DE8914379U1 - Device for generating electrical energy using part or all of the hydraulic energy available in the water supply networks - Google Patents

Description

1 · · It

The invention relates to an independent device for generating electrical energy using a part or all of the hydraulic energy available in the water supply networks during the filling and emptying processes of the containers.

Automation, centralized management of the water supply system, and constant monitoring of the quality of the water distributed (groundwater and river water contamination) lead to the use of electrical or electronic devices in such installations, such as water tanks on towers or tanks partially or completely buried in the ground, various sensors installed on the pipes, etc. These devices must necessarily be supplied with electricity, but in most of the places to be equipped there is generally no electricity supply.

The solutions currently used are unsatisfactory either because of their low autonomy, such as industrial dry batteries or other batteries that require frequent maintenance because they are either exposed to vandalism or the weather, such as solar batteries and wind sensors, or because of the disproportionate investment in relation to the power required, such as connection to the French electricity network (BDF), which requires the construction of an electrical line of several hundred metres, if not several kilometres, consuming several tens of watts, and which also increases the sensitivity of the installation to the weather.

The device according to the invention makes it possible to eliminate these disadvantages. It comprises a rotating machine, which can supply electrical energy and a shaft with a drive driven by the water flow.

The device is held in the axial direction of the water flow by a mechanical structure that allows the device to be easily attached to the pipes commonly used in water supply networks. The various components are designed according to the existing systems and the power of the generating machine. Since the water circuit is generally intermittent, the device according to the invention is advantageously supplemented by a battery equipped with conventional circuits for regulating and limiting the flow. The devices according to the invention make it possible to have continuous electrical energy where it is needed, for an unlimited period of time, since the containers are regularly emptied and filled. The devices located inside the containers are protected against vandalism and atmospheric agents, as well as against overvoltages caused by atmospheric disturbances, and the level of investment remains proportionate to the purpose achieved.

An improvement in operation is achieved by using a casing made of one or more parts that completely surrounds the machine. Each end has an opening whose cross-section forms a "flow pipe" independent of the dimensions of the water supply line and determines the operating conditions of the machine. The passage cross-section of the casing or casings, which determines the drive energy, can be changed by optionally using reduction pipes of different diameters.

In order to adjust the speed of the machine depending on the hydraulic conditions of the supply line in which the machine is located, the end of the casing surrounding the impeller can be fitted with fixed pivoting vanes. By acting on the

the angle of the water flow can be changed in relation to the plane of the wheel blades. Since the angle of an impeller depends on this angle, the ability to pivot these blades allows the specific speed of an impeller to be set within a certain flow and conveying speed of the water in the supply line. Devices for setting these fixed blades manually or automatically using the water speed or by locking them with the output voltage of the AC machine, for example by an external drive element, remain within the scope of the invention.

According to one embodiment of the invention, the rotary machine generating the current is a single or multi-phase alternating current generator, having neither collector, slip rings nor brushes. The armature is fixed so that the two ends of each coil exit directly through a multi-conductor cable connected to the known alternating current rectifying circuits. These windings can be connected in series or in parallel to allow for variable voltage, current and voltage outputs of 12 V, 24 V or 36 V batteries. The field magnet, which forms a unit with the impeller and has permanent magnets, can rotate indiscriminately in one direction or the other. This feature is particularly interesting for certain installations in which the water circulation can be reversed if necessary.

The construction of the alternator, the choice of stainless steel or plastic materials/ the sealing of the windings allow it to be submerged without the need for rotating seals that can cause friction, wear and leakage. The alternator fills and works with water. The only sealing to be ensured is the passage of the fixed cable through the supply line, which is generally done by a plug.

bushing. Holes in the body and covers ensure cooling of the armature and lubrication of the bearings. The machine constructed in this way is particularly reliable and can therefore be used very well in isolated systems where it works without supervision.

Further features of the invention will become apparent from the following description of an embodiment shown in the attached schematic drawings:

Figure 1 is a half-section of a first possible embodiment of the invention, in which the rotatable field magnet sits on the fixed central armature and carries the impeller.

Figure 2 is a front view of this first embodiment and the schematic design, among other possible ones, of the fastening of the machine within the supply line, as well as of the impeller, which does not have to take up the entire cross-section of this supply line.

Figure 3 shows a possible installation of this embodiment with the associated two clusters at any location on a supply line, whereby two adapter cones are used to maintain the initial cross-section.

Figure 4 is a half-section of a second possible embodiment of the invention with a fixed armature, inside which the field magnet rotates, forming a unit with the impeller arranged at the end of the machine.

Figure 5 is a plan view of this second embodiment of the invention and shows the support arms of the machine inside a supply line.

Figure 6 shows an installation option for this design, in conjunction with housings, fixed blades and a reducing ring at any point on a supply line,

Figure 7 shows a top view of the previous figure and shows the holding arms of the machine in its housing by means of an attachment, as well as the holding arms of this attachment inside a supply line.

Figure B shows the impeller housing and its blades, which can be pivoted by rotating this housing on the attachment.

Figure 9 is a rear view of the impeller housing showing the pivoting blades.

Figure 10 shows a possible device, among others, for the possibility of manual operation of the fixed wings.

Figure 11 shows a possible device, among others, for automatically controlling the position of the fixed wings using the force of the water flow within the supply line.

Figure 12 shows a possible device, among others, for controlling the position of the fixed wings by an external control motor.

Figures 13, 14 and 15 show possible embodiments, among others, for fastening the machine to the inlet of a bin filling supply line in the upper part of a container, to the outlet of an emptying line in the lower part of a container and to any desired point on a supply line.

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With reference to these drawings, the device comprises a body (1) having two bearings (2a)(2b), for example ball bearings, in which a bolt (3) is arranged. The fixed armature, consisting of a laminated magnetic circuit (4) and windings (5), is fixed to the body (1), and the unit is sealed by encapsulating it with an insulating material (6). The field magnet (7) provided with permanent magnets (B) forms a unit with the bolt (3). According to Figure 1, the impeller (9) is fixed directly to the field winding (7), while according to Figure 4, the impeller is fixed to the end of the bolt (3). Two conical covers (10a)(10b) are fixed to the two ends of the machine.

Figures 1 and 2 for the first embodiment and Figures 4 and 5 for the second embodiment show the fastening of the machine by the arms (11) to an existing supply line (12), the diameter of which is enlarged by an adapting cone (13). The fastening is ensured by the screws (14) which pass through holes in the pipe (15) connected to the cone (13) and screw into the ends of the arms (11). The holes (38) shown in Figures 1 and 4 ensure the circulation of water inside the machine in order to cool the armature and lubricate the bearings.

Figures 3 and 6 represent the machine which, through the arms (17), forms a unit with a head (16). This head, which carries the casings (19)(20), is held by the webs (23) inside the tube (22) which is adapted to the feed pipe (12) by the two inverted cones (12s) and (13b). The structure is held by the screws (14) which are screwed into the arms (17) through holes in the tube (22).

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Figures 6 and 7 show the fixed wings (21) with their end pins located in the notches (18) of the cap, and the reducing rings (37a) (37b) at each end of the housings.

Figure 8 shows a means for presetting the angle of the fixed wings. These wings are connected to each other and to the casing (20) on the opening side, but are free over the entire conical part of this section. The free ends are provided with a pin (25a) (25b) (25c) (25d) which, during assembly, engages in the notches (18a) (18b) (18c) (18d) of the cap (16). When the casing (20) is rotated within the limits of the slotted hole(s) (26) provided therein and guided by the screws (27) screwed into the cap (16), but which are loosened during this adjustment, a twisting effect is caused on the fixed wings (21), which are held at their other ends in the notches (18), in which they can slide. This rotation causes these wings to be tilted in one direction or the other, as can be seen for the wing (21a). The adjustment is indicated by means of the identification (28) on the housing (20) and the scale (29) on the attachment (16).

Figures 9 and 10 show one of the other possible configurations for manually controlling the fixed wings according to the principle described above. Actuating pins (30) allow a ring (31) to be pivoted around the casing (20). The fixed wings (21), which form a unit with the ring (31), are set in rotation with the same effect as if the casing were rotated. In the example described in figure 6, the locking is achieved by screwing in the pins (30) with the effect of clamping the casing (16) between the lips of the ring (31).

Figure 11 shows one means among others for automatically controlling the fixed wings by the water flow. The shaft (31) mounted on the housing (20) through holes in the inside of the housing (20) can pivot freely within the grooves of the rings (32). The vanes (21) always form a unit with the ring (31), which also has further vanes (34) on the outside, which are located in the main flow of the supply line. These vanes, which are inclined in relation to the flow direction, produce a torque that drives the inner vanes (21) via the ring (31). The inclination of the vanes (34) is selected so that an increase in the flow speed in the supply line causes a change in the angle of the flow within the machine, which keeps the speed of the impeller constant. The vanes (21), which are made of a material with a certain elasticity, thus perform the functions of return springs.

Figure 12 shows a structure that allows the speed of the machine to be controlled by an external drive element. The ring (31) attached to the end of the housing (20) by means of balls (33) has a segment of a bevel pinion (35) into which the drive pinion (36) engages. By changing the position of the wings (21), the rotation of this pinion changes the operation of the machine.

Figures 13/ 14 and 15 show different possibilities for installing the machine at the end or in the middle of a water supply line using part or all of the elements described above. The invention is not limited to the embodiments shown, and numerous modifications are possible without departing from the scope of the invention. In particular, the shape or type of the various elements that make up the machine, as well as those that serve to construct it, can be varied for reasons of

the reasons of simplified manufacture or simpler installation. Likewise, numerous modifications to the design of the power generating machine are possible, including the use of conventional electrical machines. A machine can also be constructed which is similar to the embodiments described here, but elements are arranged differently. All these modifications remain within the scope of the most important means of the invention.

The device according to the invention is particularly suitable for the production of electrical energy in isolated installations in the water supply network. This solution is practical, economical and particularly reliable for ensuring the power supply of electrical or electronic equipment, which is essential for the automation, remote management and quality control that are becoming increasingly common in these installations.

Claims (9)

M 1827/V/ro PROTECTION CLAIMS 1. Device for generating electrical energy using part or all of the hydraulic energy available in the water supply networks during filling and emptying operations,
marked by, a power generator arranged inside a supply line in the axial direction of a water flow with an impeller (9) and with arms (11) and/or webs (23) serving to hold the power generator inside the supply line. 2. Device according to claim 1, characterized in that the power generating machine is arranged in a housing (19, 20) or between cover parts (10a, 10b). 3. Device according to claim 2, characterized in that the housing (20) has fixed but pivotable blades (21) serving to vary the speed of the power generating machine. 4. Device according to claim 3, characterized in that the housing (20) has a ring (31) serving to control the position of the pivotable wings (21) by hand. 5. Device according to claim 4, characterized in that the ring '31) is rotatably mounted on balls and the device device which serves to automatically maintain the rotational speed constant when the flow rate changes. 6. Device according to claim 4 or 5, characterized in that it comprises a pair of pinions (35, 36) serving to rotate the ring (31) and to regulate the position of the fixed wings (21) from the outside. 7. Device according to claim 2, characterized in that the housing (20) has rings (37) serving to adjust the energy taken from the water network to the necessary electrical energy and to reduce the inflow loss to a minimum by reducing the diameter. 8. Device according to claim 2, characterized in that the housing or cover parts (10a, 10b) and the body (1) of the power generating machine have holes (38) serving to cool the armature and to lubricate the bearings. 9. Device according to claim 1, characterized in that the ends of each winding (5) forming the armature of the power generating machine extend separately out of the device.