DE202006008193U1 - Air conditioning system for diffusion-inhibited protective clothing - Google Patents

Abstract

climate system for diffusion-inhibited protective clothing, like so-called ABC suits or similar, consisting of a preferably by thermoelectrics, cold or Heat generating Energy part and a converter that transfers the energy through a metal Contact area, the form-fitting on the heat or cold donating metal surface of the energy part is, absorbs and by means of a fan a certain amount of air by a hose-like connection to a circulatory hose line on a worn inside the suit vest leads, the is also designed as an energy converter and the cold or heat energy over the vest into the interior of the protective suit and through the reflux through the converter or cold energy leads into the atmosphere, characterized in that the circulating hose line on a worn inside the suit vest from a elastic, partially permeable wrapping from good heat-conducting Material exists.

Description

The The invention relates to a climate system for diffusion-inhibited protective clothing, like so-called ABC suits or similar, consisting of a preferably by thermoelectrics, cold or Heat generating Energy part and a converter that transfers the energy through a metal Contact area, the form-fitting on the heat or cold donating metal surface of the energy part is, absorbs and by means of a fan a certain amount of air by a hose-like connection to a circulatory hose line on a worn inside the suit vest, which also is designed as an energy converter and the cold or heat energy through the vest in the interior of the protective suit and passes through the return flow through the converter Warmth- or cold energy into the ambiance.

It are climate systems for the mentioned Application known with various air conditioning techniques such as absorbers, Zeolite technology etc. are built. The wearer of a protective suit generates in high ambient temperatures about 300 W, based on the entire Body surface. The known systems try to dissipate this energy from the body. That's possible, but it does too big, heavy Air conditioning systems from 6-10 kg weight and more. These need additionally correspondingly large Batteries for the primary energy; as well as the heated ones Air is directed into the atmosphere, as well as large filter systems in case of a used ABC suit. One recognizes that these devices for the mobile Use, such. For example, in soldiers who restrict mobility.

task This invention is intended to avoid the disadvantages described above and to create a climate system that is compact, lightweight and versatile Depending on the type of protective suit to use and that is the mobility of the wearer of the Protective suit not hindered. This is especially true of soldiers of big advantage. In thermodynamics one does not speak of cold but only from heat. For general better understanding for the The present invention will be terms such as cold, heat, tempering in the following used accordingly.

It is provided only the upper torso area of the wearer of the Protective suit to cool and especially the chest and neck area. This applies to a well-being as sufficient, as well as medical experts confirm. From therefore, a heat dissipation of approx. 50 to 150 W with a duration of approx. 2 hours. Therefore, also reduce the applied energy output, the Size and that Weight of the air conditioner etc. It is the advantage of the invention that the system specifically the heat dissipation reached to the trunk area. It is intended not to overly cool the area or to warm, but at the trunk area an approximately constant temperature of approx. To reach 27-30 ° C, allowing air conditioning at different ambient temperatures is reached. As energy producer is the thermocouple technology preferably to use. The efficiency is not very high, but it has a very small design, is very easy to fix and needs as primary energy only electric power. It can also be done simply by current reversal at low ambient temperatures the interior of the protective suit heated become. In particular, the provision of the electricity is through the rapid progress of battery and battery technology also on weight very cheap per watt. Therefore, the efficiency of the Themoelement technique is good to increase. So are already batteries with a capacity of 30 Ah at a current decrease of 4 A or more at a weight of about 200 grams for a long time in trade. Another big one Advantage of the invention is that the whole system no air exchange to the ambience required and so no additional filter units against ABC ambience needed.

The invention is based on an embodiment ( 1 - 10 ) explained. 1 shows as a simple sketch the three main components. The energy part ( 7 ), the converter ( 6 ), the cooling vest ( 2 ) in the chest area ( 3 ) and in the neck area on the body, and two hoses ( 5 ), which connect the cooling vest with the converter. 2 and 3 show a protective suit ( 1 ) and the cooling vest ( 2 ). At the cooling vest one recognizes a hose line ( 9 ) from the lower left chest area over the neck area to the lower right chest area as circulation with the tubing ( 5 ) and to the converter ( 6 ) leads. If the converter and power unit are carried outside the suit, the hose leads ( 5 ) via a coupling connection ( 8th ), which is attached to the protective suit, from the interior of the protective suit to the converter. This type of couplings ( 8th ) are state of the art. So you can see that the whole air conditioning unit during use does not change the gas-tightness of the suit. In the invention it is also possible to carry the converter inside ( 3 , Pos. 6 . 7 ). Then the fabric of the protective suit lies between the internal converter and the energy part. Thus, the air conditioning through the protective suit passes. This feature will be described in more detail below.

4 shows the climate changes ( 1 ), the hose at the vest ( 13 ) and the connecting hose line ( 2 ) to the converter ( 3 ), in full section the converter ( 3 ) and the energy part ( 4 ). You can see the so-called heat sink at the energy part ( 7 ) - these are the comb-like profiled metal parts from good thermally conductive material - with the thermo-elements ( 8th ), the fan ( 9 ), the battery part ( 10 ) and an electrical control part ( 11 ). Structure and function of the energy part ( 4 ) show the classical structure of a thermo-elements (also known as Peltier technique) operated refrigerator and are state of the art and therefore need not be described in detail. This also applies to the structure of the converter ( 3 ) with a heatsink ( 5 ) and a fan ( 6 ).

The difference between the present invention and the known systems is that the second heatsink (depending on the application, heat- or cold-dissipating) 5 ) of the converter ( 3 ) not solid or nearly integral with the heatsink ( 8th ) of the energy part ( 4 ) connected is. The heat transfer takes place by planar concerns of Heatsink surfaces to each other by means of a releasable clamping or holding connection. The fan ( 6 ) in the converter ( 3 ) leads the tempered air through the heatsink ( 5 ) in the circuit of the hose ( 13 ) on the cooling vest ( 1 ).

6 shows the cross section of the hose ( 13 ) on the vest. In the west area, the hose consists of a metal knit ( 17 ), which around an elastic, spring-like constructed spiral part ( 18 ) is woven. This prevents that especially in the shoulder region of the hose is compressed by load, as it is z. B. by equipment that are worn with straps on Schultenr may occur.

5 shows a partial section of the vest. The hose of the vest including the supply lines and the flow in the converter have only a total gas volume of about 1.5 ltr. This allows the air to be quickly transported through the fans in the converter as a circuit and to absorb cold well. The metal fabric of the vest tube ( 13 ) preferably consists of a good heat conducting aluminum. The vest tube has an extremely large upper surface due to the metal knit and can absorb cold inside as well as release it to the outside. The vest consists of spacer fabric, which with distance cams ( 14 ) is executed, and has large spaces, so that by small fans ( 4 , Pos. 15 ) the air in the vest can circulate again, flows around the vest tube and through several openings ( 21 ) can also be exchanged with the surrounding warm inner air of the protective suit. The effect is supported by the fact that the structure of the metal fabric, as a fabric, also partially allows an exchange of air ( 5 , Pos. 20 ), but at the same time the largest amount of circulating air ( 19 ) remaining in the circuit, the system can flow unhindered. The surface of the metal knit supports this effect, since the boundary vortex formation is strengthened, which again works well for the cold transport from the west tube to the west volume.

7 shows an embodiment in which the heat-transmitting outer surfaces of Heatsinks ( 3 ,) of the converter ( 1 ) and heatsinks ( 8th ) of the energy part ( 2 ) are concave-convex to each other. A strong permanent magnet ( 10 ) equipped with a device ( 11 ) is axially displaceable, is in the center of the heat sink of the energy part ( 2 ) embedded. The converter ( 1 ) has opposite the position of the permanent magnet, a metal plate ( 7 ), so that both parts are held together with the magnetic force and the heat transfer can take place. It can also be the fabric of the protective suit in between, and the heat or cold can still flow from the converter to the power part. Depending on the thickness and thermal conductivity of the suit material, a reduction of the energy flow occurs. This can be partially compensated by increasing the energy of the energy part. For very thick fabrics ( 12 ) of the protective suit can at the point of energy transfer, a thin film with good thermal conductivity ( 13 ), z. B. made of aluminum, gas-tight, so that the heat exchange takes place almost without reduction of the efficiency. Thus, the interior of the suit can be tempered without a hose coupling on the suit is needed. It can be seen, as described above, the functional parts of the converter and the power part: fan ( 4 ), Supply to the vest ( 5 . 6 ) a ring-shaped thermocouple ( 9 ).

8th shows as a simple sketch a hose coupling ( 17 ) on protective suit ( 14 ) with the inner tubes ( 15 . 16 ) to the vest and the exits ( 5 . 6 ) of the converter ( 1 ) and the energy part ( 2 ).

9 shows that it is provided that the current-emitting batteries in a separate magazine-like part ( 18 ), which in a recess ( 19 ) of the energy part ( 2 ) can be plugged. This has the advantage that the application period of the air conditioning system can be extended indefinitely by simply replacing the battery magazine.

10 shows as a partial and full-sectional drawings an embodiment of the converter. You can see the case ( 1 ), the heatsink ( 5 ) with the external contact surface ( 6 ) to the energy part, the outputs ( 2 . 3 ) to the hose of the vest, the fan ( 7 . 8th ). With the profiled holding claws ( 9 ), the converter is fixed, but releasably attached to the power part. The current transfer from the power part to the fan operation of the converter serve the plug contacts ( 10 ) at a suitable point of the converter, which act connected to the corresponding contacts on the power part. In the lower flow area is a replaceable magazine-like Commitment ( 11 ), which consists of absorber or adsorber material. This is also flowed around by the air circuit of the system and can occur air humidity, the z. B. occurs during sweating of the suit carrier, bind and improve the air conditioning function of the whole system.

Claims (9)

Air conditioning system for diffusion-inhibited protective clothing, such as so-called ABC suits or the like, consisting of an energy preferably by thermoelectric, cold or heat generating energy part and a converter, the energy through a metal contact surface, the form-fitting on the heat or cold-emitting metal surface of the energy part, receives and by means of a fan air a certain amount of air through a hose-like connection to a circulating hose leads to a worn inside the suit vest, which is also designed as an energy converter and the cold or heat energy passes through the vest in the interior of the suit and by the backflow through the converter conducts heat or cooling energy into the ambience, characterized in that the circulating hose line to a worn inside the protective suit vest of an elastic, partially permeable envelope of good heat conducting mate exists. Air conditioning system for A diffusion-proof protective clothing according to claim 1, characterized in that the serving the hose on the vest made of a knitted fabric of good thermal conductivity Metal exists. Air conditioning system for Diffusion-inhibited protective clothing according to claim 1, characterized in that the converter connected to the vest with a releasable connection mechanism provided to the power part. Air conditioning system for Diffusion-inhibited protective clothing according to claim 1, characterized in that the contact surfaces of the converter and the energy part concave-convex to one another congruent are shaped. Air conditioning system for Diffusion-inhibited protective clothing according to claim 1, characterized in that in the power part for connecting the converter to the power part a magnet is installed. Air conditioning system for Diffusion-inhibited protective clothing according to claim 1, characterized in that in the converter a magnet is installed. Air conditioning system for Diffusion-inhibited protective clothing according to claim 1, characterized in that at a suitable location in the cooling circuit moisture-reducing material is installed. Air conditioning system for Diffusion-inhibited protective clothing according to claim 1, characterized in that the batteries for power supply in a separate magazine-like replaceable part are installed. Air conditioning system for Diffusion-inhibited protective clothing according to claim 1, characterized in that in the vest, independent of the main circuit consisting of converter, supply line and west hose, additionally one or more fans are installed.