DE10142103A1 - Spatial cell for protecting transmitter system or other electronic telecommunications equipment has fan element(s) in roof area vent, cooling device(s) in interior for cooling internal air - Google Patents

Abstract

The cell has at least one fan element (36) and ventilation openings (34) in at least one cell wall. The fan element(s) is mounted in a ventilation opening in the roof area of the cell and at least one cooling device (54) in the interior for cooling internal air. The cooling device is arranged internally in front of at least one cell wall opening and contains a liquefier (59) and evaporator (60) in front of a wall opening or opening. An Independent claim is also included for a method of air conditioning a spatial cell.

Description

The invention relates to a room cell to protect a Sen system or other electrotechnical devices for the Telecommunications with at least one fan element as well with ventilation breakthroughs in at least one cell wall dung. The invention also includes a method for climate tize the room cell.

Transmitter systems or corresponding electrotechnical devices generate relatively high power losses, and their lives duration depends on certain limit temperatures, which must not be exceeded. Serve as a room cell So-called Telekom mobile boxes, which are used as steel containers or as a concrete room cell - each with an access door hen - be made.

The applicant has up to 4 kW for dissipating heat losses developed its own ventilation concept for concrete room cells winds that works without air conditioning and only - relatively rarely - when high outside temperatures use a built-in fan required. This is at the door side a fan element in the dimensions 52 cm × 64 cm installed, which contains a filter mat. For the exhaust air are provided near the roof ventilation slots, as in a Embodiment of DE 197 06 320 A1 from the applicant are take. When the temperature inside the station is over 45 ° C rises, turns on in the opposite Wall-mounted fan - for a recess opening knife of 34.5 cm - a, as the supply air cross-section so probably the supply air fan element with filter mat as well. Ventilation slots. By the nature of their con structure, the greatest possible dust is avoided the.  

The Erfin has knowledge of this state of the art which set the goal of cooling behavior in so-called mobile boxes to improve and meet higher requirements who are not up to the previous procedure is. On the one hand, in addition to 4 kW, 7 kW and 10 kW ver pleasure must be dissipated, on the other hand, the permissible internal cell temperature is only a maximum of 35 ° C, even at a maximum ambient temperature - the Outside air - from 40 ° C; in this constellation one leads natural ventilation with the support of a ven tilators to no improvement.

The teaching of the independent leads to the solution of this task claim; the subclaims give favorable further training to. In addition, all com fall within the scope of the invention binations from at least two of the ones in the description, the Drawing and / or the features disclosed in the claims.

According to the invention are in a ventilation opening in the roof area - or a corresponding connection with the Cell outside - at least one fan element in the room cell ment and in the cell interior at least one cooling device for Cooling the indoor air arranged. In addition, the cooling device at least one wall opening of the cell wall on the inside be upstream.

One condenser and one has proven to be cheap Evaporator of the cooling device at least one wall opening to arrange, at least near the evaporator in the Front wall of a housing of the air conditioner opening is provided.

For the rest, that cooling device is a separate one Air circuit can be assigned, as below is discussed.  

A normal air conditioner, for example 7 kW or 10 kW Cooling capacity is very expensive and voluminous. At a Split device would also be at risk of vandalism the outside parts.

Thus, according to the concept of the invention over most of the year - at not so high temperatures - the ventilation is operated according to the above-mentioned method, ie via an air supply element with a filter mat which, due to the space requirement of the additional air which is developed according to the invention and which is assigned to the air supply Cooling device is arranged on the back of the room cell or the mobile box, including the all-round ventilation and one - based on space and due to the location at the highest point - in the roof-located fan with 3000 m ³ hourly output.

If temperature-related, natural ventilation or the additional use of the fan no longer sufficient to meet the above Will meet requirements Supply air - outside air up to 40 ° C - with the internal spe The cooling unit is cooled, at the same time the fan in operation in the roof. This solution is compared to conventional Lichen air conditioners that generally cool the indoor air len, both in the purchase and in the operation costs cheaper and less prone to maintenance; the cooling devices operate much less than the air conditioner.

The cooling device used according to the invention in the preferred th dimensions 65 × 40 × 18 cm contains the described Condenser immediately before and at the level of the supply air element tes. The supply air then enters the device from the bottom, cooled the mobile box, supplies it with cool air, which in the There is heat exchange with the devices and the heat loss over the fan located in the roof and the round venting leads away. Since the device is in a corner of the mobil box is mounted, the cooling air outlet takes place according to the invention L-shaped on two sides of the device.  

The condenser of the cooling device is preferably by a separate air circuit cooled from the top of the device centrifugal fans are maintained and a supply air grille in the concrete wall of the mobile box as via an exhaust air grille above the supply air grille in the Concrete wall of the mobile box with the outside air is formed.

The cooling units are designed to be the same Sizes and the same connection dimensions for both 4 kW and 7 kW, as for 10 kW power loss in the mobile box sen.

A method for air conditioning lies within the scope of the invention tion of the above cell to protect a transmitter location or other electrotechnical devices for tele communication, in which the supply air with an internal Cooling unit is cooled while a roof ventilation element is actuated.

The concept according to the invention leads to the following advantages, among others:

• - less hours of operation than an air conditioner, because the inside temperatures are always higher than that Outside temperatures are, therefore
• - longer lifetime;
• - cheaper solution than air conditioners;
• - space saving due to special construction;
• - Interchangeability for different requirements stakes (4 kW, 7 kW, 10 kW) in a building, because the additional cooling devices and the construction elements elements supply / exhaust air and the like in the mobile box have the same dimensions.

Further advantages, features and details of the invention result from the following description more preferred Exemplary embodiments and with reference to the drawing; this shows in:

Figure 1 is a plan view of a concrete cell as a so-called. Mobile box - without a roof plate - for transmitter systems of tele communication.

. Figures 2 to 4 are sectional views through side walls and end walls of the voicemail.

Figure 5 shows the vertical section through the room cell along line VV of Figure 1 with a front view of an air conditioner.

Fig. 6 shows the vertical section through the chamber according to line VI-VI of FIG. 1;

Fig. 7 is a fragmentary horizontal section in a section from Figure 3 along the arrow VII with one of a side wall projecting from support angle.

Fig. 8 is the detail of the detail of Figure 7 in perpendicular thereto sectional view top view of the support angle.

FIG. 9 the bearing angle enlarged compared to FIG. 8;

Fig. 10 is a partial section through a door of Figure 1 with subsequent plinth rich;

FIG. 11 is a plan view of a roof panel of the mobile telephone box;

FIG. 12, FIG. 13 enlarged sections from FIG. 11 according to their arrow XII or XIII;

FIG. 14 shows a cooling device indicated in FIG. 1 in front view;

FIG. 15 is the side view of FIG. 14;

Fig. 16, the cooling device of Figures 1, 14 in rear view.

FIG. 17 is the top view of Fig 14 to 16.

Fig. 18, 19 lateral and longitudinal section of another Room cell with installation elements;

FIG. 20 is the layout of FIG 18,. 19;

Fig. 21, 22 flow sketches for the transverse and longitudinal section corresponding to FIG 18, 19, showing flow paths in natural convection (first stage).

Fig. 23, 24, two sketches scheme for forced ventilation (second stage);

Fig. 25, 26 two sketches scheme to function as an air conditioner (third step).

A cuboid-shaped room cell or mobile radio box 10 made of concrete has a rectangular plan with an example outer side length a of here 240 cm and a width b of 180 cm and has a monolithically molded, parallel side walls 14 , 14 _a and end walls 16 connecting them to a base plate 12 a thickness e of 10 cm and a clear height h of 240 cm. In the upper edges 17 of these station walls 14 , 14 _a , 16 a step 18 of height 6 of about 6 cm and width g of 140 cm can be seen at 18 ; the remaining length e _{1 of} the remaining upper edge 17 corresponds approximately to the wall thickness e. This stage 18 forms with a ver in Fig. 5, 6 roof panel 20 a roof-close ventilation slot 22 , the design - in particular an outer cover with cover profiles 24 - can be taken as an example from DE 197 06 320 A1 as part of a switching station. Flow arrows x in FIG. 1 indicate the flow directions here.

The roof panel 20 of edge height z of 14 cm, provided by a vertex line 19 with two surfaces 21 inclined towards the edge, has a protrusion i of approximately 10 cm on the station walls 14 , 14 _a, which in the example of FIGS. 5, 6 taper upwards in cross section , 16 placed and fixed at the corners - in the area of anchor holes 26 - with the interposition of sealing plugs 27 by tie rods 28 . Then the mentioned cover profiles 24 in the area of the ventilation slots 22 - for example at dowel holes 23 - festge. In Fig. 1, the edge 20 _{a of} the missing roof plate 20 is indicated by dashed lines.

The provided on its inner surface with insulation panels 30 roof panel 20 has, according to FIGS. 5, 6 a - overlapped by a Dachkup 32 and encompassed by an outer edge collar 33 - ventilation opening 34 with fan 36 ; the hourly output is preferably 3000 m ³ . A circular projection of the tubular ventilation opening 34 is indicated in FIG. 1 at 34 _a , and in addition in FIG. 11 a - alternatively possible - rectangular ventilation opening 34 _r .

In an approximately central opening 38 of the side wall 14 is a left hinged door 40 of width b ₁ of about 90 cm and height h ₁ of 200 cm laterally deflected according to FIG. 1; near the joint cheek of the opening 38 in the sen threshold 39 an earthing plug 42 can be seen.

The cut-outs according to Fig. 7, 8 of the doorless side wall 14 _a blank on a side of a recess 44 of the length n of 16 cm and the length n ₁ of 32 cm a support angle 46 of length q recognize of 45 cm, the inner leg 47 at the Side wall 14 _a is screwed at 49 and the outer leg 48 of the width q1 of about 8 cm protrudes from the side wall 14 _a .

In the interior 50 of the concrete cell 10 are arranged in Fig. 1, 5, 6 on the end walls 16 at 52 transmitters or other electrical engineering cal devices for telecommunications, which generate relatively high power losses and whose service life depends on certain limit temperatures. In addition, on the door-free side wall 14 _{a there is} a cooling device 54 with a housing 56 of width s of here 65 cm, depth t of about 40 cm and height h ₂ of 180 cm. The air supply because of this, two openings 15 are provided in this side wall 14 _a according to FIG. 3 with ventilation grilles neglected in the drawing.

The cooling device 54 contains in its housing 56 - in front of and at the level of a supply air element of the side wall 14 _a equipped with filter mats - a condenser 59 and below it an evaporator 60 of a respective width s ₁ of 50 cm. A compressor 61 is sketched near the evaporator 60 and an air outlet opening 58 on the front surface 57 of the housing 56 facing the cell interior 50 ; Fig. 6 also shows a side air outlet opening 56 _a . The supply air enters cooled from the cooling device 54 into the mobile radio box 10 (arrow y), supplies it with cool air which is in heat exchange with the electrical devices and the heat loss via the fan 36 located in the roof plate 20 and the all-round ventilation 22 dissipates.

The cooling device 54 is mounted at a distance c from here 60 cm to the adjacent end wall 16 , and the cooling air outlet takes place on at least two sides of this cooling device 54 .

The condenser of the cooling device 54 is cooled by a separate air circuit, which is maintained from - located in the cooling device 54 above - radial fans 62 and via an air supply grille in the concrete wall of the mobile radio box 10 and via an air grille located above the supply air grille in the concrete wall the outside air is formed. Supply air flow and exhaust air flow can also be routed through a common grille.

The cooling devices 54 are designed in such a way that they have the same sizes and the same connection dimensions for both 4 kW and 7 kW or 10 kW power loss in the mobile radio box 10 , both because of the standardization (series production of the housings) and because of the constant shapes of the room cells 10 made of concrete, moreover because of the interchangeability in one.

In addition to the cooling device 54 , a low-voltage distribution 64 with a width t ₁ of 30 cm and a height k of 90 cm is arranged at a distance k ₁ from the base plate 12 .

The room cell or mobile radio station 10 _a of FIGS. 18 to 26 is cast monolithically and closed at the top by a roof plate 20 . Its walls 14 , 14 _a , 16 are just as thermally insulated as the single-leaf security door 40 . The weight of the room cell 10 _a without devices is 70 kN.

The configuration with devices can be designed variably and, in the example shown, consists of four switch cabinets 52 - a width which also corresponds to the depth t ₂ of 60 cm and a height h ₃ of 200 cm - and a low-voltage distribution 64 . A cooling device 54 of depth t of 34 cm and height h ₂ of 205 cm is installed behind a special fan element 66 on the side wall 14 on the door side as part of the ventilation concept.

The mobile radio station 10 , 10 _a has special requirements with regard to the internal temperature. Accordingly, with a maximum outside temperature of 35 ° C and a power loss of the installed devices of 7 kW, an inside temperature of 35 ° C must not be exceeded. A three-stage ventilation and air conditioning concept is used to ensure these conditions. In the first stage 22, the dissipating heat loss by natural convection, ie, by a supply air louver 68 dust filter mat and an exhaust-rotating vent 70 takes place according to FIG. 21.

When the outside temperature rises, the heat loss is removed in the second stage - FIGS. 23, 24 - by increasing the ventilation throughput with the aid of a fan 36 _a installed in the rear wall of the station. If the limit temperatures of 35 ° C. are reached in the second stage in the station interior 50 , the cooling device 54 switches on for the supply air, so that the supply air flow of stage 2 is additionally cooled. The heat dissipation of the cooling device 54 takes place via a ventilation circuit - supported by a separate fan.

Both the supply air opening to room cell 10 _a and the ventilation openings of the cooling device circuit are covered by a specially designed common ventilation blind. Direct weather influences on the cooling device 52 are excluded. This construction ensures a high level of property protection.

There is also the option of working on the remaining three Unrestricted insertion of cables into the station sides.

The effectiveness of the system described was documented by a test in a climatic chamber, in which three radiators with a total of 7 kW heating power were installed to simulate the power loss of the devices, which were permanently switched on for the duration of the measurement series. The regulation of ventilation levels 2 (fan) and 3 (cooling unit) was set so that the fan switched on at a room temperature of 30 ° C and switched off again at 25 ° C, the cooling unit switched on and off at a room temperature of 35 ° C Switched off again at 27 ° C.

The room sensor for the control was located in the middle of the room between the devices at a distance of about 15 cm below the roof panel 20 . Fifteen thermocouples were positioned in order to be able to record the development of temperatures at various points throughout the interior.

The investigations in the climate chamber should be the Determination of the temperature distribution in the room, the determination the average room temperature and the determination of the appropriate positioning of the room temperature sensor for control the fan and the air conditioner. For this purpose, ambient temperatures were gradually increased from 10 ° C set to 35 ° C. According to DIN 8900, part 2, adjusted the relative humidity.

Twenty minutes after the heat load was switched on, it was shown that the ambient temperature of 10 ° C exceeded the limit of 35 ° C on the room sensor, so that ventilation levels 2 and 3 were in operation. It was obvious that the room sensor hung under the roof in a heat cushion, as is also known from measurements of transformer ventilation tests.

In the course of the tests, the position in front of the rear wall below the fan was determined for the optimal position of the room sensor, which is to record the average room temperature for the control of ventilation levels 2 and 3 .

After repositioning the room sensor, the continuation of the measurements showed that ventilation level 2 was able to keep the room temperature below 35 ° C up to an ambient temperature of 30 ° C. Since it was also assumed that ventilation level 1 (natural convection) was sufficient at lower ambient temperatures, the climatic chamber was reduced to 5 ° C at the end of the tests.

Further metrological investigations took place in the open area. The location was chosen so that the cell phone station 10 _{a was} free all day in the sun and wind.

The measurement arrangement was based on the results of the metrological examination in the climate chamber. The regulation of ventilation level 2 - fan - has been retained (on at 30 ° C, off at 25 ° C room temperature) and that of ventilation level 3 (cooling device) has been changed so that the cooling device switches on at 35 ° C and at 30 ° C switched off again.

The sensor E for the detection and regulation of the average room temperature was positioned on the rear wall 14 a below the fan 36 a. The metrological investigations in the climatic chamber were confirmed in such a way that even at daytime temperatures above 30 ° C - as they were achieved on the measuring days in the open air - ventilation level 2 was able to keep the average room temperature below, even with a permanently switched on heat load of 7 kW of 35 ° C, so the cooling unit did not switch on.

The positions of two inside temperature sensors F and one outside temperature sensor G can be seen in FIGS. 19, 20 with distance dimensions (r = 110 mm; r ₁ = 100 mm; r ₂ = 180 mm, r ₃ = 80 mm) that illustrate the positions.

When the outside temperature cooled below 20 ° C, the fan switched off 3%, so that ventilation level 1 was reached, ie the room temperature was below 25 ° C.

After about ten minutes, the room temperature rose again to 30 ° C, so that the fan switched on again 3%. Over the duration of this series of measurements of about 94 hours, the running time of the fan was 3% (ventilation level 2 ) about 78 hours (= 83%), so that ventilation level 1 was sufficient for about 16 hours (= 17%). During this period, the outside temperatures ranged from 34 ° C to 14 ° C.

In a further series of measurements over 23 hours, in which the internal heat load was reduced to 5 kW, the running time of the fan was 18 hours (= 78%), ventilation level 1 was therefore sufficient for 5 hours (= 22%). During this period, the outside temperatures ranged between 33 ° C and 13 ° C.

The metrological investigations have shown that with the 3-stage ventilation concept according to the invention multifunctional, economical solution especially for the high demands on mobile radio stations with regard to of the internal temperatures to be observed was found.

The station 10 , 10 _a with this ventilation concept is characterized by robustness, maintenance improvements and greater economy. All important functional units are arranged within the protective concrete jacket. Operation is low-maintenance and energy-saving, since the function of the cooling unit is only required over a short period of time - seen over the year - ie in extreme - that is, rare - temperature conditions.

In conclusion, it should be noted that the inventive three-stage ventilation concept in the context of Invention also in others - not described here - Space cells are used for electrical installations can.

Claims (20)

1. space cell for protecting a transmitter system or other electrotechnical devices for telecommunications with at least one fan element and ventilation openings in at least one cell wall, characterized in that in a ventilation opening ( 34 ) of the roof area of the space cell ( 10 , 10 _a ) at least one fan element ( 36 ) and at least one cooling device ( 54 ) for cooling the interior air are arranged in the interior ( 50 ) of the room cell. 2. Room cell according to claim 1, characterized in that the cooling device ( 54 ) is arranged at least one wall opening ( 15 ) of the cell wall ( 14 _a ) on the inside. 3. Room cell according to claim 1 or 2, characterized in that the cooling device ( 54 ) is assigned to a fan element. 4. Space cell according to claim 2 or 3, characterized in that a condenser ( 59 ) and an evaporator ( 60 ) of the cooling device ( 54 ) are arranged upstream of the wall opening / breaks ( 15 ), at least close to the evaporator in the front wall ( 57 ) of a housing ( 56 ) of the cooling device, an air outlet opening ( 59 ) is provided. 5. Room cell according to one of claims 1 to 4, characterized in that the cooling device ( 54 ) is assigned a separate air circuit. 6. space cell according to claim 4 or 5, characterized in that above the condenser ( 59 ) at least one Ra dialventilator ( 62 ) of the cooling device ( 54 ) is arranged. 7. space cell according to claim 5 or 6, characterized in that the air circuit of the cooling device ( 54 ) is guided via an air supply grille in the wall ( 14 _a ) of the space cell ( 10 , 10 _a ) and an exhaust air grille above the supply air grille. 8. Room cell according to one of claims 1 to 7, characterized in that the condenser ( 59 ) of the cooling device ( 54 ) is a supply air element, for example an all-round ventilation ( 22 , 24 , 70 ) of the room cell ( 10 , 10 _a ) upstream , 9. Room cell according to one of claims 4 to 8, characterized in that the cooling device ( 54 ) on the cells rear wall ( 14 _a ) is arranged off-center and both in the front wall ( 57 ) of the housing ( 56 ) and on a side wall contains an air outlet opening ( 58 , 58 _a ). 10. space cell according to one of claims 1 to 9, characterized by a supply air blind with Dust filter mat in the heat dissipation flow. 11. Room cell according to one of claims 1 to 10, characterized in that in the room cell ( 10 , 10 _a ) a plurality of control cabinets ( 52 ) and a low-voltage distribution ( 64 ) are arranged. 12. space cell according to one of claims 1 to 11, characterized by a ventilation blind of the Air intake opening.   13. space cell according to claim 12, characterized in characterized by a common ventilation blind for the supply air opening and the ventilation openings of the Refrigerators circuit. 14. Method of air conditioning a room cell for protection a transmitter system or other electrical engineering Ge councils for telecommunications according to at least one of the preceding claims, characterized in that the supply air is ge with an internal cooling unit is cooled while an overlying one Ventilation element is actuated. 15. The method according to claim 14, characterized by a first stage in which the dissipation of the heat loss is carried out by natural convection ( Fig. 21, 22). 16. The method according to claim 14 or 15, characterized in that the dissipation of the heat loss is carried out in a second stage by increasing the ventilation throughput by means of ventilation ( Fig. 23, 24). 17. The method according to claim 16, characterized in that that at a temperature limit of around 35 ° C inside the cooling unit for the supply air is switched on. 18. The method according to claim 17, characterized in that that the supply air flow is additionally cooled. 19. The method according to claim 17 or 18, characterized characterized that the heat dissipation of the cooling device via a separate ventilation device is carried out.   20. The method according to any one of claims 14 to 19, characterized by a cooling interval as the third Treatment stage.