DE19502137A1 - Roof-mounted cooling plant for refrigerated transporter - Google Patents

Abstract

The cooling plant is flat and has an evaporator (4) and one or more radial fans (6,7) provided in a housing (2) which projects through a roof opening into the cold chamber (22) so far downwards that the lower region lies below the inner wall of the insulating lid of the chamber. The coolant condenser (17) is a parallel flow one. The coolant collector-cum-drier (14) is horizontal. The base plate (1) and the evaporator housing are one-piece and are preferably made of plastic. The evaporator housing is formed out of the base plate by a vacuum process. The water droplet catcher shell (9) is formed on the evaporator housing.

Description

Roof split cooling systems for refrigerated transport vehicles z. B. Fresh service Transporters included in one on the roof of the refrigerator compartment arranged housing the refrigerant condenser with fan ventilation - mostly axial fans -, also under an insulated hood Refrigerant evaporator, as well as one or more for cooling air circulation re fans, usually centrifugal fans. In addition, in the housing arranged on the vehicle roof still required Chen control and regulation devices, collector dryer and the connection pipes housed between the above elements.

The radial fans assigned to the evaporator suck out air the space to be cooled through an opening in the vehicle roof, the air flows through the evaporator, is cooled and through a second Opening led back into the refrigerator.

In order not to get a short circuit of the air flow, the inside of the Cold room ceiling an air distribution box arranged in the wall Air openings are provided for the entry and exit of air. The Air outlet openings are often provided with adjustment devices, to be able to adjust the direction of the air flow into the refrigerator. This usual design means that the air distribution box in the Cold room must protrude. Has the usual construction described here as a result that the roof housing of the split cooling system 200 to 250 mm, too because even more extends beyond the height of the roof. It follows not only the disadvantage of high air resistance and greater burning rather, it often happens that fresh service vehicles do not drive through a gate because it is a few centimeters too high can.

The roof split cooling system according to the present invention is against this designed so that the disadvantages mentioned largely avoided  and the maximum height above the roof is about halved. This is achieved in that the evaporator and the one or more Ra dial fans in the evaporator housing are laid as far down that they are partly inside the refrigerator.

In addition, an otherwise common "tube and fin" capacitor is through one compact and flat "parallel flow" condenser replaced. Furthermore, in place of a conventional standing collector dryer one in horizontal version used. The bottom plate and the evaporator rim Housing are preferably made of plastic and in one piece. The Evaporator housing is formed by vacuum forming, too the drip tray is formed. The evaporator housing protrudes through a rectangular cut-out in the insulated roof of the cold room into this. In the cold room, this cutout with the evaporator housing clad with a tub, which the air circulation and the Allows drip water drainage.

In the drawings is an embodiment of a roof split cooling plant shown schematically according to the invention.

The figures show (cut open in the longitudinal direction):

Fig. 1 shows a section through a conventional roof-split cooling system design,

Fig. 2 shows a section through a roof split cooling system according to the vorlie invention.

As can be seen from Fig. 1, evaporators and evaporator fans are arranged above the cold room roof in this embodiment. The air is connected to an air distribution box under the ceiling in the cold room through separate ducts for supply and exhaust air. This version has all the disadvantages listed in the introduction. The embodiment according to the invention in FIG. 2, on the other hand, makes it possible to halve the overall height above the roof. For this purpose, the evaporator ( 4 ) and one or more radial fans ( 6 , 7 ) are laid down in the evaporator housing ( 2 ) and its lower area is below half the ceiling ( 11 , 12 ) of the cooling chamber ( 22 ) of the condenser ( 17 ) instead of a "tube and fin" condenser is a compact and flat "parallel flow" condenser. In addition, a horizontal collector / dryer ( 14 ) is used instead of a conventional standing refrigerant collector / dryer.

The evaporator housing ( 2 ) is formed from the preferably plastic base plate ( 1 ), preferably by vacuum deformation, with a drip tray ( 9 ) being molded on. The dripping water is drained off through a drain opening ( 10 ). The Verdampferge housing protrudes through a rectangular opening ( 13 ) in the insulated roof ( 11 , 12 ) in the vehicle cooling compartment ( 22 ). Openings ( 15 ) generate the air movement through the evaporator ( 4 ) by means of one or more radial fans ( 6 , 7 ). To avoid leaks as well as for optical reasons, the roof opening ( 13 ) and the evaporator housing ( 9 ) are clad with a trough ( 16 ) on the inside of the cooling chamber, which is designed in such a way that the air circulation through the supply and exhaust air openings ( 15 ) and the drip water can be drained through the opening ( 10 ). The evaporator together with fans is covered in an airtight manner by an insulated hood ( 8 ).

The condenser ( 17 ) located at the front in the direction of travel is arranged in a housing which is open at the front, preferably made of metal and in the upper cover wall of which one or more axial fans ( 18 ) are mounted. The cooling air is drawn in via openings ( 20 ), passed through the condenser ( 17 ) and discharged to the environment again through the opening (s) ( 21 ) in the upper cover ( 3 ) of the roof split cooling system.

It is obvious that this roof split cooling system according to the Erfin avoids the disadvantages of the state-of-the-art systems, without the need for more material and labor is.

Claims (6)

1. Flat split roof cooling system, characterized by the following features:

• a) The evaporator ( 4 ) and one or more radial fans ( 6, 7 ) are in the evaporator housing ( 2 ), which protrudes into the cooling chamber ( 22 ), so far down that their lower area below the inner wall side of the insulation - Ceiling ( 11 , 12 ) of the cooling room ( 22 ).
• b) The refrigerant condenser ( 17 ) is a "parallel flow" condenser.
• c) The refrigerant collector / dryer ( 14 ) is arranged horizontally.

2. Roof split cooling system according to claim 1, characterized in that the base plate ( 1 ) and the evaporator housing ( 2 ) are in one piece and preferably consist of plastic. 3. Roof split cooling system according to claims 1 and 2, characterized in that the evaporator housing ( 2 ) is formed by means of vacuum deformation from the base plate ( 1 ). 4. Roof split cooling system according to claims 1 to 3, characterized in that the drip water drip tray ( 9 ) is integrally formed on the evaporator housing ( 2 ). 5. Roof split cooling system according to claims 1 to 4, characterized in that the evaporator housing ( 2 ) protrudes through a roof opening ( 13 ) in the cooling chamber ( 22 ). 6. Roof split cooling system according to claims 1 to 5, characterized in that the roof opening ( 13 ) and the evaporator housing ( 2 ) on the inside of the cooling space ( 22 ) are covered with a trough ( 16 ), which openings for air circulation ( 15 ) and the drip water line ( 10 ).