DE2517919A1 - Steam raising plant - with boiler which can be sunk into earth's crust, has telescopic moving boiler top with internal earth roof transport or guide shaft - Google Patents

Abstract

A steam production or raising installation, in partic. for use in utilizing underground energy, has a boiler which can be sunk into the surface of the earth and which has an auger type cutter mounted to its base and supported from the ground surface outwards. The boiler (1) is constructed in the form of a hollow cylinder with the internal tube or pipe (10) acting as the transport or guide shaft for the earth roof as well as the stabiliser for water (11) steam (9) and oil pipes (19).

Description

Automatically retractable boiler Trit telescopic boiler and additional. internal, adjustable heating sands for generating energy from the interior of the earth, - Can also be used as a manufacturing device for the construction of manholes - for extreme depths and / or diameter, as a mechanical method; as well as compressed air, ultrasonic or laser drilling as a non-mechanical process in single use or in mutual Combinations.

=================================================== ======== 1st preliminary remark Ideas and suggestions to generate energy by using geothermal energy are known for a long time. However, the construction of e.g. power plants in the interior of the earth implies construction measures ahead in a way that has not previously been feasible.

Assuming that power plants could be built in the earth's interior or would be built, such as the Offenlegungsschrift No. 1,812,348 or the Patent No. 361,473 (88 d, 7/04) provide, the question of the effective one remains Performance of such systems because they use considerable amounts of energy reused for own operation would have to be there necessary cooling units, ventilation systems, pumps and the like in operation keep; Not to mention the additional maintenance that is required underground.

2. Everything. Description of the Invention This invention is used the boiler to be brought into the earth at the same time as a drilling device. This is going through its special design is possible by designing the boiler as a hollow cylinder who carries, stores and guides the broaching tools at its lower end.

The overburden, as well as the possible change of the broaching tools, takes place through the hollow cylinder 10 of the boiler 1.

The automatically retractable boiler (Fig.l) can be dimensioned in this way be that one or more boilers 1 and 40 - each on the same principle work - telescopically in connection with broaching tools in any desired depth can be lowered (Fig. 4).

The additional use of one, by the boiler system or systems centrally located oil heating probe that can be regulated by the oil level and its depth can be independent of the boilers, 1. enables additional heat supply the or the boiler 1 and 40 (Pig.4) over the hollow cylinder of this (Fig.5), 2. the Heating of an above-ground boiler system.

The boiler 1 is omitted for the creation of shafts; the broach ] 4 is only used in connection with the inner tube or hollow cylinder @O @ The invention is therefore based on the fact that the boiler systems actually into which Erdinners can be introduced up to a depth of a few thousand meters, their diameter can be up to several meters.

In this way, the geothermal energy can be used economically.

In addition, there is no need to extract energy for the boiler system's own operation or systems, as there are no additional operating units such as cooling devices and the like

Find use.

On the contrary, due to the high gradient of the boiler feed water from the The surface of the earth to the sunken basin of up to several thousand meters deep and the resulting negative pressure in the systems above ground becomes higher there Efficiency, e.g. in low-pressure turbines.

It should be mentioned that the shaft drilling rig is also used: e.g. for the construction of underground tank systems and depots, which for reasons of Storage and security should be brought to greater depths, with the The landscape is preserved.

In the vicinity and along rivers, deep wells can be used as drinking water collectors be created with a high degree of cleanliness of the water that the river and Groundwater through the natural filter properties of soil and rock (gravel) seeps to the deep wells.

The economic viability for such uses results from that with the drilling process into the depths, the required shaft or container wall is placed in the earth.

An embodiment of the invention is shown below with reference to FIG Drawings described.

In these, FIG. 1 shows a section through the automatically retractable bar Boiler with gear and clearing tools Figure 2: View of the clearing tools retracted Figure 3: Extended view of the clearing tools (working position) Figure 4: Section through primary and secondary (Teleskon) boiler Figure 5: Section through primary or Secondary boiler with probe Figure 6: Section through the probe.

3. Technical description of the invention 3.1 Boiler As Fig.l shows, the invention relates to a boiler 1, which is designed as a hollow cylinder is. The boiler 1 is equipped with two chambers, whereby through the lower part 3 of the boiler 1, the upper chamber, the kettle 4 with an overlying steam room 5 forms.

The water level in the kettle 4 is built-in, not shown Swimmer kept constant.

A tube 6 located in the steam chamber leads through the boiler bottom 3 Steam through the outlet 7 into the superheater chamber 8.

From there the superheated steam is in the steam riser pipe 9 to the Not shown steam turbine plants releated on the earth's surface.

Another particularly constructive feature. of the boiler / l is in given its huge surface. The boiler 1 can be any height up to some hinders have meters. Due to the enormous height or length of the boiler 1 prevails a temperature difference between steam chamber 5 and Wesselboden 2, which is the result results. that on the one hand the temperature inside the earth increases with increasing depth, Otherwise, water and steam space 4 and 5 and superheater space 8 in a volume ratio for example 1: 4.

The interaction of the factors: exceptionally large boiler surface, Temperature increase in the earth's interior with increasing depth, determinable volume ratio between water 4 and steam room 5 on the one hand and superheater room 8 on the other hand, ensure the function of the system.

The steam cycle described also causes a maximum heat exchange in the boiler by the superheated steam through the steam riser pipe 9 - the through the Water boiler 4 and steam chamber 5 leads - is passed and thereby to the heating of Water and steam contributes.

The solution of the kettle 4 is carried out via Wasserzuflußrchre ll. These can be arranged in such a way that they spiral around the inner tube 10 lying.

This causes an increased preheating of the water by increasing Geothermal energy causes at the appropriate depth.

as well as a cefall stroke is prevented.

3.2 Broaching tool The broaching tool 14 (Fig. 2) with gear housing 12 (Fig.1), which is stored in the hollow cylinder of the boiler l, kanr through the inner tube 10 and the boiler hollow cylinder l can be retracted and extended.

Breaking 28 and broaching tools 14 consist of at least two single and swiveling scraper caterpillars (Fig. 2 and 3), e.g.

Pivot in 22 to retrieve and spread out at work rotation 23 and rit their rollers 16 on the boiler bottom 2 support.

For this purpose, the boiler bottom 2 is designed to be particularly strong as a runway.

The overburden is in Arbeitsdrelung 23 of the clearing caterpillars 14 of these conveyed to the screw conveyor 15 and in front of this on the ring plate 17, from wc he is brought to the surface of the earth by means of a gripper, not shown.

Breaking 28 and Räumwerkveuge 14 can with additional, on the axes of rotation 26 and 27 bearing breaker cones 28 are embroidered. There. can, depending on requirements, either only the inner axes of rotation 26 or only the outer axes of rotation 27 or else both wire axes carry the crushing cones 28.

It is also possible to use the crushing cone 28 with different cone angles to @develop with the same Hegel surface in each case.

These arrangements act as primary crusher and favor the crushing process.

The gear housing 12, with its oil motors 18 in the cylinder ear 10 of the boiler 1 is performed. pingsu @ is provided with grooves, which are in the guide rails 13 of the cylinder tube 10 can be pushed in vertically and is thus secured against rotation.

Stop 13a prevents the gear housing 12 from being closed low, i.e. possibly below boiler bed 2.

Prech 28 and Abräumraupen 14, which in working rotation over the boiler diameter down @@@ gen. move on the one hand about their axes of rotation 26 and 27, on the other hand slowly around the axis A of the screw conveyor 15. (see arrows 29 and 30, Fig. 3).

The broaching tools 14 are driven here, for example, by oil motors 18 via the drive axles 26. The displacement of the three broaching tools shown in FIG 14 in the direction of arrow 30 is carried out by one or more separate (not shown) Oil motors via the ring gear 21.

This arrangement ensures that the feed rate in Direction of arrow 30 regulates itself automatically depending on the existing soil conditions, the regulation being effected by an overload protection in the oil pressure circuit or overpressure valve is installed.

It can also be provided that the clearing tools via the oil motors 18 14 be safe via the drive axles 26 in the direction of arrow 29 and that the same Motors t8 take over the feed via the ring gear 2] in the direction of arrow 30 at the same time.

The screw conveyor 15 is driven by means of appropriate angular gears likewise by the oil motors 18.

3.3 Telescopic boiler (Fig. 4) In order to penetrate even deeper into the earth, can be retrieved after gear housing 12 with broaching tools 14 of the boiler 7th are, through the hollow cylinder 10, a second boiler (telescopic boiler 40, Figure 4), the the same structure as the primary boiler including the gear housing 12 with clearing tools 14 has and its dimensioning is only the inner diameter of the Prlmärkessel 1 adjusts, be lowered.

For the best possible use of the heat from the earth's interior, it is intended through the hollow cylinder 10 of the primary boiler 1 and the telescopic boiler 40 a heating probe 42 (Fig.5) to be used, which can have any length, but at least from the upper edge of the primary boiler @ to far below the lower edge 41 of the telescopic boiler 40 reaches deep into the ground.

To insert the probe 42, the device is used as a deep drilling device - without kettle] - used. After retrieving gear housing 12 with broaching tools 14 can be in the Tube 43 (Fig.5) a separate probe 42 with a closed Soil can be introduced, or the pipe 43 can be used as a probe wall, inden at its lower winch e-in bottom by a plug 45, which means filler 46 is sealed, receives a closure.

The probe 42, which is still far deeper than the boiler 7 and 40 in the ground can be filled with thermal oil, for example, to act as an additional heat transfer medium to serve.

For this purpose, the oil level of the probe is up to the upper edge of the primary boiler 1 brought. In this way, the boilers brought into the ground are of inside with even higher temperatures from the larger Erdtjefen over supplies the probe oil.

A suitable filler or contact material between Clhe @ zsonn @ 42 @@@ Inner tube of the telescopic boiler 40 and the inner tube of the primary boiler l introduced is, transfers the higher temperature of the oil heating probe 42 to the hollow cylinder 10 of boiler (s) 1 and 40.

The particular advantage of having one or more boilers over a wide area deeper oil heating probe 42 also has higher temperatures from the inside to add is also due to the fact that in the event of a drop in the ambient temperature the boiler the function of this is fully preserved.

Claims (12)

Patent claims: 1. Steam extraction system, especially for energy generation aue the Earth interior, with to be submerged in its longitudinal axis boiler @ (Fig.l), which on his Floor 2 a milling and clearing tool 14 and 15 stores and leads and from the earth bar surface is controlled from, characterized in that the boiler @ as a hollow cylinder and the inner pipe 10 as a shaft for the overburden, also as a stabilizer for water ll, steam -9 and oil lines 19 is formed. 2. Steam generating plant according to claim 1, characterized in that that the boiler 1 in an overhead water space 3 and steam space 5, as well as in an underlying, large superheater space 8 is divided, with one side one or more steam pipes 6 from the steam space 5 into the superheater space 8 and on the other hand a steam pipe 9 from the superheater space 8 through the water 4 and 5 steam room. 3. Steam generating system according to claim 1 and 2, characterized in that that the gear 12 mounted on the bottom 2 of the boiler l can be switched on and off against Rotation secured in its guide 13 and in the working position in its longitudinal axis can be sufficiently mobile. 4. Gear 12 according to Amspruch 3 thereby gekeppseichnet that it is on Gear bottom one, two or more milling 28 and Abräumwerkseuge 14, as well as one guided in the center Conveyor screw 15 carries. being the arrangement a combination between mechanical and non-mechanical tools, as a pre-loosener agents, such as Can be compressed air, ultrasound or laser beams. 5. Milling 28 and Abräumwerkzeu @ e 14 according to claim 4, characterized in that that these are swiveled in 22 when introduced according to FIG Swing out automatically in the working direction of rotation 29 and 30 and slowly move around the Central axis A of the transmission 12 move over a ring gear 21 to move with their. Push support rollers 16 under the boiler bottom 2. The arrangement as in FIGS. 2 and 3 can be such that the tools are designed in the same way or that with several wräs- 28 and clearing tools 14 different types of tools with different cutter positions are used Find. 6. Transmission 12 with milling 28 and clearing tools 14 according to claim 4 and 5 characterized in that the tools rotate in the opposite direction swivel in (F17. 2) in order to be able to be brought back to the surface of the earth. 7. Gear 12 with milling 28 and clearing tools 14, as well as conveyor worm 15 according to claim 4 bi.s 6 characterized in that the drive preferably means Oil motors 18 takes place. 8. Steam generating plant according to claim 1 to 7, characterized in that that a second steam generating system - a telescopic boiler 40 - (Fig.4) is the same Design and according to the inner diameter of the inner tube 10 of the primary system 1 (Fig.l and 4) through this first system, lowered to even greater depths can be. 9. Steam generating plant according to claim 8, characterized. that after retrieving the second, smaller clearing tool of the telescopic boiler 40 is advanced to even greater depths by inserting a drill pipe 43 (Fig. 5) is, rn which a probe 42 is lowered as a tube with a closed pod or that Pipe -3 is provided with a floor that is at least up to the top edge of the Steam space 5 of the first steam generating system (Fig. 1) filled with thermal oil is thereby also primary 1 and secondary boiler 40 (Fig.4) from the inside or to feed with warmth only from the inside. 10. Steam generating system according to claim 1 to 9! characterized, that the probe 42 (FIG. 5) extends to the surface of the furnace and with a filling tube 44 is provided, which extends to the bottom of the probe. 11. heat recovery system, characterized in that the probe 42 (Fig.6) according to claim 10 without primary 1 and secondary boiler 40 by methods such as in claim 12 or, if possible, introduced into the ground according to a conventional roughening method will. 12. Plant, in particular for the production and construction of manholes and / or underground depots, work or shelters, storage and tank facilities, Wells and groundwater collecting tanks up to large diameters and / or extreme ones Depths according to claim 1, 3, 4, 5, 6, 7, 8 characterized in that the bore at the same time shaft wall, linings, insulation or the like created or can be introduced. L e r s e i t e