DE10119095A1 - Dust and water-tight switch cabinet for electrical and electronic devices has walls connected heat-conducting body with fluid flow along longitudinal axis - Google Patents

Abstract

The cabinet has a multi-layer wall which expels heat to the outside, and provides sufficient protection when located outdoors. To increase the area available for thermal transfer, at least one wall (2) on one or more sides is thermally connected to a heat conducting body made as one part. The heat conducting body allows fluid flow along its longitudinal axis.

Description

The invention relates to a control cabinet for electrical and electronic devices, the dust and is watertight, at least partially has a multi-layer wall that the heat generated inside releases through the housing wall to the outside and the Built-in offers sufficient protection even when it is installed outdoors, as it is made of DE 198 12 117 A1 is known. To ensure adequate heat transfer through the To enable the housing wall, it is provided with bodies so that the heat-exchanging Surface is enlarged.

Ensuring adequate protection against environmental influences for electrical and electronic equipment due to a cabinet placed outdoors requires a dust and waterproof version of the cabinet. The arising inside the cabinet or heat brought into the cabinet by solar radiation can be Housing wall or via special devices such as heat exchangers or cooling devices be dissipated. The housings are multi-walled to protect against sunlight executed, the housing wall being surrounded by another outer wall, that there is an air space between the two. To use as much heat as possible to be able to remove the housing wall flows between the outer wall and the Housing wall a fluid flow. This is usually one by at least one fan assisted flow of the cool outside air, which is drawn into the lower part of the cabinet and exits in the area of the upper roof covering. Located inside the closet another air duct wall parallel to the housing wall at a distance of one Allows air flow. An air flow in the Inside the housing through the space between the air duct wall and the inner Run along the housing wall, which keeps the interior air of the cabinet in circulation. The Housing thus has two mutually independent fluid flows through the Housing wall are separated from each other. To increase the heat transfer performance is the surface of the housing wall inside, outside or inside and outside through Application of heat sinks or cooling fins enlarged.

Cabinets of this type are characterized by a structure without extensive cooling units and without negative effects on the degree of protection of the housing. The for Enlargement of the heat-exchanging surfaces of the housing wall Heat sinks or cooling fins generally have a complex geometry and consist of  many individual parts and their manufacture and application to the housing wall a considerable effort, which is the total cost of such a cabinet essential affected.

The object of the invention is to provide a control cabinet, which by a comparatively simple enlargement of the housing wall surfaces is sufficient Heat transfer performance of the housing wall secures and that by simple Manufacturing and assembly can be manufactured inexpensively.

This problem is solved by the features of claim 1. Beneficial and expedient configurations are specified in the subclaims.

With the invention it is achieved that the surface of the cabinet suitable for heat transfer can be increased in a particularly simple and inexpensive manner, so that the heat transfer performance can be increased significantly compared to a simple housing wall. According to the invention, one-piece, simply shaped heat-conducting bodies 4 , 5 , 6 , 7 are designed, which are applied to the walls of the housing 2 in a heat-conducting manner. One advantage of the heat-conducting bodies according to the invention consists in their simple manufacture from a rectangular material cut and standard forming processes such as bending or stamping. A particularly simple construction of the heat-conducting body is the trapezoidal shape 13 . Here, an elongated material cut is made in a trapezoidal wave structure without making holes or openings. The connection points between the heat-conducting body and the housing wall are set in the perpetrators 15 of the trapezoid.

In a further variant of the heat-conducting body 12 , cup-like depressions are embossed into an elongated material blank. The underside of these cups 11 represents the connection points to the housing wall 2. The depth of these cups determines the distance between the wall of the heat-conducting body and the housing wall 2 .

The dimensions of the heat-conducting bodies are such that they at most fill the space between the outer wall 3 and the housing wall 2 and the space between the housing wall 2 and the inner air duct wall 1 , a design which is advantageous to the outer wall or to the inner air duct wall Airspace leaves.

Control cabinets of conventional size require only two heat-conducting bodies according to the invention for each housing wall, one on the inside and one on the outside. Due to the symmetrical structure of the heat conducting bodies 4 , 5 , 6 , 7 , identical bodies can be used for the inner and outer walls of the housing. A symmetrical arrangement of the heat-conducting bodies on the inside and outside enables the heat-conducting bodies to be applied jointly to the walls of the housing body in one operation. The heat conducting bodies can be connected to the housing wall 2 by gluing or resistance spot welding. In a further variant of the heat-conducting bodies 4 , 5 , 6 , 7 , they are made from perforated sheet metal, and the perforation can be of any shape. Instead of the perforated plate, an expanded metal or other sieve-like fabric can also be used.

In a further embodiment, in addition to the housing walls 2 , the door 17 of the control cabinet is also provided with heat-conducting bodies 4 , 5 , 6 , 7 , which further increases the heat transfer capacity of the control cabinet.

An embodiment of the invention is explained in more detail with reference to FIGS. 1 to 3.

Fig. 1 shows a cross section of the cabinet in plan view.

Fig. 2 shows a heat-conducting body in a trapezoidal shape,

Fig. 3 shows a heat conducting body with impressed wells.

In Fig. 1, a water and dust-tight control cabinet housing 2 is shown which is surrounded by an outer wall 3 and which has an inner air duct wall 1 in the interior 10 . An air duct 9 is formed between the outer wall 3 and the housing wall 2 , through which ambient air can flow, and an air duct 8 is formed between the housing wall 2 and the inner air duct wall 1 , through which the inner air of the housing can flow. The inner heat-conducting bodies 4 and 6 are applied in a heat-conducting manner to the inner side of the housing wall 2 , with heat-conducting bodies in trapezoidal shape 4 being embossed on the housing sides and heat-conducting bodies with embossed cups 6 being exemplarily sketched on the rear. The outer heat-conducting bodies 5 and 7 are applied in a heat-conducting manner to the outer side of the housing wall 2 , heat-conducting bodies in trapezoidal shape 5 being applied to the housing sides and heat-conducting bodies with embossed cups 7 being applied to the rear.

The desired heat transfer takes place through the housing wall 2 , the heat-conducting bodies 4 , 5 , 6 , 7 ensuring an enlarged surface of the housing wall 2 . Air flows in the air ducts 8 and 9 forced by fans ensure the heat transport. The air flow flows along the housing wall and along the longitudinal axis of the heat-conducting body. The heat-conducting body 4 , 5 is connected in the “valleys” 15 in a heat-conducting manner to the housing wall 2 , the “mountains” 16 projecting outwards or into the interior. The heat-conducting bodies applied to the rear of the housing 2 are connected to the housing wall at the bottoms of the cup embossments. The heat conducting bodies 4 , 5 , 6 , 7 are expediently arranged symmetrically if they are applied to the inside and outside of the housing wall. The use of trapezoidal and cup-shaped heat-conducting bodies 4 , 5 , 6 , 7 takes place alternatively and is not tied to a specific housing side.

In addition to the housing wall 2 , the door 17 can also be provided with an outer wall 18 and an inner air duct wall 20 , so that the air channels 19 and 21 are created. Thermal conductors 23 are then also fastened on the inside and 22 outside of the door 17 . After the air ducts have been integrated into the air flow, the door represents another heat-exchanging surface.

Fig. 2 shows a trapezoidal thermal conductors 13 which may be made of a knitted stretch material blank by bending, and has a plurality of edges 14 and 15 over a plurality of valleys and mountains sixteenth

Fig. 3 shows a heat conducting body 12 having embossed wells 11 which may be made of a knitted stretch material blank by embossing the wells.

Claims (6)

1. Control cabinet for electrical and electronic devices, which is dustproof and watertight, at least partially has a multi-layer wall, which emits the heat generated inside through the housing wall to the outside and which also provides the built-in protection when it is outdoors is set up, characterized in that in order to enlarge the area available for heat transfer, at least one housing wall 2 is connected in a heat-conducting manner to the housing wall on at least one side with a continuous heat-conducting body, which is made from one part, the heat-conducting body allowing fluid flow along its longitudinal axis , 2. Switchgear cabinet according to claim 1, characterized in that the heat-conducting bodies applied to the housing wall 2 are applied inside and outside in a symmetrical arrangement which enables a common fastening. 3. Control cabinet according to claim 1 or 2, characterized in that the heat-conducting body consists of profiled bodies 13 . 4. Control cabinet according to claim 1 or 2, characterized in that the heat-conducting body consist of flat bodies in the cup-like depressions 11 are embossed. 5. Control cabinet according to claim 3 or 4, characterized in that the heat-conducting body are made of perforated sheet metal, expanded metal or other sieve-like material. 6. Switchgear cabinet according to one of the preceding claims, characterized in that in addition to the housing walls on the door 17 heat-conducting bodies are attached and that the air channels 19 and 21 of the door are integrated into the air flow.