The present invention is capable of other embodiments, and various changes and modifications may be made by one skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims.

Claims

1. A multi-temperature-zone refrigeration storage system, comprising:

a refrigeration unit;

a quick-freezing warehouse;

a freezer;

a refrigerator;

a fresh-keeping warehouse;

the refrigerator set provides cold accumulation liquid for a first cold accumulation tank, the first cold accumulation tank is connected with the quick freezer through a first cold accumulation pipeline a, the second cold accumulation tank is connected with the freezer through a second cold accumulation pipeline b, the third cold accumulation tank is connected with the refrigerator through a third cold accumulation pipeline c, and the fourth cold accumulation tank is connected with the fresh-keeping warehouse through a fourth cold accumulation pipeline d; the quick-freezing chamber is connected with the second cold accumulation tank through a first liquid return pipeline e, the freezing chamber is connected with the third cold accumulation tank through a second liquid return pipeline f, the cold storage chamber is connected with the fourth cold accumulation tank through a third liquid return pipeline g, and the fresh-keeping chamber is connected with the first cold accumulation tank through a fourth liquid return pipeline h;

the second cold accumulation tank is connected with the first cold accumulation tank after being converged with the fourth liquid return pipeline h through a fifth liquid return pipeline i;

the third cold accumulation tank is connected with the first cold accumulation tank after being converged with the fourth liquid return pipeline h through a sixth liquid return pipeline j;

the first cold accumulation pipeline a, the second cold accumulation pipeline b, the third cold accumulation pipeline c and the fourth cold accumulation pipeline d are respectively connected with a circulating pressure pump, and the flow speed and the flow of cold accumulation liquid are adjusted by adjusting the circulating pressure pump on the first cold accumulation pipeline a so as to control the temperature of the quick freezing warehouse; the flow speed and the flow of the cold accumulation liquid are adjusted by adjusting a circulating pressurization pump on the second cold accumulation pipeline b so as to control the temperature of the freezer; the flow speed and the flow of the cold accumulation liquid are adjusted by adjusting a circulating pressure pump on the third cold accumulation pipeline c so as to control the temperature of the refrigerator; the flow speed and the flow of the cold accumulation liquid are adjusted by adjusting a circulating pressure pump on the fourth cold accumulation pipeline d so as to control the temperature of the fresh-keeping storehouse and the office area;

the first cold accumulation tank, the second cold accumulation tank, the third cold accumulation tank and the fourth cold accumulation tank are located in normal pressure pipeline areas.

2. The multi-temperature zone cold storage system according to claim 1, wherein the fourth cold accumulation tank is connected to the office area through a fourth cold accumulation pipeline d; the office area is connected with the first cold accumulation tank through a fourth liquid return pipeline h.

3. The multi-temperature zone freezer system of claim 1, wherein the first cold storage tank is a-65 to-45 ℃ cold storage tank; the second cold storage tank is a cold storage tank at the temperature of-35 to-18 ℃; the third cold accumulation tank is a cold accumulation tank at the temperature of-18-0 ℃; the fourth cold accumulation tank is a cold accumulation tank at the temperature of 0-15 ℃.

4. The multi-temperature-zone refrigeration storage system according to claim 1, wherein the refrigeration unit comprises a main refrigeration unit and an auxiliary refrigeration unit, and the main refrigeration unit and the auxiliary refrigeration unit are connected in parallel.

5. The multi-temperature-zone freezer system of claim 2, wherein the freezer, the refrigerator, the fresh food compartment, and the office area are one or more of each.

6. The multi-temperature-zone freezer system according to any one of claims 1 to 5, wherein the quick freezer, the refrigerator and the fresh food compartment are each changeable to any one of temperature zone modes of the quick freezer, the refrigerator and the fresh food compartment, and when an office area is included, the office area is changeable to any one of temperature zone modes of the quick freezer, the refrigerator and the fresh food compartment.