ES2583828B2 - Device to generate electricity with magnetic media, improved - Google Patents

Abstract

Improvement introduced in the invention patent No. P201630090 relating to a "Device for generating electricity" according to which the device comprises magnetic means (101, 102, 103, 104) for the transmission of movement between at least one pair of hydraulic pistons inlet (44a, 44b) and a pair of hydraulic output pistons (43a, 43b), said pair of hydraulic inlet pistons (44a, 44b) being hydraulically connected to the first hydraulic piston (41), and said pair of hydraulic pistons output (43a, 43b) hydraulically connected to the second hydraulic piston (42). In this way, a device for generating electricity is available, with an increased ratio of the output power to that of the input.

Description

DESCRIPTION

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OBJECT OF THE INVENTION

The purpose of the present patent application is an improvement introduced in the invention patent No. P201630090 in which a device for generating electricity is presented through a mechanism comprising an actuator that exerts a linear force 10 on at least one piston hydraulic, with an attached generator through which energy is produced. The improvement consists in the inclusion of intermediate magnetic means for the transmission of the movement. It also has the advantage that at the output the power obtained is greater than that consumed.

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BACKGROUND OF THE INVENTION

It is known from the state of the art, as reflected in document US2014049051, a power generating device that generates self-sufficient electricity without the need for 20 external resources. The device comprises two vertical members, each comprising a weight. The weights of the vertical elements are secured to a chain that is passed through a cogwheel. The sprockets are then rigidly attached to an axle, such that the chain passes over the sprockets by rotating the axles. The axes are fixed to a gearbox, which is then fixed to a magnetic component 25 induction generation. The weights move in the opposite way, so that when one weight is lifted the other is lowered, with the weight lowers the activation of a switch, which turns on a hydraulic pump and the piston, which acts to increase the weight . The lifting and lowering of the weights rotates the shafts, which in turn turns the turbines of the magnetic components of induction generation to produce electricity.

It is also known from the state of the art, as reflected in document KR20090083514, a system for producing electricity by using a hydraulic cylinder equipped with a cylinder shaft, a joint shaft, and a fixed clutch gear. The hydraulic cylinder comprises cylinder shafts, joint shafts and clutch gear assemblies. The cylinder shaft pushes the articulation shaft like a two-stroke piston. The articulation shaft is converted from linear movement to rotation movement, and rotates the clutch gear assembly. The connecting shaft is connected to the cylinder shaft and the clutch gear is configured to increase torque. More than 90% of electrical energy is obtained than the electricity consumption that is realized. It comprises three safety batteries.

It is also known from the state of the art, as reflected in WO2004088770, an electricity generation system configured to generate electrical energy from potential energy. It comprises a support frame, an actuator, a counterweight, a hydraulic assembly, a multiple pulley system and an electric lifting motor. The set includes a hydraulic accumulator, a hydraulic turbine and a generator. The counterweight is fixed to the piston rod. The electric lifting motor is configured to alternately raise and lower the counterweight with the help of the multi-pulley system 15, arranged between the counterweight and the support frame, in order to correspond to the piston rod inside the inner chamber of such that the hydraulic fluid can circulate through the hydraulic group. The accumulator receives and pressurizes the hydraulic fluid from the actuator and releases it to the hydraulic turbine so that the hydraulic turbine can be rotated. The generator is rotatably driven by the hydraulic turbine 20 and converts its rotational movement into electrical energy.

Thus, it is seen that there is still a need for a device to generate electricity, with an increased ratio of the output power to that of the input.

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DESCRIPTION OF THE INVENTION

The present invention relates to a device for generating electricity through a mechanism comprising an actuator that exerts a linear force on at least one hydraulic piston, intermediate magnetic means for the transmission of movement, and an attached generator through the which ends up producing an energy.

Thus and generically, starting from an electric input actuator, a force is transmitted to the first hydraulic piston where a pressure is produced in bars (bar), a pressure that we transfer to a first hydraulic input piston with which we develop an F1 force which is what produces the movement of the system. Said electric input actuator, if deemed more convenient, can be replaced by a hydraulic pump, in order to feed the first hydraulic piston.

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More particularly, the improvement introduced in the invention patent No. P201630090 is related to a "Device for generating electricity" according to which at least a first axis between a first support and a second support, at least one input actuator acting on at least a first hydraulic piston, said at least a first hydraulic piston acts on at least a second hydraulic piston, which drives a mechanical propeller element 10, wherein said propellant mechanical element comprises a first serrated surface on a first skate, which slides on a first guide, where the first gear surface gears, as a rack, with a first input gearwheel on the first axle, where the first axle comprises at least a second output transmission wheel, an electric generator comprising a second axle with a third input transmission wheel, wherein said second output transmission wheel and t The input drive wheel is mechanically linked by means of a transmission belt, wherein said first input gearwheel comprises a first freewheel mechanism such that it transforms the reciprocating movement of the first axis into rotational movement, such that the The first axis moves in a single direction of rotation, and where specifically the improvement with respect to the invention patent No. P201630090 consists in that the device for generating electricity comprises magnetic means for the transmission of the movement between at least one pair of pistons hydraulic input and a pair of hydraulic output pistons, said pair of hydraulic input pistons being hydraulically connected to the first hydraulic piston, and said pair of hydraulic output pistons hydraulically connected to the second hydraulic piston. In this way an increase in the force of exit in the hydraulic pistons of exit with respect to the force is applied that is applied in the hydraulic pistons of entrance. This ratio of force of exit (Fs) with respect to the force of entrance (Fe) reaches a value of 60 to 1. 30

In more detail, the magnetic means for the transmission of movement between each hydraulic input piston and each hydraulic output piston comprise at least a first pair of magnetic input means and at least a first pair of magnetic output means. In this way there are two complementary magnetic transmission branches of movement, which allow a round-trip cyclic movement.

According to the principle of operation of the mechanism, each hydraulic input piston comprises an input shaft mechanically linked to at least one pair of arms, the 5 of which are mechanically linked in turn with each of the magnetic input means respectively, of such so that there is a mechanical means of transmission of the movement, capable of being varied in terms of its dimensions and configurations in order to obtain greater or lesser performance of the device.

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In a preferred embodiment of the invention, each of the arms comprises at least one fulcrum respectively, through which a movement transmission relationship is established. Thus, said movement transmission ratio can be customized for each of the arms.

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More specifically, the principle of operation of the mechanism is such that each of the arms is capable of rotating around its respective support point under the thrust of the input shaft, causing the vertical displacement of the magnetic input means so that when the input shaft rises, the magnetic input means descend, said magnetic input means approaching the magnetic output means 20. It is in this way, by varying the distances between the magnetic means that the action-reaction mechanism is produced, that ends up transmitting the movement from the hydraulic input pistons to the hydraulic output pistons.

Advantageously, at least one first magnetic input means interacts with at least one first magnetic output means so that an attractive force is produced between them, which causes an approach movement between them.

On the other hand, at least a second magnetic input means interacts with at least a second magnetic output means so that there is a force of repulsion between them, which causes a movement of distance between them.

According to another aspect of the invention, the magnetic output means are mechanically linked to an output shaft of the at least one hydraulic output piston, so that the movement of the magnetic means is transmitted to the hydraulic output piston. 35

More particularly, the first magnetic outlet means is a ferromagnetic material without magnetization. Thus the device is functional even without all the magnetic means being magnets, magnetic field emitters.

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On the other hand, in a preferred embodiment of the invention, the magnetic input means and the magnetic output means are made of magnetized ferromagnetic material, such that all magnetic means are capable of attracting and / or repelling, or of being attracted and / or repelled.

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According to the principle of operation of the mechanism, a repulsive force is produced in the device between the second magnetic input means and the second magnetic output means as a result of their relative orientation, so that it is possible to use said relative orientation as a variable of Design to get better performance. fifteen

On the other hand, by varying the position of the arm's support point, the distance that the magnetic input means travel vertically varies with respect to the distance the input shaft travels vertically. In this way, the degree of approximation between the magnetic input means and the magnetic output means can be regulated, said design variable being arranged to regulate the performance of the device.

In a preferred embodiment of the invention, the pair of hydraulic input pistons are hydraulically connected to the first hydraulic driving piston so that when said first hydraulic driving piston expands, one hydraulic input piston compresses and the other expands respectively. This produces an alternative cyclic movement between both hydraulic inlet pistons.

Additionally, the pair of hydraulic output pistons are hydraulically connected to a second receiving hydraulic piston so that when said second receiving hydraulic piston 30 expands, it does so as a result of the fact that one outgoing hydraulic piston compresses and the other expands respectively. This results in an alternative cyclic movement between both hydraulic output pistons.

Inciding on the principle of operation of the mechanism, an input shaft of the at least one hydraulic input piston vertically displaces the magnetic input means, which exerts a magnetic force on the magnetic output means, which horizontally displaces an output shaft of at least one hydraulic output piston. In this way, and by means of said transformation of the movement from a vertical axis to a horizontal axis 5, a more efficient positioning of the component elements of the additional system for the device for generating electricity is achieved.

Advantageously, the movements of the first hydraulic input piston and the first hydraulic output piston are alternately synchronized with the movements of the second hydraulic input piston and the second hydraulic output piston. In this way an alternative cyclic movement is obtained for the additional system of the device for generating electricity.

The attached drawings show, by way of non-limiting example, a device for generating electricity with magnetic means, constituted according to the invention. Other features and advantages of said device for generating electricity with magnetic means, object of the present invention, will be apparent from the description of a preferred but not exclusive embodiment, which is illustrated by way of non-limiting example in the drawings that are accompany, in which: 20

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1.- It is a schematic and simplified view of the device for generating electricity 25 with magnetic means, in accordance with the present invention.

DESCRIPTION OF A PREFERRED EMBODIMENT

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In view of the aforementioned figures and, according to the numbering adopted, an example of a preferred embodiment of the invention can be observed therein, which comprises the parts and elements indicated and described in detail below.

More specifically, the additional system for a device for generating electricity with magnetic means works as follows: When the force F1, as can be seen in Figure 1, is pulling up the magnet named 101 with the plate 104 making traction. On the other hand, magnets 102 and 103 are subjected to a repulsive force, so that the support that supports magnets 103 and 104 is pushed 5 to the left with a force 5 times greater than the force of piston 44a, 44b That force on the piston 43a, 43b, produces a pressure in bars (bar) that we transfer to the second hydraulic piston 42 producing an output force (Fs) that is what produces the movement of the system, being the result of approximately an increase from 1 to 60 with respect to the input force (Fe). 10

Thus, as can be seen in Figure 1, the improvement introduced in the invention patent No. P201630090 relating to a "Device for generating electricity" according to which at least a first axis 11 between a first support 21 and a second support 22 , at least one inlet actuator 31 acting on at least a first hydraulic piston 41, said at least 15 a first hydraulic piston 41 acts on at least a second hydraulic piston 42, which drives a mechanical propeller element 6, wherein said driving mechanical element 6 comprises a first toothed surface 611 on a first skate 621, which slides on a first guide 631, where the first toothed surface 611 engages, as a rack, with a first toothed wheel 71 on 20 first axis 11, wherein the first axis 11 comprises at least a second output transmission wheel 72, an electric generator 33 comprising a second axis 12 with a third wheel d and input transmission 73, wherein said second output transmission wheel 72 and third input transmission wheel 73 are mechanically linked by means of a transmission belt 78, wherein said first input gearwheel 71 comprises a first mechanism of freewheel 81 so that it transforms the reciprocating movement of the first axis 11 into rotary movement, such that the first axis 11 moves in a single direction of rotation, and where specifically the improvement with respect to the invention patent No. P201630090 consists wherein the device for generating electricity comprises magnetic means 101, 102, 103, 104 for the transmission of the movement between at least one pair of hydraulic input pistons 44a, 44b and a pair of hydraulic output pistons 43a, 43b, being said pair of hydraulic input pistons 44a, 44b hydraulically connected to the first hydraulic piston 41, and said pair of hydraulic output pistons 43a, 43b hydraulically connected to the second hydraulic piston 42. 35

Additionally, the magnetic means 101, 102, 103, 104 for the transmission of movement between each hydraulic input piston 44a, 44b and each hydraulic output piston 43a, 43b comprise at least a first pair of magnetic input means 101, 102 and at least a first pair of magnetic output means 103, 104. 5

More specifically, as can be seen in Figure 1, each hydraulic input piston 44a, 44b comprises an input shaft mechanically linked to at least one pair of arms 111, 112, which are mechanically linked in turn with each of the magnetic input means 101, 102 respectively. 10

According to another aspect of the invention, as can be seen in Figure 1, each of the arms 111, 112 comprises at least one fulcrum 121, 122 respectively.

According to a preferred embodiment of the invention, as can be seen in Figure 15 1, each of the arms 111, 112 is capable of rotating around its respective support point 121, 122 under the thrust of the input shaft, causing the vertical displacement of the magnetic input means 101, 102 so that when the input shaft rises, the magnetic input means 101, 102 descend, said magnetic input means 101, 102 approaching the magnetic output means 103 , 104. 20 More specifically, each arm 111, 112, comprises a fulcrum 121, 122.

Specifically, the distance 1 (D1) is the one that goes from the support point 121, 122 to the joint of the arm 111, 112 with the magnetic input means 101, 102. The distance 2 (D2) is the one that goes from the support point 121, 122 to the connection of arm 111, 112 with the end of the axis of the hydraulic input piston 44a, 44b. In a preferred embodiment the distance 2 (D2) is 5 times greater than the distance 1 (D1).

It should be mentioned that, as can be seen in Figure 1, at least one first magnetic input means 101 interacts with at least one first magnetic output means 30 104 so that an attractive force is produced between them.

On the other hand, as can be seen in Figure 1, at least a second magnetic input means 102 interacts with at least a second magnetic output means 103 so that a repulsive force is produced between them. 35

More particularly, as can be seen in Figure 1, the magnetic output means 103, 104 are mechanically linked to an output shaft of the at least one hydraulic output piston 43a, 43b.

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According to an alternative embodiment of the invention, as can be seen in Figure 1, the first magnetic outlet means 104 is a ferromagnetic material without magnetization.

According to a preferred embodiment of the invention, as can be seen in Figure 1, the magnetic input means 101, 102 and the magnetic output means 103, 104 10 are made of magnetized ferromagnetic material.

According to another preferred embodiment of the invention, as can be seen in Figure 1, a repulsive force is produced between the second magnetic input means 102 and the second magnetic output means 103 as a result of their relative orientation. fifteen

More specifically, as can be seen in Figure 1, varying the position of the support point 121, 122, the distance between the magnetic input means 101, 102 varies vertically with respect to the distance the axis travels vertically. input In particular, the maximum approximation between the magnetic input means 20 101, 102 and the magnetic output means 103, 104 is 1mm.

According to the principle of operation of the mechanism, as can be seen in Figure 1, the pair of hydraulic inlet pistons 44a, 44b are hydraulically connected to the first hydraulic impeller piston 41 so that when said first hydraulic impeller piston 41 expands, one hydraulic inlet piston 44a, 44b compresses and the other expands respectively.

Further detailing the principle of operation of the mechanism, the first hydraulic piston 41 has a first chamber and a second chamber, separated by the internal disk of the piston.

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A first hydraulic inlet piston 44a has its first chamber connected to the first chamber of the first hydraulic piston 41, and its second chamber connected to the second chamber of the first hydraulic piston 41, while, conversely, a second hydraulic inlet piston 44b has its first chamber connected to the second chamber of the first hydraulic piston 41, and its second chamber connected to the first chamber of the first hydraulic piston 41.

In addition, as can be seen in Figure 1, the pair of hydraulic output pistons 43a, 43b are hydraulically connected to a second hydraulic piston 5 receiver 42 so that when said second hydraulic piston 42 receiver expands, it does so as a result of that one hydraulic outlet piston 43a, 43b compresses and the other expands respectively.

A first hydraulic outlet piston 43a has its first chamber connected to the first chamber of the second hydraulic piston 42, and its second chamber connected to the second chamber of the second hydraulic piston 42, while, conversely, a second hydraulic outlet piston 43b it has its first chamber connected to the second chamber of the first hydraulic piston 41, and its second chamber connected to the first chamber of the first hydraulic piston 41. 15

According to a preferred embodiment of the invention, as can be seen in Figure 1, an input shaft of at least one hydraulic input piston 44a, 44b vertically displaces the magnetic input means 101, 102, which exert a magnetic force on the magnetic output means 103, 104, which horizontally move an output shaft of the at least one hydraulic output piston 43a, 43b.

According to another preferred embodiment of the invention, the movements of the first hydraulic input piston 44a and the first hydraulic output piston 43a are alternately synchronized with the movements of the second hydraulic input piston 44b and the 25 second hydraulic output piston 43b.

The details, shapes, dimensions and other accessory elements, as well as the components used in the implementation of the device to generate electricity with magnetic means may be conveniently replaced by others that are technically equivalent, and do not depart from the essentiality of the invention or the scope defined by the claims that are included after the following list.

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List references:

11 first axis

12 second axis

13 third axis 5

14 fourth axis

21 first support

22 second support

23 third support

31 input actuator 10

32 second input actuator

33 electric generator

41 first hydraulic piston

411 outer wall

412 water circuit 15

42 second hydraulic piston

44th hydraulic first piston inlet

44b second inlet hydraulic piston

43rd first hydraulic output piston

43b second hydraulic piston outlet 20

5 hydraulic transmission means

6 propeller mechanical element

611 first toothed surface

612 second toothed surface

621 first skate 25

622 second skate

631 first guide

632 second guide

7 gear train

71 first gear 30

72 second drive wheel

73 third drive wheel

74 fourth transmission wheel

75 fifth wheel drive

76 sixth cogwheel 35

77 seventh cogwheel

78 transmission belt

81 first freewheel mechanism

82 second freewheel mechanism

9 auxiliary device 5

101 first magnetic input means

102 second magnetic input medium

103 first magnetic output medium

104 second magnetic output medium

111 first arm 10

112 second arm

121 first foothold

122 second foothold

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Claims (1)

1- Improvement introduced in the invention patent No. P201630090 relating to a "Device for generating electricity" according to which: - at least a first axis (11) between a first support (21) and a second support (22), 5 - at least one input actuator (31) acting on at least a first hydraulic piston (41), said at least one first hydraulic piston (41) acting on at least a second hydraulic piston (42), which drives an element mechanical drive (6), wherein said mechanical drive element (6) comprises a first toothed surface (611) on a first skate (621), which slides on a first guide (631), wherein the first toothed surface ( 611) gears, as a rack, with a first toothed wheel (71) on the first axle (11), where the first axle (11) comprises at least a second output drive wheel (72), - an electric generator (33) comprising a second axle (12) with a third input transmission wheel (73), wherein said second output transmission wheel (72) and 15 input third transmission wheel (73) are mechanically linked by means of a transmission belt (78), wherein said first input sprocket (71) comprises a first freewheel mechanism (81) such that it transforms the reciprocating movement of the first axle (11) into rotary motion, such that the first axle (11) moves in a single direction of rotation, 20 characterized in that it comprises magnetic means (101, 102, 103, 104) for the transmission of the movement between at least one pair of hydraulic input pistons (44a, 44b) and one pair of hydraulic output pistons (43a, 43b), being said pair of hydraulic input pistons (44a, 44b) hydraulically connected to the first hydraulic piston (41), and said pair of hydraulic output pistons (43a, 43b) hydraulically connected to the second hydraulic piston (42). 2- Improvement for a device for generating electricity with magnetic means according to claim 1 characterized in that the magnetic means (101, 102, 103, 104) for the transmission of movement between each hydraulic input piston (44a, 44b) and each piston 30 Hydraulic outlet (43a, 43b) comprise at least a first pair of magnetic input means (101, 102) and at least a first pair of magnetic output means (103, 104). 3- Improvement for a device for generating electricity with magnetic means according to claim 2 characterized in that each hydraulic input piston (44a, 44b) 35 comprises an input shaft mechanically linked to at least one pair of arms (111, 112), the which are mechanically linked in turn with each of the magnetic input means (101, 102) respectively. 4- Improvement for a device for generating electricity with magnetic means according to claim 3 characterized in that each of the arms (111, 112) comprises at least one support point (121, 122) respectively. 5- Improvement for a device for generating electricity with magnetic means according to claim 4 characterized in that each of the arms (111, 112) is capable of rotating around its respective support point (121, 122) under the thrust of the input axis, causing vertical displacement of the magnetic input means (101, 102) so that when the input axis rises, the magnetic input means (101, 102) descend, said magnetic input means (101) approaching , 102) towards the magnetic output means (103, 104). fifteen 6- Improvement for a device for generating electricity with magnetic means according to claim 5 characterized in that at least a first magnetic input means (101) interacts with at least a first magnetic output means (104) so that a attraction force twenty 7- Improvement for a device for generating electricity with magnetic means according to claim 5 characterized in that at least a second magnetic input means (102) interacts with at least a second magnetic output means (103) so that a repulsive force 25 8- Improvement for a device for generating electricity with magnetic means according to claim 5 characterized in that the magnetic output means (103, 104) are mechanically linked to an output shaft of at least one hydraulic output piston (43a, 43b). 30 9. Improvement for a device for generating electricity with magnetic means according to claim 1 characterized in that the first magnetic output means (104) is a ferromagnetic material without magnetization.  35 10. Improvement for a device for generating electricity with magnetic means according to claim 1 characterized in that the magnetic input means (101, 102) and the magnetic output means (103, 104) are made of magnetized ferromagnetic material. 11- Improvement for a device for generating electricity with magnetic means according to claim 10 characterized in that a repulsive force is produced between the second magnetic input means (102) and the second magnetic output means (103) as a result of its orientation relative. 12- Improvement for a device for generating electricity with magnetic means according to claim 5, characterized in that by varying the position of the support point (121, 122), the distance that the magnetic input means travel vertically varies (101, 102) with respect to the distance that the input axis travels vertically. 13. Improvement for a device for generating electricity with magnetic means according to claim 1, characterized in that the pair of hydraulic input pistons (44a, 44b) are hydraulically connected to the first hydraulic piston (41) impeller so that when said first hydraulic piston (41) impeller expands, one hydraulic inlet piston (44a, 44b) compresses and the other expands respectively.  twenty 14- Improvement for a device for generating electricity with magnetic means according to claim 1 characterized in that the pair of hydraulic output pistons (43a, 43b) are hydraulically connected to a second receiving hydraulic piston (42) so that when said second hydraulic piston (42) receiver expands, it does so as a result of the fact that one hydraulic outlet piston (43a, 43b) compresses and the other expands respectively. 25 15- Improvement for a device for generating electricity with magnetic means according to claim 1 characterized in that an input shaft of the at least one hydraulic input piston (44a, 44b) vertically displaces the magnetic input means (101, 102), which exert a magnetic force on the magnetic output means (103, 104), which move horizontally an output shaft of the at least one hydraulic output piston (43a, 43b). 16- Improvement for a device for generating electricity with magnetic means according to claim 1 characterized in that the movements of the first hydraulic inlet piston (44a) and the first hydraulic outlet piston (43a) are alternately synchronized with the movements of the second hydraulic input piston (44b) and the second hydraulic output piston (43b).