SE446480B - Transport units for refrigerated storage with central cooling unit - Google Patents

Abstract

Device for refrigerated storage, especially for storage during transport from one or more central locations to usage locations for local storage. The device comprises a number of transports units, such as cooling boxes (2), with storage space. Each transport unit (2) contains reservoir space, which is designed to be filled with a cooling agent of the type that becomes at least partially frozen but can still be pumped at a low temperature. The cooling agent can maintain this state almost constant until it has completely assumed a liquid state. The reservoir space is enclosed by a jacket, which is equipped with outer insulation as well as insulation facing the storage space of the transport unit. The insulation facing the reservoir space is broken to bring the jacket in thermal contact with the storage space. The reservoir space for cooling agent has a number of outer connections. The device also comprises a central, preferably stationary cooling unit (1) with a reservoir (8) for the cooling agent as well as cooling devices (11, 15) for the cooling agent and connection bodies (21, 23) for the outer connections of the transport units (2). Transport devices (18, 19, 20, 22) like lines and pumps are located between the cooling agent reservoir (8) and the connecting bodies (21, 23) so that the cooled agent (9) can be transferred via the transport unit connections and the cooling unit (1) connecting bodies (21, 23) to the transport units' reservoir space while warmed agent is removed from the same. This allows the storage space of the transport unit to be kept cool while the cooling agent assumes its liquid state.<IMAGE>

Description

Said object is achieved by means of a device according to the characterizing part of the appended claim 1.

The invention will be described in the following by two embodiments with reference to the accompanying drawings, in which Fig. 1 shows a schematic side projection of a stationary cooling unit and a portable cooling unit applied to the cooling unit in the form of a cooling box, which is shown in phantom form; Fig. 2 shows a section of the cooling box; Fig. 3 shows a section along the line III-III in Fig. 2; Fig. 4 shows a section along the line IV-IV in Fig. 3; and Fig. 5 shows a partial view of the edge portion of the cooling box and with respect to the second embodiment.

As can be seen from Fig. 1, the device according to the present invention has two main components, namely a larger stationary cooling unit 1 and a number of cooling boxes 2. The cooling unit 1 is preferably arranged for stationary use.

The cooling boxes 2 are portable and intended for transport and local storage. To set up a drawer, a shelf 3 is arranged on the cooling unit 1.

According to Fig. 1, the stationary cooling unit has four wall portions 5 and a bottom plate 6, which together have the shape of a box. At the upper end of the body a lid 7 is attached. All sides, walls and lid and an intermediate part 4 are provided with a friend insulation of suitable material and thickness. The outer sides of the insulation are clad with suitable, hard material, such as sheet metal. In the upper part of the unit a container 8 intended for a refrigerant 9 is enclosed. Between two of the opposite wall portions of the container 8, at least one guide plate 10 is arranged at a distance from the wall portions. Along the vertically standing wall portions of the container and in contact with the coolant, an elongate, helical pipeline 11 is arranged, which communicates with a supply line 12 and a return line 13. An inlet line 18 is connected to the inner volume of the container 8 at its upper end and an outlet line 19 at its bottom.

The lower part of the unit houses a cooling unit 15 with a power source of known type, which is not shown in the drawings and which can be operated with various alternative forms of energy such as electricity. The cooling unit is usually equipped with a pump / compressor 14, which in a known manner provides a circuit for a refrigerant such as freon in a liquid phase and a vapor phase. In this liquid phase, the refrigerant exits the cooling unit through a supply line 12 and returns after evaporation in the pipeline 11 in its vapor form through a return line 13. The operation of the cooling unit is controlled by means of a thermostat which senses the temperature of the refrigerant 9.

Furthermore, in the lower part the outlet line 19 is provided with a pump 20, the pump direction of which extends towards an outer end of the outlet line 19 at which a self-closing nipple 21 of known type is arranged outside 446 480 for the wall 5 of the lower part. The inlet line 18 is arranged in a similar manner and in it a pump 22 is arranged, the pump direction of which extends inwards from a second self-closing nipple 23, which is arranged next to the first-mentioned nipple 21. The nipples 21, 23 are thus connected to the container 8. .

As shown in Fig. 2, the portable cooling unit, the cooling box 2 has a body consisting of four vertical, opposite and adjoining wall portions 25, a bottom portion 26 and a lid 27 loosely attached to said wall portions and in opposite position to the bottom portion, so that a cold storage space 28 is formed. Furthermore, the wall portions, the bottom portion and the lid have internal spaces which are filled with insulating material. The insulation in the vertically standing wall portions 25, embedded in the insulating material, encloses an inner container space 30 extending around the box in a metal jacket 29, which has an outlet 32 and an inlet 33 arranged in pipes, which extend through the insulation in one of the wall portions 25. each pipe is a nipple 34, 35, fitted having a self-closing valve. In addition, the unit preferably has a basket (not shown) for the refrigerated goods.

The inner surfaces of the wall elements have recesses 31 in which a number of heat transfer elements 37 have been mounted on fastening elements 36, fixedly mounted on the jacket 29 to the container space 30. The heat transfer elements are T-shaped in cross section with an outer part 38 and a fastening part 39 (compare Fig. 3).

The intention is that heat transport is to take place from the storage space in the cooling box to a refrigerated cooler enclosed in the container space 30 in the jacket 29. The transfer must take place via the heat transfer elements 37. The capacity of these elements depends partly on the surface of the outer part 38 exposed to the storage space and partly on the conductivity capacity of the element, which in turn is determined by the thermal conductivity of the material used, the cross-sectional area of the conductive the parts, in particular the fastening part 39, the transfer length and the design of the contact point between the element 37 and the jacket 31 at the fastening element 36. By making the heat transfer elements 37 interchangeable and available in sets with different dimensions and thereby with different friend transfer capacities, the latter can be adapted for different conditions by replacing the heat transfer elements. The most suitable would then be for the elements in the kit to be manufactured with different cross-sectional areas of the fastening part 39, while on the other hand the outer part 38, which is to fit the recess 31, has an unchanged size. The embodiment with replaceable heat transfer elements represents the first embodiment. Such a substitutability can also exist in the second embodiment, but in that case it is only used for coarse adjustment of the cooling capacity, while fine adjustment and temporary adjustment takes place by means of a control element in the form of a door 60, see Fig. 5. The door 60 is off insulating material and 446 480 '4 is displaceable in front of the heat transfer element 37 from a position in which it is exposed to the storage space and a position where it is covered by the door. As is understood, the heat transfer capacity increases the larger part of the elements, which are freely exposed to the storage space. Even with a fully closed door, a certain heat transfer capacity is obtained because it has limited insulating capacity and otherwise heat will leak from the storage space 28 to the coolant in the container space 30 also through the per se well-insulated wall portions 25.

In a simpler embodiment, the door 60 can be displaceable in its slot purely manually and the adjustment is then suitably made according to a calibrated scale, by means of which an at least approximate temperature setting can be obtained. I fig. 5, however, a more advanced embodiment is shown. According to the figure, the door 60 is connected by means of a rod 62 to a thermostat element 63 attached to the wall portion 25. The thermostat element contains a screw-shaped spring of bimetal (not shown). One end of the spring is attached to the container wall by means of a housing 65 and via an adjusting screw with a control knob 66. Its other end is attached to the rod 62. As is well known, a bimetal consists of two rolled pieces of metal with mutually different coefficients of expansion. The body will thereby obtain different bending states at different temperatures. By utilizing this phenomenon, the spring between its ends obtains different lengths at different temperatures and will thereby via the rod 62 guide the door 60 to different opening positions. By adjusting this effect, the door can be made to open when the temperature tends to rise and to close when it tends to fall.

In addition, an adjustability can be obtained if the non-working end of the spring is made displaceable, as indicated by the control knob 66. However, this function is well known per se and therefore does not need to be described in more detail. Incidentally, a similar function can alternatively be obtained by means of a bellows, in which the pressure from an enclosed medium at different temperatures gives different expansion of the bellows. Other devices for a corresponding control are also known.

As shown, the temperature can be controlled by the means described.

However, the lowest temperature that can be obtained depends on how far down the refrigerant has cooled and it is then, as is known, necessary to adapt its composition to the selected temperature. Both the temperature above and below 0 ° C can be used, the lowest were used for frozen goods. The cooling box lid 27 has an inner and an outer surface which are joined by a vertically standing edge portion 42 extending around the lid. Furthermore, the outer surface of the lid is provided with a bearing surface 43 extending around the lid which delimits an inner surface portion 44 raised relative to said bearing surface. The inner surface of the lid has a circumferentially extending support surface 45 opposite to the support surface. The cooling box further has on its bottom portion 26 a circumferentially extending guide edge 46, which delimits an inner surface portion 47 recessed relative to the support edge. The guide edge 46 fits around the surface portion 44 of the lid to ensure control when stacking. The cooling box lid 27 may further be provided with a temperature monitoring device 50 consisting of a thermostat 51 mounted on the inner surface of the lid element, which is connected via electrical wires to an alarm unit 52 mounted in a recess on the outer surface of the lid.

The container 8 in the stationary unit 1 is during operation for the most part filled with refrigerant, which in a known type has the property that it does not freeze until at a very low temperature. The refrigerant has a transition stage from solid to liquid phase at this low temperature, which means that a high cooling effect is obtained for a longer period by utilizing its heat of fusion. In addition, it has the property of assuming around the freezing point not completely solid without a viscous, pumpable state. The refrigerant 0 is cooled in the container 8 down to the range -30 ° C by means of the elongate pipeline 11 arranged in the container 8, which in turn is cooled by evaporating the refrigerant supplied through the supply line 12 from the cooling unit 15.

When a cooling box 2 is to be used for cold storage, it is first ensured that its cooling capacity and thus its storage temperature is adapted to what is to be stored in the box, taking into account even the storage time. As stated above, this adaptation can in the simplest case take place by replacing the heat transfer elements 37, which are arranged in the manner described above for different heat transfer capacities. In this method of adaptation, it may be assumed that the boxes are more permanently set up for specific storage data in the facility with specific use and to which belong a cooling unit 1 and a number of cooling boxes 2, which in turn can be divided into a number of groups according to their capacity adjustment. At high precision in containing the desired temperature, the drawers can be equipped with a thermostat device according to Fig. 5. If the drawers are to be used for a more differentiated use with different requirements at temperature level, this can be adjustable in that way , as previously described, thus by means of the slidable cover 60, which can then be controlled by means of the described adjustable thermostat 63.

Immediately before using a cooling box 2, it must be loaded with cooled refrigerant from the container 8. This is done by placing the cooling box as shown in Fig. 1 on the shelf 3 and sliding it against the wall 5 of the cooling unit 1, so that its nipple 21 is connected to the cooling box. 2 nipple 135 and so that the nipple 23 is connected to the nipple 34. As mentioned, the four nipples are of the self-closing type, which means that when they are pushed together they come to seal against each other, after which ... 446 480 6 both joined nipples, so that the wires to which the nipples belong come into communication with each other. Correspondingly, the said valves are closed while they are still tight against each other. As a result, the two systems represented by the container 8, the lines 18 and 19 and the pumps 20 and 22 in the cooling unit 1 and the container space 3D in the jacket 29 with the pipes 32 and 33 in the connected cooling box can be connected to each other. When this has taken place, the two pumps 20 and 22 are started. The refrigerant 9 is thereby pumped from the bottom of the container 8 through the outlet line 19 and via the pipe 33 into the container space 30. The pumped refrigerant thereby pushes out refrigerant existing in the container space 30 through the tube 32 and further through the tube 18, the pump 22 assisting in the transport, and into the upper part of the container 8.

The refrigerant previously enclosed in the container space 30 can be assumed to have assumed a molten state and is thus considerably warmer and more fluid than the introduced refrigerant. With a suitable design of the flow channels and a reasonable inlet speed, this means that the newly supplied refrigerant layers below the previous one and lifts the partition limit, until the entire space 30 is filled with the cooled refrigerant. In the container 8 in the refrigeration unit 1, the warmer refrigerant flows in at its top and is assumed to layer on top of the colder refrigerant. Since the tapping takes place at the bottom of the container by means of the line 19, only the lower, cooler layer will be drained until the warmer layer begins to reach down towards the bottom of the container. The guide plate or plates 10 assist in maintaining a layering by preventing cross-currents.

The cooling box 2 is now loaded with cooled refrigerant in the container space 30 and can be removed from the cooling unit 1, which is easily done by pulling the box outwards on the shelf 3, whereby the nipples are released from each other and the valves are closed as mentioned earlier. The cooling space 28 can now be used for cold storage of the material in question. This is presumably stored before loading in the cooling box in a stationary cooling storage unit next to the cooling unit 1. It can often be a question of material which is frozen during long-term storage and the said cold storage unit can then be connected to a thawing point where the material is brought to temperature for further transport in and for use. This is the case, for example, with blood products, which are often stored refrigerated for transport to the place of use in a chilled state.

In the refrigerated storage space 28 closed by the lid 27, the temperature is maintained substantially constant at the adjusted value until the refrigerant in the storage space 30 has assumed a completely molten state. The temperature can be controlled by means of the instrument 50, which as mentioned can be designed as an alarm unit, which indicates when the cooling capacity is no longer sufficient. 446 480 In the cooling unit 1, the upper layer of the molten refrigerant in the container 8 will be gradually cooled by means of the refrigerant which is introduced from the cooling unit 15 into the pipeline 11. The cooling capacity and volume of the container 8 shall be such adapted, that such a thick layer of refrigerant cooled to the intended temperature is present at the bottom of the container 8, that at the predicted frequency of refrigerant charges of refrigerators always sufficiently refrigerated refrigerant will be drained.

In the system according to the invention, the cooling boxes 2 are for their function dependent on continuous filling of refrigerants, which means that only the cooling boxes themselves are not prone to theft. A large number of cooling boxes can be used for each cooling unit. The cooling boxes can be transported freely and travel between different, preferably stationary cooling units if it is assumed that the connection nipples are made the same on the different units.

The invention makes it possible to maintain an evenly distributed and near constant temperature for a longer period of time, such as for 24 hours, regardless of external conditions. The device according to the invention is insensitive to its function for careless handling as well as if it is transported up and down or on the side.

The invention is not limited to the exemplary embodiment described above and shown in the drawings, but can be varied within the scope of the appended claims. For example, instead of as shown as a magazine cooler, the refrigerant container of the refrigeration unit can be designed as a flow-through cooler.

You can also design the alarm at the refrigerator with digital display or with a memory that can be read afterwards to see how the temperature variation has been. The use of the invention is not limited to the mentioned area of use but can have a variety of other areas of use, such as in the chemical industry or in the food industry and distribution and for military purposes.

Claims (6)

446 480 PATENT CLAIMS Device for cold storage, in particular for storage during transport from one or more central places to places of use where a local storage can take place with the device comprising a number of transport units, for example cooling boxes (2) with a storage space (28), characterized ä that the transport units (2) each contain a container space (3), which is intended to be filled with a refrigerant of the type which can assume a condition which is at least partially frozen but still pumpable at a low temperature, such as the refrigerant is able to keep substantially constant until its completely assumed liquid phase, that the container space is accommodated in a jacket (29), which is provided with both an outer and an insulation (25) facing the storage space (28) facing the transport unit, that the insulation facing the container space is at least partially broken to bring the jacket (29) into thermal contact with the storage space, preferably within limited areas (31), to keep the cooling space (30) for the coolant has a number of external connections (34, 35) and that the device further comprises at least one central, preferably stationary cooling unit (1), which is arranged with at least one container (8) for the coolant and cooling devices. (11, 15) for holding the refrigerant in its said frozen but still pumpable condition and with connecting means (21, 23) for said external connections (34, 35) on the transport units (2) and between the container (8) for the refrigerant and the connecting means ( 21, 23), transport devices (18, 19, 20, 22) such as lines and pumps, so that in the container (8) cooled refrigerant (9) cooled by means of the cooling devices (11, 15) can be transferred via the connections (34) of the transport units , 35) and the connecting means (21, 23) of the refrigeration unit (1) to the container space of the transport units while removing heated refrigerant from the same, whereby the storage space (28) of the transport unit can be kept refrigerated while the refrigerant is transferred to s. in liquid phase. Device according to claim 1, characterized in that in the storage unit (2) the jacket (29) of the container space (20) has a connection with the storage space (28) via heat transfer elements (37), which are in contact with the jacket and through material line. transfers heat to it from one or more surfaces facing the storage space. . _ Device according to claim 2, characterized in that the heat transfer units (37) are interchangeably arranged, - so that heat transfer elements 446 480 elements with different heat transfer capacity can be used for adapting the heat transport from the storage space (28) to the jacket (28). . Device according to one of the preceding claims, characterized in that the connecting path of the jacket to the storage space for heat transport therefrom is arranged to be able to be covered by means of an insulating door (60), which can be adjusted with respect to its degree of opening for adjustment of the heat transfer capacity. Device according to claim 4, characterized in that the door (60) is arranged to be set to its degree of opening by means of the temperature in the storage space (28) sensing thermostat (63). Device according to one of the preceding claims, characterized in that the storage unit (2) has a temperature monitoring instrument (50).