DE29722052U1 - Transport container cooling system - Google Patents

Description

Transport container cooling system

The invention relates to a cooling system to which transport containers can be connected and charged with cold.

/ Similar cooling systems are possible using solid sorption units

known in which the refrigerant circuit is separated after ice production in a mobile evaporator . !

EP 0 577 869 A1 describes a cooling system in which, by means of a solid sorption unit, a water supply can be frozen in a double-walled container of a mobile cooling container that is only docked temporarily. In addition to the sorbent container, the cooling system has a vacuum-tight working medium vapor collection line to which evaporators for a working medium, e.g.

as an aggregate of a transport container, can be docked and undocked. A vacuum pump is also required for operation in order to generate a sufficient vacuum after each docking and undocking process when using zeolite as a sorbent and water as a working medium, so that part of the water can evaporate at low temperatures and the rest can freeze. Due to the high melting enthalpy of the ice of 334 kj/kg, if the double-walled container is designed accordingly, it then represents a heat sink for several hours, with the help of which refrigerated goods can be stored and transported at almost constant temperatures just above the freezing point without the need for the supply of energy. The process requires, on the one hand, a vacuum for freezing well below the triple point pressure of 6.11 mbar and, on the other hand, a very high level of equipment expenditure for the sorbent containers with integrated heat exchangers for coupling and decoupling desorption and adsorption enthalpy, as well as very complex control and regulation. The cooling system is susceptible to failure simply because of the constantly necessary vacuum-tightness of the connections and the regular re-evacuation of the coolant circuit (collecting line and sorbent container). And even with an optimal design of the system, the freezing time and thus the storage time for the cold energy is long, and the energy consumption is high due to the low cooling-heat ratio caused by the process.

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Furthermore, rolling serving carts for food - so-called trolleys - are known from aviation, which are either cooled for longer periods with dry ice or for a short time with solid aluminum inner walls that are heavily sub-cooled in circulating air refrigerators. While the dry ice variant is energy-intensive and therefore cost-intensive and also causes an excessively high CO2 concentration in the aircraft interior, the cooling is due to the low specific heat capacity of aluminum from

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only 0.896 kJ/(kg-K) can only be used for a short time.

The object of the present invention is to realize a transport container cooling system in the normal cooling and deep-freezing range with short cold storage times and long cooling times as well as simple cold recharging after partial discharge, low equipment and control technology expenditure and low energy consumption.

This problem is solved by the characterizing features of claim 1.

The subclaims reflect further advantageous embodiments.

In the transport container cooling system according to the invention, in which transport containers are connected to a cooling system and charged with cold, the cold is produced in a stationary or mobile binary ice producer and pumped as liquid ice via a feed line system into binary ice storage units connected to it in mobile transport containers. It passes through these binary ice storage units while displacing water already used for cooling purposes (i.e. melted binary ice) and is returned to the binary ice producer via a feed line system, with the pumping process being controlled depending on time, quantity or temperature.

The binary ice generator used according to the invention is a unit known from supermarket display case cooling systems, which uses cold vapor compression technology and environmentally friendly refrigerants to produce a suspension of the finest ice crystals, water and a freezing point-lowering substance (e.g. table salt). The freezing point of this pumpable ice is -1 to -40 ⁰ C, and the specific melting enthalpy can be set to values above 300 kJ/kg depending on the freezing point-lowering substance.

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The invention divides the coolant circuit after ice, in which very large amounts of cold are stored, has been pumped to a consumer. The previous approach to solving the problem of cooling transport containers, the technically critical division of the coolant circuit, is thereby broken.

To control the pumping process, in one design the temperatures in the feed and discharge pipe systems are measured and compared, and the pumping cycle is stopped when the temperatures are almost the same. The temperatures in the feed pipe system are measured between the circulation pump and the first transport container connection and in the discharge pipe system after the outlet from the binary ice storage of the transport containers or before entering the binary ice generator. ^

In other design variants, the filling of the binary ice storage tanks of the transport containers is regulated by means of a flow volume counter for the binary ice or by a filling time measurement.

The binary ice producer produces binary ice at the desired temperature and melting enthalpy. A circulation pump pumps the binary ice through a flow line system into a binary ice storage tank in the respective transport container, which is docked to the flow line system using an automatic device. Within a few minutes, a container is filled with binary ice and can be undocked. It can then keep refrigerated goods at a constant temperature for several hours, which can be adjusted using the freezing point lowering substance; this means that normal refrigeration containers just above freezing point and deep-freeze containers in the range below -20 ⁰ C can be operated with cold. After the ice has melted, the transport container can be docked again to the same or another binary ice producer and charged with cold. It is also possible for a transport container to be operated for some time in stationary cooling mode on a binary ice producer.

Mobile binary ice generators are also intended to be installed in land, water or air vehicles, preferably directly or near cooling consumers, e.g. on-board kitchens. In addition to the connections for the binary ice storage units of the

Additional stationary cooling consumers can be connected to the mobile transport container via a separate supply and discharge line system.

Transport containers within the meaning of the invention can also be delivery vehicles for chilled foodstuffs, the respective cooling chamber of which has a binary ice storage unit,

which is connected in the manner described to a supply and discharge line system of a /

Binary ice generator can be docked and undocked and filled with binary ice.

The invention will be explained with reference to the drawing. It shows.

Fig. 1: the transport container cooling system and

Fig. 2: the transport container cooling system with additional stationary

cooling consumers.

The drawing shows advantageous embodiments of the inventive ideas:

A binary ice generator 1 is connected to a feed line system 2 and a feed line system 3. Pipelines with small cross-sections can be used for the feed line and the feed line system. The binary ice 10, whose temperature is monitored by a thermocouple 14, is pumped through the feed line system 2 by a circulation pump 4. A binary ice storage tank 7 of the transport container 8 is connected to this by means of an automatic coupling 6. The binary ice 10 is pumped into the double-walled binary ice storage tank 7 when the valve 5 is open. The binary ice storage tank 7 is thermally insulated from the outside and cools the goods to be stored via the inner wall. In a preferred embodiment, the binary ice storage tank 7 is designed as a labyrinth in order to prevent binary ice short circuits from the inlet to the outlet.

The after-run temperature is monitored by means of a thermocouple 13, which is located at the end of the after-run line in front of the storage tank of the binary ice generator 1. If the temperatures at the inlet and outlet are identical or almost identical, the filling process with binary ice and thus the cold storage is considered complete and the valve 5 is closed again. It is also possible to install temperature sensors in each transport container in order to determine the temperature and thus the charge level of the binary ice individually. As a result,

further transport containers 11, 12 etc. are filled with binary ice in the same way.

The loaded transport containers can then be loaded with refrigerated goods and cool them during a transport lasting several hours. They can be transported back to binary/ice generator 1 for recharging. However, they can also be connected to another binary ice generator at another location and cooled there.

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recharged with cold or supplied with cold in a stationary manner. Additional stationary cold consumers 16, such as bottle and flow coolers as well as cooled display cases etc., can be connected to this other binary ice producer, which is located in the galley of train restaurants, ships or aircraft, for example, via another supply line system 15 and can be tempered using commercially available temperature control technology.

Claims (8)

Protection claims 1. Transport container cooling system consisting of mobile transport containers that are connected to a cooling system and charged with cold, characterized in that / ■ / _{Î t} j ■ ! a stationary or a mobile binary ice generator (1) via a flow ■ and follow-up line system (2, 3 j with connectable to these line systems Binary ice storage (7) of the mobile transport container (8) and a time-, quantity- or temperature-dependently controlled circulation pump (4) for liquid ice is arranged in the ■ feed line system (2). 2. Transport container cooling system according to claim 1, characterized in that the binary ice generator (1) has a storage facility. 3. Transport container cooling system according to claim 1, characterized in that for temperature-dependent control of the circulation pump (4), measuring points (13,14), preferably thermocouples, are provided in the feed line system (2) between the circulation pump (4) and the first transport container connection (6) and in the feed line system (3) before entering the binary ice generator (1). - 4. Transport container cooling system according to claim 1, characterized in that to control the circulation pump ( 4) Volume counters are provided for measuring the volume of binary ice in the flow line system (2) or a time measuring device is used to limit the operating time of the circulation pump (4). 5. Transport container cooling system according to claim 1, characterized in that the binary ice storage (7) in the transport containers (8) is designed as a labyrinth. . -■·..■ 6. Transport container cooling system according to claim 1, characterized in that the mobile binary ice generator (J) in land, water or air vehicles, I is preferably located directly in or near cooling consumers. 10 7. Transport container cooling system according to claim 1 and 6, characterized in that the binary ice producer (1) in land, water or air vehicles has, in addition to the connections for the binary ice storage (7) of the mobile transport containers (8), a separate supply line system (15) to stationary cooling consumers (16). 8. Transport container cooling system according to claim 1, characterized in that the transport containers (8, 11, 12) are delivery vehicles for chilled food, the respective cooling chamber of which has a binary ice storage unit (7) which can be docked and undocked via connections to a feed and feed line system (2, 3) of a binary ice producer (1) and can be filled with binary ice.