WO2018158071A1 - Externally integrated reformer control unit for a submarine - Google Patents

Abstract

The invention relates to a reformer for a submarine, the reformer having a reformer housing (10), the chemical reaction occurring within the reformer housing (10), the reformer additionally having a control housing (20), control electronics for controlling the reformer being arranged within the control housing (20), the reformer housing (10) and the control housing (20) being spaced apart from each other, the reformer housing (10) and the control housing (20) being connected to each other in a shock-elastic manner.

Description

 Exterior integrated reformer control unit for a submarine

The invention relates to a reformer with control electronics for a submarine. In a submarine many components are integrated. As a result, in particular the wiring within the submarine is very complex. Lines are subject to defense equipment standards for integration into a submarine and are classified into four categories. This is important in order to avoid an interaction between the different lines in the extremely large number. Therefore, only lines of the same category are moved adjacent.

On the other hand, it is necessary in a submarine to be able to control vital functions from the submarine's control room. This makes it necessary to relocate the corresponding electronic connections through the submarine.

The object of the invention is to provide a reformer for use in a submarine, which meets the high integration density and safety requirements.

This object is achieved by a reformer having the features specified in claim 1. Advantageous developments will become apparent from the dependent claims, the following description and the drawings.

The inventive reformer for a submarine has a reformer housing, wherein the chemical reaction takes place within the reformer housing. The reformer additionally has a control housing, wherein control electronics for controlling the reformer are arranged within the control housing. The reformer housing and the control housing are spaced apart. The reformer housing and the control housing are shock elastic connected to each other. By the spacing of the reformer housing from the control housing primarily three things are achieved. On the one hand, this leads to a thermal decoupling. The actual reformer works at high temperatures that are too high for electronics. An integration of the control electronics in the reformer housing is therefore thermally problematic. By the spacing is further achieved that in case of shock reformer housing and control housing can move apart from each other and so the reformer as a whole can be trained better shockproof. By spacing, however, electronic connections must be made between the reformer housing and the control housing. However, this third point is disadvantageous because strict rules apply to the laying of electronic lines on submarines, on the one hand, because of the high number of connections required, the additional integration of further lines is always problematic. Thus, other lines influence the constructive view of the submarine. This third point is inventively compensated by the fact that the reformer housing and the control housing are shock elastic connected to each other. As a result, there is a large spatial proximity, whereby the electrical lines between them are not subject to the strict rules of laying on board a submarine. Due to the shock-elastic connection, the reformer housing and the control housing can be separated and move independently of each other in case of shock. A submarine reformer is suitable for use on a submarine. In particular, the reformer is suitable to be used in the environmental conditions of a submarine. This means in particular the usability at a variable ambient pressure of about 600 hPa bi 1400 hPa, possible low thermal signature, for the crew of the submarine harmless emission of gases and in particular shock-resistant construction and extreme reliability.

In a further embodiment of the invention, the reformer housing and the control housing are connected to each other via at least one wire rope spring element. Wire rope spring element consist for example of a wound into a spiral wire, which is connected on one longitudinal side with the reformer housing and on the opposite longitudinal side with the control housing. However, more complex designs are conceivable.

In a further embodiment of the invention, evaluation electronics, in particular for gas monitoring and at least one DC / DC power converter, are arranged in the control housing.

In a further embodiment of the invention, sensors are arranged in the reformer housing. The sensors are electronically connected to the transmitter. For the Monitoring requires a large number of sensors on a regular basis, one being the monitoring of process parameters and the other the composition of the gas in the reformer housing. As a result, a high number of lines is necessary.

In a further embodiment of the invention, the reformer housing is shock-elastic connected to the submarine and the control housing is shock-elastic connected to the submarine. As a result, the reformer housing and the control housing are also vibration decoupled from the rest of the submarine.

In a further embodiment of the invention, the control electronics for self-sufficient control of the reformer is designed. In the event of damage to the submarine, for example due to a shock load, it is advantageous if as many components as possible continue to function in order to enable emergency operation and thus the maneuverability of the submarine. Therefore, the control electronics is preferably designed so that it is still functional without a connection to the control station of the submarine.

In a further embodiment of the invention, the reformer housing and the control housing are connected to each other with at least one first electronic line, wherein the at least one first electronic line need not be considered constructive for the boat cabling in a submarine. In particular, connections between sensors and the control electronics regularly fall into this group.

In a further embodiment of the invention, the reformer housing and the control housing are connected to one another via at least one first cable track. Preferably, this cable path is at least partially disposed between the reformer housing and the control housing. Particularly preferably, this cable path is arranged completely between the reformer housing and the control housing. In a further embodiment of the invention, the reformer housing, at least in the region which is adjacent to the control housing, a thermal insulation or the control housing at least in the region which is adjacent to the reformer housing, a thermal insulation. As a result, the thermal decoupling can be optimized and the reliability of the control electronics can be optimized. Preferably, the reformer housing a thermal insulation on. It is also conceivable that the reformer housing and control housing have an insulation.

In a further embodiment of the invention, air is blown into the space between the control housing and the reformer housing. This happens to reduce the heating of the control housing.

In a further aspect, the invention relates to a submarine having a reformer according to the invention and a control station, wherein the control station is electronically connected to the control housing by means of a boat line.

Preferably, the boat line between the control station and the control housing has a higher quality than the line between the control housing and the reformer housing, the higher quality is a higher quality in at least one properties selected from the group comprising insulation strength, shielding, flammability, fire propagation, Release of corrosive or toxic gases, resistivity and dielectric strength.

The reformer according to the invention is explained in more detail with reference to an embodiment shown in the drawing.

Fig. 1 cross-section of a submarine with a reformer

In Fig. 1 is a cross section through a pressure body 40 of a submarine with a reformer is shown. Inside the pressure body 40, a reformer housing 10 is arranged, which is connected via shock-elastic bearings 80 with the deck 90 of the submarine. The reformer housing 10 is connected via cable spring elements 50 with a control housing 20. Through a cable track 60 run electronic lines between the reformer housing 10 and the control housing 20. As a result, these lines are not directly installed in the submarine itself and therefore are not subject to the strict requirements. The control housing 20 is also connected via shock elastic bearings 80 to the deck 90 of the submarine. In addition, the control housing 20 is connected to a control station 30 via a submarine compliant boat line 70. The control room can also be in another section of the submarine. The control station 30 can be for exclusive Monitoring and control of the reformer serve, but it can also be provided that the control station 30 monitors and controls other functions of the submarine.

reference numeral

 10 reformer housing

 20 control housing

30 control room

 40 pressure hull

 50 wire rope spring element

60 cableway

 70 boat line

80 shock elastic storage

90 deck

Claims

claims

A reformer for a submarine, wherein the reformer has a reformer housing (10), wherein within the reformer housing (10) the chemical reaction takes place, wherein the reformer additionally comprises a control housing (20), wherein arranged inside the control housing control electronics for driving the reformer is, wherein the reformer housing (10) and the control housing (20) are spaced from each other, wherein the reformer housing (10) and the control housing (20) are resiliently interconnected.

2. A reformer according to claim 1, characterized in that the reformer housing (10) and the control housing (20) via at least one wire rope spring element (50) are interconnected.

3. Reformer according to one of the preceding claims, characterized in that in

Control housing (20) an evaluation electronics are arranged in particular for gas monitoring and at least one power DC-DC converter.

4. A reformer according to claim 3, characterized in that in the reformer housing (10) sensors are arranged and the sensors are electronically connected to the transmitter.

5. Reformer according to one of the preceding claims, characterized in that the

Reformer housing (10) Schockeleastisch is connected to the submarine and the control housing (20) is Schockeleastisch connected to the submarine.

6. Reformer according to one of the preceding claims, characterized in that the

Control electronics for self-sufficient control of the reformer is designed.

7. Reformer according to one of the preceding claims, characterized in that the

Reformer housing (10) and the control housing (20) with at least a first electronic line is connected to each other, wherein the at least one first electronic line does not have to be considered constructive for the boat cabling in a submarine.

8. Reformer according to one of the preceding claims, characterized in that the

Reformer housing (10) and the control housing (20) via at least one first cable track (60) are interconnected.

9. Reformer according to one of the preceding claims, characterized in that the

Reformer housing (10) at least in the region which is adjacent to the control housing (20) has a thermal insulation or that the control housing (20) at least in the region which the reformer housing (10) is adjacent, has a thermal insulation.

10. Submarine with a reformer according to one of the preceding claims and a control station (30), wherein the control station (30) to the control housing (20) is electronically connected.