TWM587853U - Linear kinetic energy generating device using cogging energy - Google Patents

Abstract

This creation refers to a linear kinetic energy generating device using cog energy. The device is composed of at least one electromagnetic module, at least one linear module, and at least one rotary output module. Each electromagnetic module can be powered by clicking. Generate instantaneous repulsive thrust relative to the linear module, and use the cogging of the linear module relative to the non-polar electromagnetic module to generate magnetic pull force recovery for the rotary output module to generate a rotary output through the linear module. The method of magnetic power supply generates magnetic repulsive thrust, obtains the maximum thrust with the minimum energy consumption, has the effect of low energy consumption and energy saving, and uses the powerful approach force generated by the cogging force of natural magnetic attraction to output kinetic energy. Creating green energy, coupled with low kinetic energy loss, can effectively improve energy conversion efficiency and achieve the purpose of energy creation and energy saving.

Description

Linear kinetic energy generating device using cog energy

This creation belongs to the technical field of generating kinetic energy using magnetic force, and specifically refers to a linear kinetic energy generating device using cogging energy, so as to use the repulsive thrust when electromagnetizing into an electromagnet to generate the maximum magnetic beam effect and minimize the power consumption It can get the maximum thrust, on the other hand, it can use its natural magnetic attraction to recover the cog energy to form a linear motion to achieve the purpose of energy creation and energy saving. There is no magnetoresistive kinetic loss without complex magnetic interference, thereby improving its energy conversion efficiency.

According to the press, the kinetic energy generating device has many different types according to its type of movement, use of energy or use mode, such as internal combustion engine equipment, Stirling engine, electromagnetic equipment, etc. Among them, the internal combustion engine equipment uses the explosive effect of burning and igniting gasoline to generate instantaneous thrust, and uses the vacuum suction of inlet and outlet to actuate the piston, thereby generating kinetic energy. Although it can generate large torque, it consumes energy and the environment. The problem of pollution and the large volume of the structure can not be applied to the environment with small space and volume; In addition, the Stirling engine uses, for example, fuel cells to generate high and low temperatures in the space below the piston. Through the temperature difference, the space below the piston changes the volume of the gas due to thermal expansion and contraction, which in turn causes the piston to linearly move. The effect of volume compression ratio, its reliability and durability are poor; As for the electromagnetic equipment [ie general motor], it is mainly composed of two opposite magnetic groups as the stator and the rotor. One of the magnetic groups is composed of a magnet and the other magnetic group is composed of a coil. The method makes it an electromagnet, and can generate repulsive and attracting magnetic forces against the magnetic parts of another magnetic group, thereby driving the rotor to rotate at high speed. The magnets and electromagnets of traditional motors move in a similar way to trains and trains, but because the magnetic lines of force between the magnets and the electromagnets are closed curves of 360-degree rotation, they are not straight, and the magnetic lines of force are penetrating. It cannot be blocked or avoided. Therefore, when the magnet enters the market, it will be blocked by unavoidable reverse magnetic lines of force, which will generate resistance. After exiting the field, it will be pulled back because of the same magnetic lines of force. This is a traditional motor structure that cannot be avoided and must bear. Physical obstacles. In addition, there is a more troublesome cogging problem. The crux of the problem is whether the core should be added with a coil [ie, a magnetized magnet]. Without the core, there will be a speed but no torque. The core is added. Although it can converge and permeate magnetically, it can greatly improve the electromagnetic efficiency, but the iron core will produce a natural magnetic attraction effect with the magnet, resulting in difficulty in starting the motor and reducing the efficiency. There is a dilemma between the two. Therefore, traditional motors usually reduce the cogging effect. The magnetic resistance of the cog effect is reduced by dislocation, such as 18P24N (18 coils vs. 24 magnets) to reduce the effect of the cog effect, but the magnetic resistance of the cog effect cannot be completely avoided, so it must be sacrificed Part of the energy conversion rate is unavoidable. At the same time, this method will make the structure of the entire electromagnetic equipment more complicated. Another method is to simply abandon the iron core to avoid the cogging effect, but the motor using the hollow coil design is certainly efficient. Higher, its disadvantage is that although it has higher speed and efficiency, it lacks torque. Although in practice, most motors have iron cores in their coils, and there are misalignment techniques to reduce injuries, but regardless No misalignment can make the cogging force zero! Therefore, the traditional motor technology is constrained by three congenital defects: approach magnetic resistance (repulsive force), exit magnetic resistance (retraction force), and cogging force.

In other words, in addition to the possible problems of environmental protection and pollution, kinetic energy generating devices, such as general electromagnetic equipment, use batteries to operate, and because they rely entirely on batteries, they consume large amounts of power. When they need to be powered continuously or intermittently for a long time, The battery's battery life will be tested, and the power shortage may occur in a short time. Moreover, when the battery is used for a long time, its half-life will come early and shorten its service life. Therefore, if the natural cogging effect can be effectively used when no power is applied to achieve the purpose of generating energy through its natural magnetic attraction, and the instantaneous firing effect can be generated by clicking when the power is applied, the energy consumption can be minimized. To obtain the maximum kinetic energy, to achieve the effect of reducing energy consumption and generating energy, how to achieve the aforementioned purpose and efficiency is what I expect in this creation.

The reason is that the creator has in-depth discussions on the advanced needs of the aforementioned kinetic energy generating device, and has actively engaged in research and solution through years of research and development experience in related industries. After continuous research and trial work, he finally successfully developed an application. The cog energy linear kinetic energy generating device can further improve the performance of the linear kinetic energy generating device under the conditions of creating green energy and reducing energy consumption and energy saving.

Therefore, the main purpose of this creation is to provide a linear kinetic energy generation device that uses cog energy, so that it can generate magnetically repulsive thrust through selective power supply, and obtain maximum thrust with minimum energy consumption, with low energy consumption and high efficiency. Energy saving effect.

Moreover, the second main purpose of this creation is to provide a linear kinetic energy generation device that uses cog energy, using the powerful approach force generated by the cog force of natural magnetic attraction to output kinetic energy, and to create green energy.

In addition, another main purpose of this creation is to provide a linear kinetic energy generating device using cog energy, which can reduce the consumption of electrical energy, not only increase the battery's endurance, but also extend the life of the battery, and at the same time have no space. Environmental protection effect with pollution and low noise.

Furthermore, another main purpose of this creation is to provide a linear kinetic energy generating device using cogging energy, whose magnetic flux does not have complicated magnetic field interference, which greatly reduces the kinetic energy loss caused by the reverse inverse force of the magnetic resistance, and effectively improves the energy. Conversion efficiency.

Based on this, this creation is mainly to achieve the aforementioned purpose and its effects through the following technical means, the device is composed of at least one electromagnetic module, at least one linear module and at least one rotary output module; The electromagnetic module has a non-polar conductive magnet, and a magnetizable coil is provided around the conductive magnet. The coil is connected with a power source capable of selectively supplying power, and an induction switch group is provided between the coil and the power source. The switch group includes a detection element provided between the coil and the power source, and the inductive switch group is provided with a detection element on the linear module for controlling the power on or off of the coil of the electromagnetic module; and the linear module described There is a fixed sliding sleeve. The sliding sleeve is provided with a sliding rod whose axis is coaxial with the magnetic poles at both ends of the magnet guide, so that the slider can linearly reciprocate with respect to the magnet, and one end of the slider corresponding to the magnet has a Magnetic piece, the magnetic piece corresponding to the magnetic pole of the magnetically permeable pole, which is generated after the magnetic field is excited by the coil The formed magnetic poles are opposite to each other, and the detection element of the inductive switch group is set at the position where the detection element is touched when the slider is located at the beginning of the stroke. As for the rotary output module, the flywheel has a flywheel periphery and linearity. A link is pivotally arranged between the ends of the module slide bar, and the flywheel of the rotary output module has an output member.

In summary, through the realization of the aforementioned technical means, this creation enables each electromagnetic module of this creation to generate a repulsive thrust by selectively supplying power to the linear module, and using the cog energy of the linear module relative to the non-polar electromagnetic module. Generates magnetic pull force recovery for reciprocating rotation output module through linear module to generate rotary output, short energy consumption time, and low kinetic energy loss without complex magnetic field interference, which can effectively improve energy conversion efficiency, and its energy saving effect, not only It can increase the battery life and extend the battery life. At the same time, it has the environmental protection effect of no air pollution and low noise, and can further realize its economic benefits.

In order to allow your reviewers to further understand the composition, characteristics, and other purposes of this creation, the following are some preferred embodiments of this creation, and are explained in detail with the illustrations below. At the same time, those who are familiar with the technical field can implement it. .

(1) ‧‧‧device

(10) ‧‧‧Electromagnetic Module

(11) ‧‧‧Magnetic guide

(12) ‧‧‧Coil

(15) ‧‧‧Power

(16) ‧‧‧Induction switch group

(161) ‧‧‧Inductive measuring element

(162) ‧‧‧Break inductance sensor

(18) ‧‧‧Inspection element

(20) ‧‧‧Linear Module

(21) ‧‧‧Slip sleeve

(22) ‧‧‧Slider

(25) ‧‧‧Magnetic

(30) ‧‧‧Rotary output module

(31) ‧‧‧Flywheel

(32) ‧‧‧Link

(35) ‧‧‧Output

(35A) ‧‧‧Shaft

(35B) ‧‧‧External gear

(40) ‧‧‧Driven shaft

The first figure is a schematic diagram of a side view of a preferred embodiment of a linear kinetic energy generating device using cog energy.

Fig. 2A is a schematic partial top-view architecture diagram of the application of the shaft output of the preferred embodiment of the linear kinetic energy generating device using cog energy of the present creation.

Figure 2B: The linear kinetic energy generating device using cog energy in this creation Schematic diagram of a partial side view of an external gear output using a preferred embodiment.

The third figure is a schematic diagram of the starting point of the thrust force of the linear motion in the preferred embodiment of the linear kinetic energy generating device using cog energy.

Fig. 4: Schematic diagram of the thrust inertial motion of the preferred embodiment of the linear kinetic energy generating device using cog energy in operation.

Fifth figure: This is a schematic diagram of the effect of the preferred embodiment of the linear kinetic energy generating device using cogging energy on the restoration of the linear motion during operation.

FIG. 6 is a schematic diagram of the effect of suction inertial motion of a preferred embodiment of a linear kinetic energy generating device using cog energy in operation.

Fig. 7: Schematic diagram of another embodiment of the linear kinetic energy generating device using cogging energy for the creation of the present invention.

FIG. 8 is a schematic diagram of a first action of another embodiment of the linear kinetic energy generating device using cog energy of the present creative.

The ninth figure is a schematic diagram of the second action of another embodiment of the linear kinetic energy generating device using cog energy of the present creative.

Fig. 10 is a schematic diagram of the third action of another embodiment of the linear kinetic energy generating device using cog energy.

Fig. 11 is a schematic diagram of a fourth action of another embodiment of the linear kinetic energy generating device using cog energy of the present creation.

Figure 12: This is a schematic diagram of another embodiment of the linear kinetic energy generating device using cog energy in this creation, for illustrating the parallel and parallel situation of two machines.

Figure 13: The linear kinetic energy generation device using cog energy in this creation A schematic diagram of the structure of another embodiment is provided to explain the parallel and serial appearance of a plurality of single machines.

This creation is a linear kinetic energy generating device that uses cog energy. The attached drawings illustrate the specific embodiment of this creation and its components, all about front and back, left and right, top and bottom, upper and lower, and horizontal. The vertical reference is only for the convenience of description, and does not limit the creation, nor limit its components to any position or spatial direction. The dimensions specified in the drawings and the description can be changed according to the design and requirements of this creation within the scope of the patent application of this creation.

The composition of the linear kinetic energy generating device using cog energy in this creation is shown in the first figure. The device (1) is composed of at least one electromagnetic module (10), at least one linear module (20), and at least A rotating output module (30), wherein each of the electromagnetic modules (10) can generate repulsive thrust relative to the linear module (20) through sensing power, and the linear module (20) is used for relatively non-polar electromagnetic modules. The cogs of the group (10) can generate a magnetic pull force recovery for the rotary output module (30) to generate a rotary output through the linear module (20); a preferred embodiment of the linear kinetic energy generating device using cog energy in this creative application For the detailed structure, please still refer to the first and second figures. The electromagnetic module (10) has a non-polar conductive magnet (11), and a conductive magnet (11) is provided with a magnetizable magnet after being energized. The coil (12) enables the magnetism (11) to generate magnetism, and the coil (12) is connected with a power supply (15) that can selectively supply electricity; and the linear module (20) has a fixed sliding sleeve (21) ), The sliding sleeve (21) is provided with a sliding rod (22) with an axis line coaxial with the magnetic poles at both ends of the magnetic module (10) of the electromagnetic module (10), and the sliding rod (22) can be generated relative to the foregoing magnetic guide (11). Reciprocating linear displacement, and one end of the sliding rod (22) corresponding to the magnetizer (11) has a magnetic piece (25), and the magnetic member (25) corresponds to the magnetic pole of the magnetizing piece (11) and the magnet (11) is subjected to the coil (12) ) The magnetic poles generated after electromagnetism are in the same pole opposite shape [as shown in the first figure, for example, when the linear module (20) magnetic piece (25) corresponds to the N-pole magnetizer (11), the magnetizer (11) The relative magnetic pole after being excited by the coil (12) is also N pole]; Furthermore, an induction switch group (16) is provided between the coil (12) and the power supply (15) of the electromagnetic module (10), and the induction switch group (16) Contains an inductive measuring element (161) provided between the coil (12) and the power source (15), and the stroke of the inductive switch group (16) and the slider (22) of the linear module (20) A detection element (18) is provided at the starting point. The detection element (18) of the slider (22) can detect the inductive measurement element (161), and can actuate the power supply (15) to supply power to the electromagnetic module (10). The coil (12) enables the electromagnetic module (10) to be excited to form an electromagnet, and Lever (22) a magnetic member (25) to generate a repulsive force. According to some embodiments, the inductive sensing element (161) may have a timer, which can set the disconnection time after the power source (15) path, for overcoming the slider (22) magnetic piece (25) and the electromagnetic module ( 10) Phase-to-phase cogging force. As also shown in the first figure, according to some embodiments, the inductive switch group (16) further includes a disconnected inductive sensing element (162) for the slider (22) to detect that the element (18) detects a power failure. When the sensing element (162) is used, an open circuit can be formed between the power supply (15) and the electromagnetic module (10), so that Large thrust, with low energy consumption and high energy efficiency. The inductive switch group (16) of this creation is based on the embodiment provided to the inductive sensing element (161) and the off-inductive sensing element (162). In addition, the inductive sensing element (161), the off-inductive sensing element (162), and the detection element (18) of the aforementioned inductive switch group (16) may be selected from mechanical micro-switches and contacts, photoelectric light source emission, and Receiving switch, proximity magnetic induction; as for the rotary output module (30) can be driven by a linear module (20), and the rotary output module (30) has a flywheel (31), and the flywheel ( 31) A link (32) is pivotally provided between the periphery and the end of the slide bar (22) of the linear module (20), and the connection relationship between the link (32) and the flywheel (31) and the slide bar (22), such as sliding When the lever (22) is located at the starting point of the stroke and the return point of the stroke, the connecting point of the connecting rod (32) and the flywheel (31) exceeds the horizontal 0 degrees and 180 degrees [as shown in the third and fifth figures], and the rotation The flywheel (31) of the output module (30) may have an output member (35), and the output member (35) may be a shaft (35A) provided on the axis of the flywheel (31) [as shown in the second figure ( A)], or external gear (35B) on the flywheel (31) [as shown in (B) of the second figure], pulleys, etc. [not shown], and the aforementioned electromagnetic module (10) The detection element (18) of the induction switch group (16) is provided on the slider (22) Corresponds to the position of the touch sensing inductive element (161) over a travel start point; whereby energy can create a group consisting of the application and saving of energy cog linear kinetic energy by means.

As for the preferred embodiment of the linear kinetic energy generating device using cogging energy in this creation, when it is actually actuated, it is shown in the third to sixth diagrams, where the third diagram is the triggering state of power supply, and the fourth diagram is the inertia of thrust Running status. The fifth picture is used to In the actual operation, as shown in the third figure, when the slide bar (22) of the linear module (20) is displaced, the check on it is performed. It is known that the component (18) touches the inductive measuring element (161) of the induction switch group (16) of the electromagnetic module (10), so that the power supply (15) directly supplies electricity to the coil (12) of the electromagnetic module (10), so that the electromagnetic mode The magnets (11) of the group (10) are excited to form a magnetic body, and have the same polarity as the opposite end of the magnetic member (25) of the linear module (20) [for example, N pole corresponds to N pole], so that the electromagnetic module (10) The magnet guide (11) generates a repulsive thrust against the linear module (20) slider (22) [such as point A of the starting point of the stroke], so that the slider (22) is pushed and passes through the link (32) Drive the flywheel (31), and then actuate the output member (35) to produce a rotary output; and as shown in the fourth and fifth figures, the slide bar (22) of the linear module (20) is subject to the repulsive thrust of the guide magnet (11) , Make the slide bar (22) move to the right and push the flywheel (31) to continue to rotate, and in operation, when the detection element (18) on the slide bar (22) is corresponding to the induction switch of the sensing electromagnetic module (10) When the inductive sensing element (162) of group (16) is broken [such as the fourth [Shown], to make the power supply (15) and the electromagnetic module (10) coil (12) into an open state [according to some embodiments, for example, when a timer is used, it will be open when the set time is reached], then the slider ( 22) Continuous displacement due to inertial thrust and inertial rotation force of the flywheel (31) of the rotation output module (30) [as shown in the fifth figure], when the slider (22) is at the end of the stroke [if the stroke is restored Point C], the magnetic member (25) of the slider (22) can generate a natural magnetic attraction force against the non-polar conductive magnet (11) of the electromagnetic module (10), so that the slider (22) is continuously pulled back The starting point of the stroke, and as shown in the sixth figure, during operation, the slider (22) is getting closer to the guide The magnetic force of the magnet (11) is increasing, and when the slider (22) returns to the starting point, the detection element (18) of the induction switch group (16) on the slider (22) can once again touch the electromagnetic module. The inductive measuring element (161) on (10) causes the power supply (15) to re-energize the coil (12) of the electromagnetic module (10) [as shown in the third figure], and then reciprocates through the slider (22) The flywheel (31) is rotated in a cyclic motion, and the output member (35) continuously generates a rotary output. Through the above description, the slider (22) of the linear module (20) is displaced at point A of the starting point of the stroke, and the electric shock is sensed. At this time, the magnetic part (25) of the slide bar (22) is closest to the magnet guide (11), which can generate the maximum repulsive force with the minimum energy consumption, so it can achieve high efficiency and energy saving, and the slide bar (22) moves linearly without Movements arranged in parallel to each other like the habit will have the magnetic resistance of the magnetic field lines turning, so this creation will not have high dynamic losses. Therefore, the electromagnetic benefit is far greater than the movements arranged in parallel, and its kinetic energy output is the largest, so its energy conversion rate high. In addition, natural magnetic attraction is used when returning to the stroke, which consumes no energy at all. It uses the cog energy of non-polar magnetic attraction to achieve the purpose of creating energy.

Furthermore, there is another embodiment of this creation, as shown in Figures 7 and 12, the device (1) consists of two sets of the aforementioned electromagnetic modules (10A, 10B) and two sets of the aforementioned linear modules ( 20A, 20B) and a set of the aforementioned rotary output module (30), wherein the rotary output module (30) is provided with a flywheel (31A, 31B) at each end of an output member (35), and each flywheel (31A, 31B) use a link (32A, 32B) to connect the sliders (22A, 22B) of the two sets of linear modules (20A, 20B) respectively, and the link (32A, 32B) and the flywheel (31A , 31B) and slider The connection relationship of (22A, 22B) can be the dislocation of the starting point of the stroke [as shown in the seventh figure] or the same position [as shown in the twelfth figure]. The main embodiment of this creation is the relative dislocation of the seventh figure For example, when the slider (22B) of one group of linear modules (20B) is located at the starting point of the stroke, the slider (22A) of the other group of linear modules (20A) is located at the stroke return point [as shown in the eighth figure] , And when the slider (22B) of one group of linear modules (20B) is at the stroke return point, the slider (22A) of the other group of linear modules (20A) is at the beginning of the stroke [as shown in the tenth figure] When the slider (22B) of the linear module (20B) on one side reaches the lowest point and the magnetic pull force is the lowest, the slider (22A) of the linear module (20A) on the other side can receive Electricity produces the greatest repulsive thrust, which is used to keep the rotating output of the output member (35) of the rotary output module (30) to be stable; and another preferred embodiment of the linear kinetic energy generating device using cog energy is practical During operation, it is as shown in the eighth to eleventh diagrams. When the detection element (18B) on the slide bar (22B) of one of the linear modules (20B) touches the electromagnetic module (10B), The inductive sensing element (161B) of the switch group (16B) should be used to enable the power supply (15B) to directly supply the electromagnetic module (10B) coil (12B), and the magnetic conductor (11B) of the electromagnetic module (10B) to be excited to form The magnetic body has the same polarity as the opposite end of the magnetic module (25B) of the linear module (20B) [for example, N pole corresponds to N pole], so that the electromagnetic module (10B) and the magnet guide (11B) are opposed to the linear module ( 20B) The slide bar (22B) generates repulsive thrust, causing the slide bar (22B) to be pushed, and the flywheel (31B) is driven through the link (32B), and then the output member (35) is actuated to generate a rotational output, and the other group The slider (22A) of the linear module (20A) is located at the return point at the end of the stroke. The magnetic part (25A) of the slide bar (22A) can generate the cogging force of natural magnetic attraction with respect to the non-polar magnetic guide (11A) of the electromagnetic module (10A), so that the slide bar (22A) is continuously pulled back to the starting point of the stroke; As shown in Figures 9 and 10, the slide bar (22B) of the linear module (20B) pushed by each other is displaced to the left and pushes the flywheel (31B) to continue to rotate. When the slide bar (22B) is in operation, When the detection element (18B) on the above corresponds to the inductive switching element (162B) of the inductive switch group (16B) of the sensing electromagnetic module (10B) [as shown in the ninth figure], the power supply (15B) and the electromagnetic The coil (12B) of the module (10B) forms an open circuit state, then the slider (22B) can continue to be displaced due to the inertia thrust and the inertial rotation force of the flywheel (31B) of the rotation output module (30). As shown, after the slider (22B) is at the end of the stroke, the magnetic part (25B) of the slider (22B) can generate a cogging force of natural magnetic attraction with respect to the non-polar magnetic guide (11B) of the electromagnetic module (10B). So that the slider (22B) is continuously pulled back to the start of the stroke. The slider (22A) of the linear module (20A) pulled by the magnetic force is displaced to the left and pushes the flywheel (31A) to continuously rotate. During operation, the slider (22A) can output the module due to suction and rotation ( 30) The inertia rotation force of the flywheel (31A) is continuously displaced, so that the slider (22A) is displaced toward the starting point of the stroke until the inductive sensing element (161A) corresponding to the detection element (18A) of the inductive switch group (16A) is triggered Repulsive thrust is generated; and as shown in the eleventh figure, during operation, the slider (22B) of the magnet module (10B) to the magnet module (11B) is getting closer to the magnet module (11B) due to the suction force. The magnetic pull force is getting larger and larger, and when the slider (22B) returns to the starting point, the inductive sensing element (161B) of the induction switch group (16B) on the slider (22B) can be touched again to detect The component (18B) [as shown in the eighth figure] causes the power supply (15B) to re-energize the coil (12B) of the electromagnetic module (10B), and then rotates the flywheel (31B) through the reciprocating motion of the slider (22B). In addition, the output member (35) continuously generates a rotary output. The reciprocating thrust of the slider (22A) shifts to the right and pushes the flywheel (31A) to continue to rotate, and during operation, when the detection element (18A) on the slider (22A) corresponds to the corresponding sensing electromagnetic module ( When the inductive switching element (162A) of the inductive switch group (16A) of the 10A) is disconnected [as shown in the eleventh figure], the power supply (15A) and the electromagnetic module (10A) coil (12A) are in an open state. The slide bar (22A) can be continuously displaced due to the inertia thrust and the inertial rotation force of the flywheel (31A) of the rotary output module (30), so that the slide bar (22A) is continuously pulled back to the starting point of the stroke.

In this way, in addition to maintaining the rotational output stability of the output member (35) of the rotary output module (30), it is subject to the cyclic thrust and suction of the slide bars (22A, 22B) of the linear modules (20A, 20B) on both sides And further increase its output kinetic energy.

Furthermore, another embodiment of this creation is shown in Fig. 13, which is driven in parallel and in series by two or more linear kinetic energy generating devices (1) applying cog energy. The shaft (40) structure is composed of three sets of devices (1C, 1D, 1E) according to some embodiments, and the slider (22C) of the linear module (20C) of one of the devices (1C) may be located at the stroke Starting point, and the slider (22D) of the linear module (20D) of the other device (1D) can be located at the stroke recovery point, so that the two output devices (1C, 1D) of the rotary output module (30C, 30D) link (32C, 32D) connection with flywheel (31C, 31D) and slider (22C, 22D) Relationships can be dislocated. It can also be the slider (22C) of the linear module (20C) of one device (1C) at the beginning of the stroke, and the slider (22E) of the linear module (20E) of the other device (1E) Located at the beginning of the stroke, the connection relationship between the links (32C, 32E) of the rotary output modules (30C, 30E) of the two devices (1C, 1E) and the flywheel (31C, 31E) and slider (22C, 22E) can be Is isotopic. And the rotary output module (30C, 30D, 30E) of the aforementioned device (1C, 1D, 1E) can synchronously drive the driven shaft (40), so that the driven shaft (40) can obtain stable rotary output, further improving Its output torque.

From this, it can be understood that this creation is an excellent creative creation. In addition to effectively solving the problems faced by the practitioners, it has greatly improved the effectiveness. And the same or similar product creation or public use has not been seen in the same technical field. At the same time, it has the enhancement of efficacy. Therefore, this creation has met the requirements of "newness" and "progressiveness" of new patents, and has applied for new patents in accordance with the law.

Claims (14)

A linear kinetic energy generating device using cog energy, the device includes at least one electromagnetic module, at least one linear module, and at least one rotary output module; wherein the electromagnetic module has a non-polar conductive magnet, and A magnetizable coil is energized around the magnetizing conductor, the coil is connected with a selectively electrified power source, and an inductive switch group is provided between the coil and the power source to control the power supply or power off of the electromagnetic module coil; and The linear module has a fixed sliding sleeve. A sliding rod with a moving axis coaxial with the magnetic poles at both ends of the magnet guide is slid inside the sliding sleeve, so that the slider can linearly reciprocate with respect to the magnet. A magnetic piece is provided at one end of the corresponding magnetic guide. The magnetic pole of the magnetic piece corresponding to the magnetic guide is magnetized by the coil. The magnetic poles are opposite to each other. As for the rotating output module, the flywheel has a flywheel and the periphery of the flywheel. A link is pivotally disposed between the end of the linear module slider and the flywheel of the rotary output module has an output member. The linear kinetic energy generating device using cogging energy as described in item 1 of the scope of patent application, wherein the inductive switch group includes an inductive measuring element provided between a coil and a power source, and the inductive switch group is connected to a linear module. A detecting element is provided, and the detecting element of the inductive switch group is set at a position sensed to the inductive measuring element when the slider is located at the beginning of the stroke. The linear kinetic energy generating device using cogging energy as described in item 2 of the scope of the patent application, wherein the inductive sensing element of the inductive switch group may have a timer for setting the power-on time. The linear kinetic energy generating device using cogging energy as described in item 2 of the scope of the patent application, wherein the inductive switch group includes a disconnection sensing element provided between the coil and the power source for setting a disconnection distance for power supply. According to the linear kinetic energy generating device using cog energy as described in item 1 of the scope of the patent application, wherein the connection relationship between the connecting rod of the rotary output module and the flywheel and the slider, the slider is at the stroke trigger point and the stroke return point The connecting points of the link and the flywheel exceed horizontal 0 and 180 degrees. As described in item 1 of the scope of the patent application, the linear kinetic energy generating device using cogging energy is applied, wherein the output of the rotary output module may be a shaft provided at the center of the flywheel shaft. As described in item 1 of the scope of the patent application, the linear kinetic energy generating device using cog energy is applied, wherein the output of the rotary output module may be an external gear, a pulley, etc. provided on the flywheel. The linear kinetic energy generating device using cog energy as described in item 1 of the scope of the patent application, wherein the device is composed of two sets of electromagnetic modules, two sets of linear modules and one set of rotary output modules. The rotary output module is provided with a flywheel at both ends of an output piece, and each flywheel is connected to the slide bars of the two sets of linear modules by a connecting rod. As described in item 1 or 8 of the scope of the patent application, the linear kinetic energy generating device using cogging energy is applied, wherein the connection relationship between the connecting rod of the rotary output module and the flywheel and the slider can be in the same position. According to the linear kinetic energy generating device using cogging energy as described in item 1 or 8 of the scope of the patent application, the connection relationship between the connecting rod of the rotary output module and the flywheel and the slider may be misaligned. According to the linear kinetic energy generating device using cogging energy as described in item 10 of the scope of the patent application, the connection relationship between the connecting rod of the rotary output module and the flywheel and the slider can be misaligned, and one of the linear module's When the slider is at the starting point of the trip, the slider of another set of linear modules is at the starting point of the stroke return. As described in item 1 of the scope of the patent application, the linear kinetic energy generating device using cog energy can be at least two, and the output of the rotary output module of each device can drive a driven shaft in parallel. According to the linear kinetic energy generating device using cogging energy as described in item 12 of the scope of the patent application, the connection relationship between the connecting rod of the rotary output module of each device and the flywheel and the slider can be in the same position. According to the linear kinetic energy generating device using cogging energy as described in item 12 or 13 of the scope of the patent application, the connection relationship between the connecting rod of the rotary output module of each device and the flywheel and the slider may be misaligned.