DE102014018168B4 - Pipe flow power plant - Google Patents

Abstract

Tubular flow power plant (1) for utilizing the flow energy in pipelines, characterized by a tubular housing shell (10) made of metal, with two semicircular cutouts (12) in an arc shape, to the top of the tubular housing shell (10), in which on the horizontal outer sides screw sleeves (18 ), wherein a cutout 12) in the rear half of the housing shell (10) is arranged as a mounting opening, through which a turbine (13), with generator (14) and an electronic control and control device (15) introduced and in the housing casing (10) are fixed, and wherein on this cutout (12) an arcuate cover cap (27), with screw sleeves (18) on the outer sides and edge sealing strip (31) to the support surface, is screwed, which are removed for repair and maintenance work and can be put back on. and wherein the second cutout (12) is arranged to the top in the front half of the housing shell (10), as an opening for installation and removal of a protective grate (16) for alluvial debris and for removal of deposited debris, wherein to the inside of the housing shell (10). Insertion rails (17) for the protective grid (16) are mounted and hereby the protective grid (16) for cleaning work, including the accumulated Schwemmgut, removed, and wherein on this second cutout (12), in the front half of the housing shell (10) , an arcuate cover cap (28), with screw sleeves (18) on the outer sides and edge sealing strip (31) to the support surface, is screwed, and wherein in this cap (28) has a window (29) made of plastic glass for controlling the Schwemmgutablagerungen before the protective grid ( 16) is mounted, and wherein a disc-shaped Rohrabstellklappe (19), with a vertical axis (20) to the center, in the housing An insert (30) for the axis (20) of the disk-shaped Pipe flap (19) is mounted and to the top of the housing shell (10) has a hole-shaped opening to the outside, through which a shut-off device (26) is introduced to shut off the inflow, the cap (28) removed for cleaning and disposal of accumulated alluvium and can be screwed on again, and wherein a conical flow-accelerating tube (23) is attached to the inlet side of the housing shell (10) which is attached to the smaller diameter side of the housing shell (10) and to the larger diameter side of the inlet tube (23). the pipe flow, wherein with the cone-shaped pipe constriction, the flow in the housing edge l (10) is accelerated, and wherein a conical diffuser tube (24) to the output side of the housing shell (10) is mounted, ...

Description

The present invention relates to a Rohrströmkraftwerk in which in a tubular housing shell made of metal, a turbine with a generator and an electronic control and control unit are installed, to protect against Schwemmgut before the turbine, a protective grid is attached and for stopping the Wassserzuflusses a Rohrabstellklappe, and wherein a conical flow acceleration tube to the inlet side of the housing shell and a conical diffuser tube to the output side of the housing shell are mounted.

HYLOW, the European Commission's hydropower research project, has shown that in hydropower, the existing energy potential in the pipelines remains virtually untapped.

Many watercourses that contain considerable energy potential are simply removed without the use of the flow energy contained herein, such as baffles at the weirs, outlets of existing power plants, wastewater treatment plants, and process water in the industry.

This is mainly due to the fact that until now no suitable power plants are available with which the existing flow energy in the pipelines can be used.

The state of the art is in the writings AT 359 006 B . DE 10 28 948 B and DE 10 2008 054 361 A1 demonstrated.

AT 359 006 B shows a Rohrströmkraftwerk with semi-circular cutouts and an impeller chamber, which consists of an impeller ring with two half shells, which can be separated for repair work. The curved outflow provided in this invention slows down the flow rate in the tube flow power plant and, between the curved drain and the drainage channel, an expensive adapter and connector must be adapted and manufactured according to local conditions. In addition, no protective grid for alluvial material and no opening to the top to remove the accumulated debris is provided in this invention. Also missing in this invention, a Rohrabstellklappe for repair work.

DE 1028 948 B shows a Rohrströmkraftwerk with adjustable vanes for changing flow directions, such as for use in pumped storage power plants. For one-sided flow patterns, such as discharge devices in barrages, outlet channels of existing power plants, drainage of sewage treatment plants and process water drainage industry, a Rohrströmkraftwerk for changing flow directions is not mandatory and also very expensive. In addition, no protective grid for alluvial material and no opening to the top to remove the accumulated debris is provided in this invention.

DE 10 2008 054 361 A1 shows a Flussströmkraftwerk, which is not designed for pipelines, but especially for use in flow waters. The pilot mission took place on the riverbed of the Rhine. It is therefore not suitable for use as Rohrströmkraftwerk.

The object of the invention is to find a solution for a power plant, is implemented with the existing flow energy potential in the pipes in electricity.

This object is achieved with a tubular flow power plant described below:
The Rohrströmkraftwerk is installed in a tubular housing shell made of metal, in which two semicircular recesses are made in an arc shape to the top.

The first cutout, which is made in the rear half of the shell of the housing, will introduce a turbine with generator, in conjunction with an electronic control and control unit, and install it inside the shell of the housing.

In a variant, the turbine, with generator and the electronic control and control unit are attached to the inside of the arcuate cover cap, which can thus be lifted and reinstalled for repair and maintenance work,

The second cutout is made to the top in the front half of the housing shell. Through this opening a protective grid for alluvial material is installed in the housing shell. For this purpose, insertion rails are attached to the inside of the housing jacket. The protective grille can be removed for cleaning and removal of accumulated debris.

On the arcuate cutout in the front half of the housing shell, an arcuate cap is tightened with edge sealing strips above the protective grid. To the top of the cap is a window made of plastic glass, designed to control Schwemmgutablagerungen. The cap can be used for cleaning and to remove accumulated Schwemmgut be removed and screwed on again.

To stop the flow of water during maintenance and repair work, a disc-shaped parking flap, with a vertical axis, is installed in the front half of the housing shell. For this purpose, a plug-in device for the axis of the disc-shaped storage flap is attached to the inside at the bottom of the housing shell and the top of the housing shell a hole-shaped, sealable opening to the outside, in which case the shut-off of the inlet a lever-shaped parking device is attached. To the inside, a stop device for the pipe cap is mounted on the housing shell at mid-height.

To the input side of the housing shell a conical flow acceleration tube is attached, with the side of the smaller diameter on the housing shell and with the side of the larger diameter at the inlet pipe of the pipe flow. With this cone-shaped constriction, the water is concentrated and accelerated from the inflow pipe to the tubular housing shell out. This results in a higher flow velocity and better turbine performance in the housing shell.

A conical diffuser tube is attached to the outlet side of the shell, with the smaller diameter side on the shell and the larger diameter side on the flow tube. With this cone-shaped extension, a diffuser effect is achieved to the outlet side and thus achieved an improved water drainage.

As a further variant, a Rohrströmkraftwerk is provided in which, with the same size pipe diameter of the housing shell, and the inlet pipe and the drain pipe, instead of the conical Strömungsbeschleunigungsrohres on the input side and the conical diffuser pipe on the output side of the housing shell, the two end sides of the housing shell with overlapping pipe connection rings the inflow pipe and the drain pipe are connected.

The installation of Rohrströmkraftwerken in existing pipelines can be made relatively easy. For this purpose, a piece is cut out in the existing piping in the length of Rohrströmkraftwerkes and inserted the Rohrströmkraftwerk.

The Rohrströmkraftwerk can be installed on land, on the banks of a stream of water and also in a body of water.

Areas of application for the pipe flow power plant are above all discharge systems at the barrages, outlet ducts of existing power plants, waste streams in dams, sewage treatment plants and process water in industry.

Further details and advantages of the present invention will become apparent from the following drawings, with the description of an embodiment.

Show it:

1 the pipe flow power plant in horizontal section,

2 the cap for turbine, generator and control and control unit,

3 the protective grid for alluvial property

4 the parking flap at the flow inlet

5 the cover for the protective grid

6 the cap, with attached turbine with generator and control and control unit.

7 the pipe flow power plant with overlapping pipe connection rings on both end sides.

1 shows the tube flow power plant 1 in horizontal section. It is in a tubular housing jacket 10 built of metal, in which two semicircular 12 Cutouts are attached to the top. In the tubular housing shell 10 Metal becomes a turbine 13 with generator 14 built-in. These are associated with an electronic control and control unit 15 ,

To protect against debris is in front of the turbine 13 a protective grid 16 attached. These are to the inside of the housing shell 10 Einsteckschienen 17 appropriate. The protective grid 16 Can be removed for cleaning and removal of accumulated debris. To shut off the water flow is a disk-shaped pipe shut-off 19 with a vertical axis bar 20 installed to the middle.

To the input side of the housing jacket 10 becomes a conical flow acceleration tube 22 attached, with the side of the smaller diameter on the housing shell 10 and with the larger diameter side of the inflow pipe 23 the pipe flow. With this cone-shaped constriction, the water from the inflow pipe 23 to the tubular housing jacket 10 narrowed and accelerated. This results in the housing shell 10 a higher flow rate and better turbine performance.

To the output side of the housing jacket 10 is a cone-shaped diffuser tube 24 attached, with the side of the smaller diameter on the housing shell 10 and with the larger diameter side of the drainpipe 25 the pipe flow. With this conical extension a diffuser effect is achieved to the drainage side, whereby an improved water drainage is achieved.

2 shows an arcuate cap 27 on the half-arched cutout 12 in the back half of the housing shell 10 is screwed, with laterally mounted screw sleeves and joint sealing strip on the outsides coming to rest.

3 shows the protective grid 16 for flow deposits, with guide rails 17 in the housing shell 10 is used and can be removed for cleaning.

4 shows the disk-shaped parking flap 19 , with a vertical axis 20 in the middle and a stop lever 26 to the top.

5 shows an arcuate cap 28 on the half-arched cutout 12 in the front half of the housing shell 10 is screwed on, with a control window 29 made of plastic glass for the Schwemmgutablagerungen. The cap 28 Can be removed for cleaning and for the removal of accumulated Schwemmgut and screwed on again.

6 shows an arcuate cap 27 on the half-arched cutout 12 in the back half of the housing shell 10 is screwed on, with screw sleeves on the sides and joint sealing strips on the outsides coming to rest. On the inside of the arched cap 27 are the turbine 13 , the generator 14 and the electronic control and control device 15 fastened so that they can be lifted out and repaired for repair and maintenance work.

7 shows a Rohrströmkraftwerk 1 with the same diameter pipe diameter of the housing shell 10 , as well as the inflow pipe 23 and the drainpipe 25 , Instead of the conical flow acceleration tube 22 on the inlet side and the conical diffuser tube 24 at the end sides of the housing shell 1 , as in 1 be shown in 7 the two end sides of the housing shell 10 with overlapping pipe connection rings 32 with the inflow pipe 23 and the drainpipe 25 connected.

Claims (3)

Pipe flow power plant ( 1 ) for the use of flow energy in pipelines, characterized by a tubular housing jacket ( 10 ) made of metal, with two semicircular cutouts ( 12 ) in an arc shape, to the top of the tubular housing shell ( 10 ), in which on the horizontal outer sides screw sleeves ( 18 ) are attached, with a cutout 12 ) in the rear half of the housing shell ( 10 ) is arranged as a mounting opening, through which a turbine ( 13 ), with generator ( 14 ) and an electronic control system ( 15 ) and in the housing shell ( 10 ) and where on this cutout ( 12 ) an arcuate cap ( 27 ), with screw sleeves ( 18 ) on the outer sides and edge sealing strips ( 31 ) is screwed to the bearing surface, which can be removed and repaired for repair and maintenance work. and wherein the second section ( 12 ) to the top in the front half of the housing shell ( 10 ), as an opening for installation and removal of a protective grid ( 16 ) for alluvial debris and for the removal of deposited debris, with the inside of the housing shell ( 10 ) Insertion rails ( 17 ) for the protective grid ( 16 ) and hereby the protective grid ( 16 ) can be removed for cleaning work, including the accumulated alluvium, and wherein on this second section ( 12 ), in the front half of the housing shell ( 10 ), an arcuate cap ( 28 ), with screw sleeves ( 18 ) on the outer sides and edge sealing strips ( 31 ) to the bearing surface, is screwed, and wherein in this cap ( 28 ) a window ( 29 ) made of plastic glass to control the Schwemmgutablagerungen in front of the protective grid ( 16 ), and wherein a disk-shaped pipe flap ( 19 ), with a vertical axis ( 20 ) to the center, in the housing shell ( 10 ) is introduced, wherein to the inside of the housing shell ( 10 ) at mid-height a stop device ( 21 ) for the pipe work flap ( 19 ) and at the bottom of the housing shell ( 10 ) a plug-in device ( 30 ) for the axis ( 20 ) the disk-shaped pipe work flap ( 19 ) and to the top of the housing shell ( 10 ) a hole-shaped opening to the outside, through which the shut-off of the inflow a lever-shaped storage device ( 26 ) is introduced, wherein the cap ( 28 ) can be removed and screwed on again for cleaning work and for the removal of accumulated alluvium, and wherein a conical flow acceleration tube ( 23 ) to the input side of the housing shell ( 10 ) attached to the side of the smaller diameter on the housing shell ( 10 ) and with the side of the larger diameter at the inflow pipe ( 23 ) of the pipe flow, wherein with the conical pipe constriction, the flow in the housing shell ( 10 ) is accelerated, and wherein a conical diffuser tube ( 24 ) to the output side of the housing shell ( 10 ) attached to the side of the smaller diameter on the housing shell ( 10 ) and with the larger diameter side of the drain ( 25 ) of the pipe flow, wherein the conical pipe extension a diffuser effect is achieved to the output side. Pipe flow power plant ( 1 ) for the use of flow energy in pipelines, according to claim 1, characterized in that the turbine ( 13 ), with generator ( 14 ) and the electronic control system ( 15 ) to the inside of the cap ( 27 ), and then for repair and maintenance work with the cap ( 27 ) can be lifted out and reinstalled. Pipe flow power plant ( 1 ) for the use of the flow energy in pipes, according to claim 1 and 2, characterized in that at the same size pipe diameter of the housing shell ( 10 ), as well as the inflow pipe ( 23 ) and the drainpipe ( 25 ), the conical flow acceleration tube ( 22 ) on the input side and the conical diffuser tube ( 24 ) on the output side of the housing shell ( 10 ) and for the two end sides of the housing shell ( 10 ) with overlapping pipe connection rings ( 32 ) with the inflow pipe ( 23 ) and the drainpipe ( 25 ) get connected.

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