DE3437750A1 - Auxiliary device - Google Patents

Abstract

The essence of this device consists of a refrigerator system, primarily for armoured combat vehicles. Heat emission can be controlled in time for camouflage purposes, and a fire-fighting apparatus and a cryogenic emergency repair device can be derived from the system context.

Description

Auxiliary device

«.Ooen-öcnaiJe-atrauc IU 2420 EUTIN. Telephone 04521/3319

This invention describes an auxiliary device, particularly for military Structures, mainly armored vehicles. The task is solved to carry out the tactical mission under more favorable conditions and to increase the survivability of the system despite adverse external influences o.a. The aim is to reduce the additional technical effort to keep small and to use the given facilities optimally or to increase their usefulness. The improvements related to the task concern the camouflage, fire extinguishing and emergency repair device, which in one of the embodiments according to the invention form a composite device that is an integral part of the overall system. This task is solved by a temporal, artificial incoherence of exergy and anergy flows by means of the decoupling effect of storage components and media. Because of the easy handling and In order to ensure that they can be procured, gases, preferably from the exhaust gas, are compressed and partially liquefied in a secondary process.

It has proven useful for understanding and systematizing that thermodynamically ^ approach to use the overall logical context to x-ray.

Camouflaging means reducing the detection capability of the detector to refuse meaningful information. Every meaningful piece of information is a measure of the degree of deviation from a thermodynamic one State of equilibrium and (according to Evans) a generalized measure of exergy. Shannon's information theoretic equation of Entropy is very similar to the general equation of the change in entropy when ideal gases are mixed

S (Q, X) = K Wj- In vr

where Q is a well-defined question, X is a knowledge of the answers the question, K is a yardstick constant and wj the probability for is the correctness of the ith answer to the question. Accordingly, wj = O means that the answer "i" is not possible and if wj

= 1

the answer is sure to be correct. In the latter case all other w) = 0 and thus S (Q, X) = 0, ie there is no uncertainty about the correct answer. Conversely, if all answers "i" are equally likely, then the entropy S (Q ₁ X) has a maximum - there is a minimum of information.

The entropy consideration is only useful if the system boundaries are known, just like the requirement of a well-defined question. The Shannon measure

I = S (Q ₁ X) - S (Q, X ')

with the terms S (Q, X) and S (Q, X ¹ ) for the uncertainties before and after receiving the message, means that the answers X and X 'are available to question Q before or after receiving the message . The following is the choice for the Shannon constant

K = k * N

where k is the Boltzmann constant (k = 1.38 · 10 * ²³ J / K) and N is the number of molecules in the system. For a single molecule in the system, N = I and thus corresponds to the smallest information unit of one bit.

1 bit = k-ln2 = 0.96 χ ICT ² - ³ J / K

This means that the minimum energy consumption at T (environment = 293K)

E _e = T _e k-ln2 = S-IO " ² "'J / bit

The total energy in cm ^{3 of} a cavity filled with black radiation, integrated over all frequencies, corresponds to the area under the spectral intensity distribution curve according to Plank's law of radiation. According to Stefan-Boltzmann's law, the density h "i> for such a radiator

ft * - /

This clearly shows that the radiation density is increased to the 4th power of depends on the temperature, otherwise constants appear in the equation. The emissivity and absorption capacity for a given temperature is constant for all bodies and its absolute value is equal to the emissivity of the black bodies at this temperature. So that stands Kirchhoff's law of radiation in accordance with the second law thermodynamics, otherwise surfaces assigned to one another would have to cool down and the opposite surfaces would have to heat up. In these thermodynamic equilibrium is not possible to recognize Information processing is inevitably associated with a reduction in exergy. According to Evans, information is a generalized hatred for them Ability to work, i.e. the exergy, and it applies

E _e = T ₀ - I

whereby this expression includes all previously known deviations such as the Gibbs and Helmholtz free energies. The quantity kT _{Q also} corresponds to the noise energy per degree of freedom in the system at ambient temperature T ₀ . The quotient T ₈ I / kT ₀ then corresponds to the signal-to-noise ratio.

For the information processing of a television picture is about the effort of 6 J is necessary, whereas prime movers certainly cause power losses of a few MJ / s and far more.

According to the chosen definition of camouflage, this means that the ability to detect can be achieved either by lowering the "useful signal level" or by increasing the interference signal level. The latter is commonly used also referred to as "deceiving", a sub-grouping for systematic reasons to "camouflage". The "useful signal" here is the unwanted transmission of information and must be minimized. The camouflage is then achieved when the object to be camouflaged is congruent with the pattern of the ambient noise. The signal power can be visual, acoustic, electrical, emit magnetic or gravity and matter event. It is difficult to suppress the signal emission from devices with high dissipation. This occurs to the greatest possible extent as heat, related to the signal power, which increases very strongly with the temperature disproportionately correlated (see above). This, associated with the inevitability of the design, power loss, which is considered undesirable No known method can be used to prevent a useful signal.

BATH ORIGINAL

For the solution of the given task it seems essential, to allow a series of individual measures to work together. Most important Step is the radical reduction in the power dissipation of the main propulsion engine. According to the teaching of DE-OS 34 03 097 an internal combustion engine is known which meets this requirement in an excellent manner. This internal combustion engine is also uniquely compatible with the overall system: simplicity, enormous power density, minimal fuel consumption and many others are mentioned as examples. Therefore, the interaction of the machine mentioned appears with the other according to the invention Facilities urgently needed. In the sense of the Hegel-Marx dialectic this strong change (reduction in power loss) leads to a qualitative leap in terms of quantity: it results Completely new possibilities of use, the system has unimagined paths open to it. On the basis of the second law of thermodynamics and since irreversibility is to be expected in all machines, an increase in entropy occurs with the loss of power, which, however remains quite modest in the said internal combustion engine. Since the residual heat emission cannot be canceled, the invention solves the task by a temporal decoupling between useful power and Power dissipation. This unnatural incoherence can be bought at a relatively high cost and is therefore in itself short, but limited critical phases that are important for survivability. During the usual operating mode, there is then increased loss of work to dissipate.

Corresponding facilities are available for the technical implementation of the various operating situations: The drive system and the auxiliary equipment is entrusted in non-critical situations with the task of compressing and liquefying an easily obtainable gas to be stored with increased heat dissipation to the environment. It has been shown that carbon dioxide is particularly suitable for this purpose is, it is easy to liquefy and versatile. In critical phases, e.g. in active combat processes, this liquefied gas is sprayed over the heated parts of the vehicle, whereby the evaporation, respectively. Sublimation, a significant drawdown of heat is to be realized. Since the heating of certain vehicle parts is predictable, fixed nozzle outlets and automatic dosing ... can be used will. The aim is to achieve a thermal radiation pattern that is matched to the surroundings so that there is no contrast whatsoever with it. A sensor system should control this adjustment.

Significant quantities of carbon dioxide can be obtained from the exhaust gases are by means of a compressor and a gas separator. The storage pressure in the container is limited to -60 bar at ambient temperature, but can possibly be increased considerably in the form of a supercritical fluid, the triple point is quickly overcome when relaxing and it uses sublimation, which creates what is known as carbon dioxide snow. This is extremely useful for both winter camouflage, such as also an excellent fire extinguishing agent. It is thus casually referred to the further purpose of the facility - flame-retardant effect and fire extinguishing. The same outlets that serve the cloaking device can also prevent fires. Besides, it is less dangerous' to store more flame-retardant equipment than fuel. the Containers can have manual extinguishing connections inside the vehicle, "and be divided into individual containers. The entire auxiliary device can also provide interior air conditioning.

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Furthermore, a simple operational cooling is thermally highly stressed To realize components, it should be borne in mind, however, that the cooling capacity ' must be provided by the machine.

About the phase shift between the incidence and output of power loss To enlarge it, it is proposed that the "anergetic" heat release be carried out in so-called heat packets. Suitable for "putting together" these packages for thermodynamic reasons only low-temperature storage, on best latent storage e.g. based on salt hydrate storage. In relation to their volume, these can hold a considerable amount of low-temperature heat and unload it as a package for a short time. These salt hydrate stores can be easily switched into the cooling water branch, for example, which then allow the cooler to be put out of operation for a certain period of time and the cooling performance through the decrystallization process to record. Outside the critical zone, this heat is released relatively quickly to the environment when the cooling system is switched over. The short-term heat emission can support a cooling device, which, in the form of an external water cooler, is briefly connected to (natural) watercourses and for rapid cooling cares. A special air cooler is also suitable, with a strong, targeted air jet loaded with excess heat for a accelerated recooling ensures. This hot air, released in short "heat packets", is less revealing than a heated object. To this For this purpose, an insulated shaft can be attached to the vehicle as a waste heat chimney, so to speak, to which the waste heat is passed on in gushes intermittently will. These measures can also be isolated with those now in use Driving machines coupled to the existing executions.

For the improved survivability of the system is made out of this auxiliary facility an emergency repair facility derived. This kind A quite universal emergency repair option is brilliantly caused by the use of the refrigerant. Through (strong) A drop in temperature can harden materials with a phase change. It is well known that simple but frozen sludge can achieve considerable strengths. To stabilize weakened components this freeze-solidification can be used e.g. using special Masses such as fiber composite materials with suitable impregnating agents. The best cryogenic repair masses can be determined by experiment. This procedure saves almost every tool, and can be used by almost everyone be carried out and promises sufficient success, since the initial strength can be safely achieved to a certain extent. Special repair knowledge is to be conveyed quickly with short instruction times. The most important aspect, however, is emergency repairs thanks to high-speed repairs even under the most adverse conditions. For the technical implementation, it makes sense to use known methods to lean against when laminating plastic. The refrigerant is for this Purposes in a minimum reserve. The repair compound can be applied by a spray gun-like device, wherein if necessary the components are mixed automatically. The extraction of heat is then caused by a spray device. So that the environmental warmth external insulation makes sense to be carried out (as far as this is possible) e.g. by means of detachable docks etc. The spray device must also be integrated into this insulation. This means that even protruding components such as beams and arms can be made makeshift prepare. Limits are only through the imagination of the user given!

BATH ORIGINAL

The technical implementation of the process of a cryogenic camouflage, fire protection and engine maintenance device can be carried out with the known, funds are carried out, which in their entirety and interconnection are, however, novel are. The process management is optimal in this context of use adapted to the real possibilities. "The refrigerant used is carbon dioxide, which in many respects (apart from the very high operating pressures) seems downright ideal.

The engine with a charge pump or the like is never redesigned so that the charge pump compressor forms an Ackert-Keller cold-heat pump in accordance with the reverse Joule-Rayton process. The air-cooler is the heat sink, the heat source is an additional heat exchanger, with a downstream cold steam heat pump, whose residual heat from the condenser is fed in to keep this actual refrigeration machine smaller and to increase the quality level.

This cold vapor heat pump is the actual refrigeration machine in it System, d: e expediently independent of the main propulsion engine is to be designed as an optimized unit. Of course one takes place Complete integration into the system in order to keep the expenditure on equipment small. The above-mentioned DE-OS discloses an internal combustion engine which Because of the very small losses, an independent refrigeration machine does not appear cheap. In this internal combustion engine, the system offers Irr.manente compression process the excellent chance, the XaIt airworm pump mentioned and to integrate the operating heat exchanges into the unit. The existing, connected heat exchangers are supplemented by those of the cold air heat pump and the cold gas heat pump. This becomes the additional Effort almost negligibly small.

In contrast to the usual refrigeration systems, the refrigerant forms an open circuit, i.e. the refrigerant carbon dioxide is extracted from the exhaust gas. taken, through compression, the all-clear and Separation from the nent gases. It is saved for the times of use and before use, it then removes heat, brings about and arrives thus a ci.e free atmosphere. Because the exhaust gases in larger amounts of nitrogen and hater (steam) is added, must be used to isolate the carbon dioxide cir.-e separator work. Through the compression and the all-clear a liquefaction of carbon dioxide and water takes place, some of which in Carbonic acid passes over. The necessary drainage can be different Way, either by adsorption already from the gas phase, e.g. by means of Zeoli.tr., or by expelling by means of a stronger one (Mineral) acid, e.g. sulfuric acid. The water must then be in one rubbing process,? .B. ■ can be separated by distillation. This I.'ebonvorgsng can incidentally by accepting and submitting solvation. Adsor worth.'on. In addition to their main task, these institutions are excellent Latent heat storage, rie rectification device of carbonic acid "can designed for intermittent or continuous operation. In this case, the cor nitrogen content poses no problem. The separated Nitrogen is via a relaxation organ, preferably "one" Relaxation turbine ,. ... ^ n a heat exchanger, un a part the exhaust gasonthal ;; ie absorb and release to the atmosphere. That We; -on its purity water is to be used for other purposes. *

ßAD ORIGINAL

The connection principle is indicated in FIG. 1. Here : nx bepch'.en that for the respective application i'a'i 3rd variants are conceivable. Ίπ ήνν schematisehen representation of Figure 1 has ö-is the ^vehicle.:. 'Su .- {tantriebsmaschine 1 with the VerbrennungslufteinlaL at 20 and de, ·; Vcv,;>'u ₌ - outlet 5. The exhaust gases are fed to the compressor 6 after they have been supercooled in the heat exchanger (WT) 4. The nachij.esch-rjltett · WT 14 causes the liquefaction of water and carbon dioxide: 5 :: · are broken down in the separating device 8, as is the 2, asf. ^: --Ti, er: components via the line 11 and the outlet 12 ίortleitung in front, with prior recording of the exhaust gas enthalpy in the WT 4. That liquefies--? Carbon dioxide reaches the storage container 9 and from there «gf. η dir distribution device 10. The enthalpy of liquefaction for the cast components is withdrawn from the system via the WT 14, which passes the withdrawn V / ar; to Atiaccphärv. The partial cooling heat of the condensate from this heat? -Ü '.-. Pcn process passes through the heat exchanger 17 into the main machine intake two, un-i v; ir.i, if necessary, discharged to the outside with the charge air cooler. The organic icrtor cooler VJT 19 can, under certain circumstances, be converted to the latent heat accumulator WT 21.

The structural design has according to the known C-rumisntzcn to be carried out, whereby it should be noted that the inlet throughput of operating materials and air in connection with the cited internal combustion engine is only a fraction of what a diesel engine or gas turbine is need, the flow of filtered air is in the ratio nocl vit.2 smaller. So, despite the amount to be paid, you can start at short notice. ".? R: c; er large amounts of heat, the relevant components such as Grütiiv; s and d. ^ rv 1. be tight! An advantageous gestaitun ^ sr-öglichku-i t -.Irili obtain.

BATH ORIGINAL

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Claims (5)

Expectations 1. Auxiliary device, characterized in that the thermal contrast of Formed with power dissipation in the form of heat to the environment time- ' borrowed can be canceled, preferably by using a refrigeration machine or heat pump system. 2. Device according to 1., characterized in that the excess heat is captured in (latent) heat storage. The discharge takes place via ordinary coolers, recooling devices via (natural) watercourses or via exhaust air shafts. 3. Device according to 1. ... 2., characterized in that carbon dioxide is preferably used as the refrigerant from the exhaust gases and that the separating device of the exhaust gas components has a latent heat storage function. 4. Device according to 1. ... 3., characterized in that the refrigerant escapes in an open circuit at the points which are specially to be cooled, or in the event of a fire are to be sprayed. 5. Device according to 1. ... 4., characterized in that the refrigerant hardens suitable repair compounds in order to achieve a Allow makeshift repairs. BATH ORIGINAL