DE102007029179A1 - The refrigerator - Google Patents

Abstract

The invention is based on a refrigeration device with a refrigerant circuit having a cold generator and at least one heat exchanger (1, 14), the heat exchanger (1, 14) having a refrigerant pipe (6) and a heat exchange body (2-5, 15 , 16). According to the invention, the tube (6) is wrapped around a plug-in heat exchange body (2-5) or the tube (6) extends within a plug-on heat exchange body (15, 16).

Description

The The invention relates to a refrigeration device according to Preamble of claim 1.

at Refrigeration appliances with a refrigerant circuit is common in the interior provided at least one evaporator, in which very cold refrigerant guided becomes. about This evaporator is absorbed from the interior of the refrigerator heat and with the refrigerant dissipated. The refrigerant is compressed by a compressor and heats up. On the outside of the refrigerator is a condenser provided in which the hot refrigerant chilled and thereby liquefied again. The heat energy from the refrigerant is released into the ambient air. Both the evaporator as well as the liquefier thus act as a heat exchanger.

It is already a big one Number of evaporators and condensers become known, all of which have the task to absorb heat as quickly as possible or leave. Either, however, the heat exchanger performance of this known evaporator and liquefying relatively low or they are occupied by high production costs.

Of the Invention is based on the object, a refrigeration device with a refrigerant circuit with a heat exchanger to equip, which has a high heat exchange performance provides and still produce cheap is.

Is solved the task according to the invention through a refrigerator with the Features of claim 1. The body connected to the refrigerant pipe connected body should the surface enlarge the pipe, so that much heat either taken from the environment or released to the environment can be. But now also a good heat transfer between the body and the Ensure pipe to be able to must be one possible large area contact between the body and consist of the tube. For this purpose, the tube is either bent that it is around the body runs, or the pipe runs within the body.

Advantageous is the body cylindrically designed. In a cylindrical outer contour is at an outside to the body guided pipe around Ensures that the pipe does not have to be kinked to fit in brought intimate contact with the body to be able to. At one inside the body out Tube are all the points of the outer contour of the body in equal distance from the tube, allowing a very uniform heat radiation comes about.

Especially Advantageously, the body a hub along the central longitudinal axis of the cylinder and several spokes on. This is possible the heat exchangeable surface of the body continue to enlarge. ever according to the diameter of the cylindrical body can be for the number of spokes Find optimum, because although the heat exchangeable surface is increased with a large number of spokes, with too small a distance of the spokes to each other but a mutual Influencing takes place, so that the heat exchange performance of the individual Can reduce spokes.

The surface let yourself continue to enlarge, if the hub executed hollow is. Likewise, more could to the hollow hub concentric rings the spokes together connect.

Also the outer ends the spokes can be connected to the sections of a cylinder jacket. It can these are individual sections, but the sections can also form a closed ring.

at one of individual sections existing cylinder jacket can Spokes so connected to the sections that the outer edges the spokes run along the central axes of each section. The spokes can However, each with a side edge of a portion of the cylinder jacket be connected. In this way, each section looks like a kinked one renewal every spoke.

The body are advantageously constructed so that they are extruded profile let produce. The production costs of the body can be very low in this way being held.

at an embodiment with outside around the body guided around Pipe, it is advantageous to bend the pipe so that a very uniform heat exchange with the body but also between pipe and ambient air can take place. The Tube is this helical around the body wound and thus forms a right-handed or left-handed coiled tubing. The even distance between the individual pipe turns ensures the uniform heat exchange.

The contact area between the rotating pipe and inside the pipe turns arranged body should be as big as possible be. The body Therefore, advantageously has a closed cylinder jacket.

A correspondingly constructed heat exchanger has in a particularly advantageous manner a plurality of juxtaposed body. In order to build the heat exchanger as flat as possible, The central longitudinal axes of the individual bodies run parallel. If the central longitudinal axes of the individual bodies are additionally in one plane, the heat exchanger has the outer contour of a plane-parallel plate and can be attached, for example, as a condenser to the rear wall of a refrigeration device. In the other case, however, the heat exchanger can also be bent so that it adapts, for example, to the contour of a freezer compartment and assumes the function of an evaporator here. In both examples, the tube is wound around a body from the bottom up and around the body arranged next to it from top to bottom. In this way, only very short pieces of pipe between the individual bodies remain without contact to one of these bodies and there is a high efficiency of the heat exchanger.

at a heat exchanger with inside the body guided Pipe, the body should the pipe as possible enclose thus the largest possible possible contact between body and pipe comes about. On the other hand, it represents a huge simplification in the manufacture of the heat exchanger when the body is after bending the pipe can be attached to the pipe, but no further fasteners are necessary to a solid Connection between pipe and body to ensure. This solid connection is ensured when the body Pipe over encloses an angle of more than 180 °. at the use of an elastic material for the production of the body can be this snaps on the tube and remains safe in this Position. According to the elasticity of the material, the enclosing angle up to 360 °. It should be taken into consideration, that the contact surface between body and Tube with larger enclosure angle also gets bigger and thus also the heat transfer performance increases.

Advantageous extends the tube inside the hollow hub of the cylindrical body. The hub is thus entire area on the pipe and thus provides excellent heat transfer from the tube to the body or from the body sure of the pipe.

The Hub is according to the invention along its longitudinal axis slotted. The body let yourself in this way, simply put on the pipe without the pipe through the body has to be pushed through.

at a correspondingly constructed heat exchanger The tube can in a known manner looped with curved and straight Sections go. The straight sections of the pipe run each through the hollow hub of a body and are parallel to each other aligned. The radius of the bent sections is slightly larger than the radius of the cylindrical body designed so that they have a distance from each other. hereby let yourself on the one hand simplify the attachment to the straight sections of the tube and on the other hand the heat exchange improve with the ambient air.

Further Details and advantages of the invention will become apparent from the dependent claims Related to the description of embodiments based on the drawing explained in detail become.

It shows:

1 a coiled heat exchanger in different views and

2 a loop heat exchanger in different views

The in 1 shown coiled heat exchanger 1 is made up of four individual tube coils 8th together. It was used here alternately right and left-handed coiled tubing. For every coiled tubing 8th is the pipe 6 bent in the form of a spiral spring, each remaining at the top and bottom of a straight endpiece. The upper and lower straight lugs point in opposite directions. Around two coiled tubing 8th connecting each other, each becomes a sleeve 7 used.

The coiled heat exchanger 1 can be made from any number of coiled tubing 8th being constructed. Because only two different types of coiled tubing 8th , namely right and left-handed coiled tubing, used, the manufacturing costs can be kept low. Due to the modular design of the coiled heat exchanger 1 by assembling any number of tube coils 8th adapted to different types of refrigeration appliances.

In order to improve the heat exchange capacity, are in the individual coiled tubing 8th Mortise heat exchange body 2 - 5 inserted. In 1 four different embodiments of such plug-in heat exchange body are shown. The plug-in heat exchange body used on the left side 2 has a hollow hub 11 and four cross-shaped support spokes attached thereto 9 on. In each of the through the spokes 9 formed quadrants are also four heat exchange spokes 10 with the hollow hub 11 connected. These heat exchange spokes 10 have no support function. The main focus in material selection can therefore be placed on the ability to effectively heat energy with the ambient air To deceive. In particular, materials with a very large surface area are suitable here.

The plug-in heat exchange body 2 has no lateral surface. With the pipe 6 Consequently, only the free ends of the support spokes 9 and the heat exchange spokes 10 in contact. The contact surface between plug-in heat exchange body 2 and pipe 6 remains relatively small in this embodiment, so that the tube 6 Surrounded by the ambient air can be flowed over a large area.

While in the plug-in heat exchange body 2 the support spokes 9 and the heat exchangers 10 on the hollow hub 11 are attached, these are in the plug-in heat exchange body 3 with a closed cylinder jacket 12 connected. A hub is not provided in this embodiment. The free inner ends of the support spokes 9 and heat exchangers 10 can touch each other, but they are not connected. Here lies the coiled tubing 8th with its inside completely on the cylinder jacket 12 at. This results in a good heat transfer between the tube 6 and the plug-in heat exchange body 3 ,

In contrast to the plug-in heat exchange body 3 is at the two heat exchange bodies 4 and 5 no closed cylinder jacket provided. Here, the cylinder jacket consists only of shell sections 13 , which have a distance to each other. This results in a cylinder jacket with vertical slots, along the central longitudinal axis of the plug-in heat exchange body 4 and 4 run. In both plug-in heat exchange bodies 4 and 5 is a hollow hub 11 provided with support spokes 9 connected is. The support spokes 9 in turn stand with the shell sections 13 in connection, so that here a continuous heat-conducting connection of the hollow hub 11 over the support spokes 9 to the jacket sections 13 consists. While in the plug-in heat exchange body 4 the support spokes 9 each with the lateral edge of a jacket section 13 connected are the support spokes 9 in the plug-in heat exchange body 5 with the jacket sections 13 along the central axis in conjunction. Also, the number of support spokes can be 9 and the associated jacket sections 13 vary. So is the hollow hub 11 in the plug-in heat exchange body 4 with four support spokes 9 and at the plug-in heat exchange body 5 connected with five spokes.

At the in 2 shown loop heat exchanger 14 is the pipe 6 bent in such a way that parallel straight sections are formed, which are connected to each other via curved sections. On the straight sections of the pipe 6 become slip-on heat exchange bodies 15 . 16 attached. These attachment heat exchange body can be designed very different. In the slip-on heat exchange body 15 are spokes 17 with an open hollow hub 18 connected. Every spoke 17 is at its free outer end with a jacket section 19 centrally connected so that a lateral surface is formed, which is interrupted by a plurality of vertical slots.

The open hollow hub 18 has an opening 20 on, with which the slip-on heat exchange body on the straight section of the pipe 6 put on. In the area of this opening are at the open hollow hub 18 no spokes 17 appropriate. In through the shell sections 19 formed lateral surface thus enters a wedge-shaped incision. The width of the opening 20 is slightly smaller than the diameter of the pipe 6 designed so that the attachment of the plug-on heat exchange body 15 is executed in the manner of a clip closure. The slip-on heat exchange body 15 are ideally oriented so that the wedge-shaped cutouts in the lateral surface turn in the same direction and the bisector of the wedge-shaped cut intersects the central longitudinal axis of the adjacent slip-on heat exchange body. In this way, the slip-on heat exchange body 15 be dimensioned so that the circumferential lines of adjacent slip-on heat exchange body 15 overlap.

The slip-on heat exchange body 16 differ from the slip-on heat exchange bodies 15 by the absence of the jacket sections 19 , As a result, although the available heat exchange surface is lower, but it is the air exchange between the individual spokes 17 improved.

Both when using the coiled heat exchanger 1 as well as the loop heat exchanger 14 it makes sense to mount the respective heat exchanger so that the heat exchange body are aligned vertically. As a result, the convection is promoted in the air channels of the heat exchange body. In order to further improve this, a fan can additionally be installed above or below the heat exchanger. For this purpose, in particular, a cross-flow fan, since it allows the air flow can be easily adapted to the shape of the heat exchanger.

1

coiled heat exchangers

2-5

Mortise heat exchange body

6

pipe

7

sleeve

8th

right- or left-handed coiled tubing

9

support spoke

10

Heat exchange spoke

11

hollow hub

12

cylinder surface

13

shell section

14

Loop heat exchanger

15-16

Plug-heat exchange body

17

spoke

18

open hollow hub

19

shell section

20

hub opening

Claims (14)

Refrigerating appliance with a refrigerant circuit with a cold generator and at least one heat exchanger ( 1 . 14 ), wherein the heat exchanger ( 1 . 14 ) a refrigerant pipe ( 6 ) and a thermally conductive connected heat exchange body ( 2 - 5 . 15 . 16 ), characterized in that the tube ( 6 ) around a plug-in heat exchange body ( 2 - 5 ) or the pipe ( 6 ) within a slip-on heat exchange body ( 15 . 16 ) runs. Refrigerating appliance according to claim 1, characterized in that the heat exchanger body ( 2 - 5 . 15 . 16 ) is cylindrical. Refrigerating appliance according to claim 2, characterized in that the heat exchanger body ( 2 - 5 . 15 . 16 ) a hub ( 11 . 18 ) along the central longitudinal axis of the cylinder and a plurality of spokes ( 9 . 10 . 17 ) having. Refrigerating appliance according to claim 3, characterized in that the hub ( 11 . 18 ) is made hollow. Refrigerating appliance according to claim 4, characterized in that the hub ( 18 ) for receiving the tube ( 6 ) of the cylindrical plug-on heat exchanger ( 15 . 16 ) serves. Refrigerating appliance according to one of claims 3 to 5, characterized in that the hollow hub ( 18 ) is slotted along its longitudinal axis. Refrigerating appliance according to claim 3 to 6, characterized in that the outer ends of the spokes ( 9 . 17 ) with sections ( 13 . 19 ) are connected to a cylinder jacket. Refrigerating appliance according to claim 7, characterized in that the sections ( 13 ) of the cylinder jacket at a side edge with the spokes ( 9 ) are connected. Refrigerating appliance according to one of claims 1 to 8, characterized in that the heat exchange body ( 2 - 5 . 15 . 16 ) is designed as an extruded profile. Refrigerating appliance according to one of claims 1 to 4, characterized in that the tube ( 6 ) helically around the plug-in heat exchange body ( 2 - 5 ) is wound. Refrigerating appliance according to one of claims 2 to 10, characterized in that the cylinder has a closed jacket ( 12 ) having. Refrigerating appliance according to one of claims 1 to 4 or 7 to 11, characterized in that the heat exchanger ( 1 ) a plurality of juxtaposed plug-in heat exchange body ( 2 - 5 ) whose central longitudinal axes are parallel, wherein the tube ( 6 ) around a plug-in heat exchange body ( 2 - 5 ) from bottom to top and around the plug-in heat exchange body ( 2 - 5 ) is wound from top to bottom. Refrigerating appliance according to one of claims 1 to 6, characterized in that the tube ( 6 ) of the slip-on heat exchange body ( 15 . 16 ) is enclosed over an angle of more than 180 °. Refrigerating appliance according to claim 12, characterized in that the tube ( 6 ) of the heat exchanger ( 14 ) in loops with curved and straight sections and several straight sections each through the hollow hub ( 18 ) of a plug-on heat exchange body ( 15 . 16 ).