阅读说明：本技术 利用流体收集能量 (Harvesting energy using fluids ) 是由 阿兰·杰卡得 约翰·罗纳 吕克·马夫利 于 2019-09-13 设计创作，主要内容包括：系统管理流体对其环境变化的反应,以将这些反应转化为能量,从而收集该能量,同时当环境条件超过预定的阈值时,保护设备免受破坏或故障。(The system manages the reaction of the fluid to its environmental changes to convert these reactions into energy to harvest the energy while protecting the equipment from damage or malfunction when the environmental conditions exceed a predetermined threshold.)

1. An energy harvesting system (100) comprising a rigid reservoir (4, 204), a piston system (10) and a temperature range setting system (30), the energy harvesting system (100) containing a fluid (2), the reservoir being in fluid communication with:

(a) a piston system (10) which converts the volume change of the fluid into a mechanical movement, an

(b) A temperature range setting system (30) comprising at least a flexible chamber (22) and a range setting mechanism (20), wherein the flexible chamber (22) is connected with the range setting mechanism (20) to engage the movement of the piston system (10) within a given temperature range to manage the reactions of the fluid to its environmental changes to convert these reactions to a collection of energy, while the protection means is not destroyed or malfunctioning when the environmental conditions exceed a predetermined threshold, thereby automatically ensuring that the energy conversion is effective within the operating temperature range and protecting the system from under/over pressure outside the operating temperature range.

2. The system of claim 1, wherein the piston system (10) includes a bellows (132, 136, 142, 146).

3. The system of claim 1, wherein the piston system (10) comprises at least two bellows (132, 136, 142, 146) having different effective surfaces, arranged such that the resulting effective surface of the piston system is the difference between the effective surfaces of the at least two bellows.

4. The system of claim 1, wherein the at least two bellows (132, 136, 142, 146) are concentric.

5. The system of claim 1, wherein the mechanical motion generated by the piston system (10) is thereafter stored in the form of latent mechanical energy.

6. The system of claim 5, wherein the potential mechanical energy is stored by compressing or expanding a spring (36).

7. The system according to claim 5, wherein the potential mechanical energy is stored by winding barrel springs (74) or bending flexure beam springs (224).

8. The system of any of claims 1, 2, 3, or 4, wherein the mechanical energy is used to generate electricity directly through the generator (58) or to impart mechanical function animations in the wearable device (500).

9. The system according to any of the preceding claims, wherein the wearable device (500) is a timepiece (500).

10. A system according to any preceding claim, wherein the flexible chamber (22) comprises a bellows (24), the bellows (24) being constrained in its expansion by a follower (32) resting on a range setting cam (34), the range setting cam being held in a prescribed position.

11. A system according to claim 10, wherein the prescribed position is maintained by a combination of its own shape, the shape of the follower (32) and a torsion spring (36) providing a pretensioning moment.

12. A system according to any one of claims 10 or 11, wherein the interface between the follower (32) and the range setting cam (34) is a simple mechanical contact.

13. A system according to any one of claims 10, 11 or 12, wherein the friction is controlled such that the range setting cam (34) can rotate even under pressure.

14. System according to any one of claims 10 to 13, wherein the range setting cam (34) has several positions with different heights forming steps to define several filling levels of the flexible chamber (22).

15. The system according to claim 14, wherein the fill level corresponds to a total volume of the fluid (2) in the energy harvesting system (100) or a predetermined pressure threshold of the chamber (22).

16. A system according to any of the preceding claims, wherein the total volume of the fluid (2) corresponds to the temperature of the fluid (2) such that the flexible chamber (22) behaves like a rigid chamber as long as the flexible chamber (22) is limited in its expansion by the follower (32) resting on the range setting cam (34), any increase in volume of the fluid (2) being converted into a mechanical expansion movement by the piston system (10).

17. A system according to any of the preceding claims, wherein if the temperature of the fluid (2) increases, the volume of the fluid (2) increases, which volume increase is converted into mechanical work by the piston system (10) through an expansion movement (12) of the shaft (126) subject to the reaction force of the mechanism to be wound.

18. The system according to any of the preceding claims, wherein if the temperature of the fluid (2) increases until the mechanical movement (12) approaches its maximum height, the finger (42) attached to the shaft (126) of the piston system triggers the rotation of the range setting cam (34), directly or through the secondary means (44), so that with careful selection of the stiffness and surface of the piston system (10) and the stiffness and surface of the flexible chamber (22), and optionally the pre-tensioned spring and torsion spring (36), the flexible chamber expands until the next volume step defined by the range setting cam (34) is reached, at which time the flexible chamber behaves like a rigid chamber.

19. A system according to claim 18, wherein any further increase in the volume of the fluid (2) is converted by the piston system (10) into mechanical movement, such that when the temperature of the fluid (2) decreases, the volume of the fluid (2) decreases, and any decrease in the volume of the fluid (2) is converted into mechanical retraction movement of the piston system (10) and the flexible chamber (22).

20. The system of claim 19, wherein further, if the temperature of the fluid (2) decreases until the mechanical movement (12) reaches a minimum height defined by a hard dead center, e.g. the finger (42) contacts the body (162) of the piston system, further contraction of the fluid (2) is fully translated into contraction of the flexible chamber (22).

21. The system of any of claims 17 or 18, wherein a hard stop is reached when the finger (42) contacts a body (162) of the piston system.

22. A system according to any preceding claim, wherein the pre-load torque of the range setting cam (34) provided by the torsion spring (36) ensures that the range setting cam (34) follows the retraction of the flexible chamber (22) and assumes the nearest cam step in front of the follower (32) thereby returning the system to its previous volume range setting with a lower volume of the flexible chamber (22).

23. The system according to any of the preceding claims, wherein the range setting mechanism (20) is constructed as a plurality of knee lever mechanisms (60), the knee being deflected by a finger (42) attached to the piston system (10) when the maximum position is reached and being spring-reset once the flexible chamber (22) retracts after the temperature of the fluid (2) has decreased.

24. A system according to any of the preceding claims, wherein the fluid (2) is selected from one of the group of fluids comprising a liquid, a colloidal liquid, a gas or any combination or mixture of any number of these elements.

25. A system according to any of the preceding claims, wherein the fluid (2) comprises a solid element designed to react to changes in its environment, said solid element being selected from one of the group of solid elements comprising particles, colorants, dyes, salts, any other dissolved material, lattice structure, ballast weight and agitators.

26. A system according to any of the preceding claims, wherein the temperature range setting system (30) is a flexible chamber (222) having a stiffness higher than the stiffness of the piston system.

27. The system of claim 26, wherein the temperature range setting system (30) is a flexible chamber (222) maintained in a first position by a spring system (224, 226) having a non-linear characteristic when the ambient temperature is within the operating range, the spring system suddenly losing stiffness when the temperature increases and the resulting pressure in the system exceeds a predetermined threshold, the spring system returning to its original position when the temperature decreases and the resulting pressure in the system falls below the predetermined threshold.

28. A system according to any preceding claim, wherein the variable heat exchanger produces a change in thermal conductivity between the fluid (2) and its environment.

29. The system according to any of the preceding claims, wherein the temperature range setting system (30) is a flexible chamber (420, 421) connected to the primary fluid reservoir (402) through a passive relief valve.

Background

The present invention relates to a device and a method for collecting energy freely available from the environment by reacting a liquid to changes in its environment, such as changes in temperature, changes in direction relative to gravity, impact and/or radiation, etc.

In recent years, the collection of energy freely available from the environment has met with increasing interest in order to be able to power more and more portable or wearable devices and to avoid the use of electrical signals or power cables for remote action or sensing devices. The invention relates to the collection of energy by means of the reaction of a fluid to a change in its environment, such as a change in temperature, a change in direction relative to gravity, an impact and/or radiation, etc.

Disclosure of Invention

The present invention provides a means of managing the reactions of a fluid to its environmental changes to convert these reactions into energy harvesting while protecting the device from damage or failure when environmental conditions exceed a predetermined threshold.

Drawings

The drawings show, by way of example, different embodiments of the inventive subject matter.

Fig. 1A-1G are views of a preferred embodiment of the present invention.

Fig. 2A-2C are views of another embodiment of the present invention.

Fig. 3A-3D are views of optional features that may be added to any embodiment of the invention.

Fig. 4 is a cross-sectional view of yet another embodiment of the present invention.

Fig. 5 is a schematic diagram of a wearable device incorporating the present invention.

Skilled artisans will appreciate that elements in the figures are illustrated for simplicity and clarity and have not necessarily been drawn to scale. For example, the dimensions may be exaggerated relative to other elements to help to improve understanding of the invention and its embodiments. Furthermore, when terms such as "first," "second," etc. are used herein, they are used to distinguish between similar elements and not necessarily to describe a sequential or chronological order. Furthermore, relative terms such as "front," "back," "top," "bottom," and the like in the description and/or in the claims are not necessarily used to describe exclusive relative positions. Thus, those skilled in the art will understand that these terms are interchangeable with other terms, and that the embodiments described herein are capable of operation in other orientations than those explicitly illustrated or otherwise described.

Detailed Description

The following description is not intended to limit the scope of the invention in any way, as it is exemplary, for describing the best mode of the invention known to the inventors at the date of this application. Accordingly, changes may be made in the arrangement and/or function of any of the elements described in the exemplary embodiments disclosed herein without departing from the spirit and scope of the invention.

In the embodiment shown in FIG. 1A, energy harvesting with a fluid is shown. The energy harvesting system 100 includes: a fluid 2 contained within a rigid reservoir 4, and a temperature range setting system 30. The reservoir is in fluid communication with a piston system 10 which converts the volumetric change of the fluid 2 into a mechanical movement. The temperature range setting system 30 includes: (a) a flexible chamber 22 and (b) a range setting mechanism 20 that ensures that energy conversion is effective within the operating temperature range and protects the system from under/over pressure outside the operating temperature range. The mechanical movements generated by the piston system 10 are converted into suitable movements by means of a transmission 50, well known in the micromechanical industry, in order to store them in the form of mechanical energy, for example by means of compression or expansion springs, wound barrel springs (barrel springs), bent flexible beam springs (not shown), racks and pinions, or directly for generating electricity by means of a generator 58, or to impart mechanical functional animations in wearable devices such as watches or pocket watches or handbags. In a variant where the energy harvesting system operates in only one direction, in which case the mechanical movement generated by the piston system 10 can be used mainly for temperature increase and for temperature decrease for adjusting the temperature range setting system 30, since the maximum available pressure required to retract the bellows comes mainly from the environment and their own stiffness, this variant provides a solution for a simple energy storage mechanism (e.g. winding a barrel spring through the transmission 50). In another variation, the piston system 10 may include one or more preloaded springs such that the mechanical motion produced by the piston system 10 may be utilized both when the temperature increases and when the temperature decreases. For the mechanical storage of energy, this variant requires a more complex transmission 50, including a mechanical direction converter, which may increase mechanical play and losses, in order to wind a barrel spring, such as the one well known in the horological industry (barrel spring). For other applications, such as rotating bi-directional generators, this variation may be more efficient.

The fluid 2 is a liquid, a colloidal liquid, a gas or any combination or mixture of any number of these elements and may comprise a solid element designed to react to changes in its environment, such as particles, lattice structures, ballast weights or agitators, which changes may be changes in temperature, changes in direction relative to gravity, impact and/or radiation, etc. Fluid 2 may be selected to exhibit a sudden change in solubility of one or more of its components, or to undergo a reversible chemical reaction upon reaching a temperature threshold within the system operating range. The fluid 2 is selected and/or designed to exhibit a combination of compressibility and thermal expansion characteristics that are optimized for the energy harvesting system and described herein in accordance with various embodiments.

Referring now to fig. 1B-1C, the piston system 10 needs to convert fluid volume changes into mechanical motion very efficiently, and in order to be installed in a wearable device, the system must be constructed as compact as possible. The bellows 132, 136, 142 and 146 provide the function of a piston and a very high fluid tightness, but have a significant footprint due to the space used by the bellows to form its flexible side walls. In addition, their stiffness is directly related to the size of the corrugations. In order to obtain a relatively long movement 12 for a relatively low fluid volume difference 152, a smaller working surface is preferred. An optimized configuration for a particular application can be found with the emphasis on obtaining a relatively wide system for shorter lengths or a narrower body for longer lengths.

Referring now to fig. 1B, a design of the piston system 10 optimized for short lengths is obtained by installing a small bellows 132 having a small effective surface 134 inside a large bellows 142 having a larger effective surface 144, and then attaching them closely together to the base 122. The volume between the two bellows 132, 142 may then act as a piston. The movable part 124, which is tightly attached to the two bellows 132, 142, presents a resulting effective surface for converting the fluid volume change 152 into motion 12, which is smaller than the effective surface of the large piston 142, since it is the difference between the larger effective surface 144 and the smaller effective surface 134.

Referring now to FIG. 1C, by installing a small bellows 132 with a smaller effective surface 134 in front of a large bellows 142 with a larger effective surface 144 and tightly coupling them together on the movable part 124 that transmits the mechanical motion 12 through the rod 126, a piston system 10 configuration optimized for narrow bodies can be achieved. The other ends of the bellows 132, 142 are tightly attached within the system body 162. The volume between the interior of the system body 162 and the bellows 132, 142 receives fluid and acts as a piston, having an effective surface for converting the fluid volume change 152 into motion 12 that is smaller than the effective surface of the large piston 142. Because it is the difference between the larger effective surface 144 and the smaller effective surface 134. This configuration is preferred when the goal is to achieve a very small resulting effective surface, as it allows the small bellows 132 and the large bellows 142 to have nearly the same dimensions.

Referring now to fig. 1D, the configuration of the piston system 10 optimized for narrow bodies may risk bellows collapse (bucking) because the internal pressure may rise with a small resulting effective active surface and a long mechanical movement 12 compared to the length of the bellows. One solution involves dividing the small bellows 132 and the large bellows 142 into two or more portions, respectively bellows 136, 146. This allows the insertion of a movable connection element 164, which movable connection element 164 stiffens the bellows transversely to its extension and provides guidance to ensure linear movement through the rod 172 and the guide 174. Friction between the guide elements 172, 174 must be minimized to maximize the energy converted into motion. Such a construction comprising a connection element that stiffens the bellows transversely to its extension direction can also be used for realizing a non-linear piston system, for example for following an integrated circumference or radius in a circular device.

Referring now to FIG. 1E, for example, the range setting mechanism 20 is configured as a combination of a cam, follower, lever, spring, locker and/or trigger, for example, as is known in the art. The flexible chamber 22 is implemented as a bellows 24, which in its expansion is limited by a follower 32 resting on a range setting cam 34, which is held in position by a combination of its own shape, the shape of the follower 32, a guiding mechanism (not shown) and a helical or torsion spring 36 providing a pretension torque. The interface between the follower 32 and the range setting cam can be a simple mechanical contact, but in any case the friction needs to be well controlled so that the range setting cam remains rotating even under pressure and so that the switching threshold is well defined. One good way to control this friction is to use rollers that can be placed into the grooved features. The range setting cam 34 has several positions with different heights forming steps to define several filling levels of the flexible chamber 22. These fill levels correspond to the total volume of fluid 2 in the energy collection system 100. The switching point between the different filling levels is designed to handle the pressure limit of the range setting cam 34 to rotate under the action of the finger 42 on the secondary cam 44. The total volume of the fluid 2 corresponds to the temperature of the fluid 2. The volume of fluid 2 should match the internal volume of system 100, at least over the expected operating temperature range, except when the temperature is low (in which case the amount of fluid contraction may exceed the minimum volume of the system and evaporation may occur).

As long as the expansion of the flexible chamber 22 is limited by the follower 32 resting on the range setting cam 34, the flexible chamber behaves like a rigid chamber, any increase in the volume of the fluid 2 being converted into a mechanical expansion movement by the piston system 10. If the temperature of the fluid 2 increases, the volume of the fluid 2 increases, which is converted by the piston system 10 into a mechanical expansion movement 12. If the temperature of the fluid 2 increases until the mechanical movement 12 reaches near its maximum height, the finger 42 attached to the shaft 126 of the piston system triggers the rotation of the range setting cam 34, either directly or through the secondary cam 44 and/or a lever (not shown). With careful selection of the stiffness of the piston system 10 and the stiffness of the flexible chamber 22, plus the optional pre-loaded spring, the flexible chamber 22 expands until the next volume step defined by the range setting cam 34 is reached. From this point, flexible chamber 22 behaves like a rigid chamber. Any further increase in the volume of the fluid 2 is converted into mechanical movement by the piston system 10. As the temperature of the fluid 2 decreases, the volume of the fluid 2 decreases, any decrease in the volume of the fluid 2 is translated by the piston system 10 and the flexible chamber 22 into a mechanical retraction motion proportional to their relative stiffness and effective surface. If the temperature of the fluid 2 decreases until the mechanical movement 12 reaches a minimum height defined by hard dead center, e.g. the finger 42 contacts the body 162 of the piston system, further contraction of the fluid 2 is fully translated to contraction of the flexible chamber 22. The angular preload of the range-setting cam 34 provided by the torsion spring 36 ensures that the range-setting cam 34 follows the contraction of the flexible chamber 22 and assumes the nearest cam step in front of the follower 32, so that the system can work again once the temperature of the fluid 2 has increased again.

Referring now to fig. 1F-1G, range setting mechanism 20 is constructed, for example, as a combination of cams, followers, levers, springs, lockers, and/or triggers, as is well known in the micro-machining industry. The flexible chamber 22 is realized as a bellows 24, which in its expansion is limited by a stop plate 66, which stop plate 66 is connected with knee levers 62, 64 attached together and with a structure by means of a pivot, forming a knee lever mechanism 60. During normal operation of energy harvesting system 100, knee levers 62, 64 are held in an extended position by spring 74 and stop 72, providing a rigid fixation for bellows stop plate 66, thereby providing maximum efficiency for piston system 10 to convert fluid 2 volume changes into mechanical motion 12. If the fluid 2 temperature rises above a predetermined threshold, the shaft 126 of the piston system triggers the deflection of the knee levers 62, 64. This can be accomplished by the cam 52 attached to the shaft 126 of the piston system pushing the knee levers 62, 64 through the sliding finger 54, or by any other mechanical transmission system known in the micro-machining industry. Once the knee levers 62, 64 are displaced from their extended positions, the stiffness of the securement means of the bellows stop plate 66 is reduced, thereby extending the flexible chamber 22 and avoiding overpressure in the system. Once the temperature drops below a predetermined threshold, spring 74 will return knee levers 62, 64 to position, and the flexible chamber is again made rigid by its stop plate 66.

More than one such knee lever mechanism 60 may be used in parallel, each mechanism 60 having a different extension length and activated in sequence, thereby providing several effective operating ranges and safety thresholds to avoid over-pressurization in the system 100. In this case, several ranges of sequence may be ensured by combinations of cams, followers, levers, springs, lockers and/or triggers, for example, as are well known in the micromechanical industry.

In the embodiment shown in fig. 2A, fluid 202 is contained in a rigid reservoir 204, reservoir 204 being in fluid communication with main bellows 210 and safety bellows 222. The main bellows 210 is sized to have a stiffness lower than that of the safety bellows 222. Thus, the volume change of the fluid 202 in reaction to the environmental change is translated in inverse proportion to the stiffness ratio of the bellows 210, 222 and its effective surface. The main bellows 210 is attached to the barrier arm 212 and the mechanical actuator arm 220, and the mechanical actuator arm 220 actuates the actuator system 230. In case the volume of the fluid 202 increases beyond the maximum allowed extension of the main bellows 210, an over-extension of the main bellows 210 is avoided by the blocking arm 212 reaching the top dead center 216. Since the main bellows 210 cannot be extended any more, all of the volume increase is transferred to the safety bellows 222. The pressure increase per temperature increment is strongly reduced due to the presence of the safety bellows 222 compared to a chamber system without the safety bellows 222. In the same manner, when a fluid volume contraction occurs, over-compression of main bellows 212 is avoided by blocking arm 212 from reaching down stop 218. The relief bellows 222 absorbs the remaining fluid volume reduction. Alternatively, if the liquid pressure becomes low enough, the fluid 202 in the liquid phase may vaporize, conforming the fluid by forming a vapor phase, limiting the pressure drop and protecting the system from cryogenic damage. The system described herein is easy to construct and suffers from a loss of efficiency due to the safety bellows 222 (which continuously absorbs a portion of the fluid volume change in a ratio defined by the stiffness ratio of the bellows 210, 222 and their effective area).

Referring now to fig. 2B-2C, an improvement in system efficiency may be obtained by adding a non-linear stiffness system to modify the general linear stiffness behavior of safety bellows 222. Such a non-linear stiffness system may take the form of a knee lever mechanism as described above, or any other system commonly known in the industry, or as described herein, as a compression spring 224 mounted on a pivot 226. As long as the temperature of the fluid 222 remains within the operating range of the system (fig. 2B), the barrier arm 212 does not contact the upper stop 216, and the stiffness of the safety bellows 222 increases due to the addition of the compression spring 224, increasing the efficiency of the system. The buckling stiffness of the compression spring 224 is selected such that if the temperature of the fluid 222 rises above the maximum allowable elongation of the main bellows 210 (fig. 2C), the blocking arm 212 reaches the upper stop 216, increasing the sensitivity of the pressure rise of the fluid 222 to temperature units, causing the force on the compression spring 224 to increase rapidly, inducing buckling of the compression spring 224. When the compression spring is flexed, the stiffness of the compression spring decreases, and the overall stiffness of the combination of the safety bellows 222 and the compression spring 224 decreases to almost only that of the safety bellows 222, ensuring protection of the system.

Referring now to FIG. 3A, an optional variable heat exchanger may be added to any of the embodiments of the present invention disclosed and described herein to enhance the sensitivity of the system to temperature changes. The fluid reservoir 301 contains a fluid that is sensitive to temperature changes, the volume changes of which are translated into mechanical movements as described in other embodiments. A portion of this generated mechanical energy is used to move the heat exchanger 302 so that the thermal conductivity between the environment and the fluid reservoir 301 varies regularly. The frequency at which the heat exchanger passes close to the reservoir 301 must be set according to the thermodynamics of the system. For example, if the variable heat exchanger is used in a wall clock or wristwatch, the heat exchanger 302 may rotate at the same speed as the minute hand, hour hand, or any other relatively slow moving component of the watch mechanism. Referring to fig. 3B, 3C, 3D, the primary heat source 303 is the wrist of the wearer. At the beginning of the cycle, as shown in fig. 3B, the heat exchanger 302 is not in the thermal path between the heat source 303 and the fluid reservoir 301. In this way, the temperature of the fluid reservoir 301 evolves towards ambient temperature. After one-quarter of the cycle, the heat exchanger 302 is half-coupled between the heat source 303 and the fluid reservoir 301, as shown in fig. 3C, facilitating a thermal path from the heat source 303 to the fluid reservoir 301. As shown in fig. 3D, after half a cycle, the heat exchanger 302 is fully engaged between the heat source 303 and the fluid reservoir 301, and thus the temperature of the fluid reservoir 301 is close to the temperature of the heat source 303. After a further quarter of the cycle, the heat exchanger 302 is half-decoupled from the thermal path between the heat source 303 and the fluid reservoir 301, and the temperature of the fluid reservoir 301 approaches ambient temperature. For optimal operation of the system, the heat exchanger 302 must have a low heat capacity and a high conductivity. Since the vacuum or gas barrier is a good thermal insulator, the variable heat exchanger can also be implemented as an empty vessel, rotating within a reservoir containing one or more highly thermally conductive fluids.

In the embodiment shown in fig. 4, the fluid 401 is contained in a main reservoir 402. The main vessel 402 is in fluid communication with the main bellows 403 and with the secondary vessel 420 through at least two check valves 410, 411 arranged in opposite directions. The volumetric change of the fluid 401 in response to changes in its environment (i.e., the environment surrounding the embodiment 400) is translated into motion of the moving face 404 of the main bellows 403. This movement can be used by way of a mechanical system for the take-up of a mechanical energy storage system, or converted into electrical energy by a generator system, or used to trigger the action of any subsequent system (not shown here). The main bellows 403 is protected from over-compression by a mechanical stop 405 and from over-tension by another mechanical stop 406. As the temperature increases, the primary bellows 403 expands until a mechanical stop 406 is reached. With further increases in temperature, the pressure within the main vessel 402 increases rapidly, possibly exceeding the maximum pressure limit of the system 400. The pressure relief check valve 410 will then open fluid communication with the secondary reservoir 420, relieving the pressure within the chamber 402. The cracking pressure of release check valve 410 must be selected to open release check valve 410 just before the pressure increase exceeds the resistance of container 402 and bellows 403. The secondary reservoir 420 is connected to a secondary bellows 421 to accommodate pressure relief to avoid damage to the system 400. Bellows 421 can be preloaded in a manner similar to bellows 222 of fig. 2B-2C, with a linear or non-linear spring similar to 224 and a fixture similar to 226, or a range setting mechanism as described in fig. 1E-1G. Upon such activation of release check valve 410, the operating range of main bellows 403 shifts to a higher total fluid volume because bellows 403 is farther away from mechanical stop 406, allowing more energy to be collected if the temperature continues to rise. If the temperature of the entire system drops, the pressure of chamber 420 will drop slower than the pressure of chamber 402, provided the volume of chamber 420 is less than the volume of chamber 402. Therefore, when the pressure difference between the tank 420 and the main tank 402 reaches the opening pressure of the check valve 411, the system automatically returns to the original operating range. Alternatively, the reset may be triggered by applying an external reset force to surface 412 of secondary bellows 421 to achieve the opening pressure of valve 411, as desired by the user. As long as the pressure differential between the secondary reservoir 420 and the main reservoir 402 is above the closing pressure of the reset check valve 411, the fluid 401 will flow through the reset check valve 411 until the lower pressure is restored in the main reservoir 402. When used in a timepiece or other high precision instrument, careful design of the system is required to set its operating range within which maximum response to environmental changes can be obtained.

Because it is not possible for the applicant to know the state of the art in practice, the invention claimed herein should be construed as any combination of functionally independent elements which are later discovered by examination to be novel and inventive.

All embodiments described herein above are also applicable when the fluid is made of a combination of at least one liquid and at least one gas dissolved in said fluid. The liquid may also contain solid particles, colorants, dyes, salts or any other dissolved material. The fluid may also contain portions of the same material in different physical states (e.g., solid, liquid, and/or gas). In this case, the change in volume of the fluid may be increased by a combination of several reactions of the fluid to changes in its environmental conditions. For example, shock and vibration may trigger the release of dissolved gases from liquids; radiation may initiate chemical reactions between components of the fluid, temperature changes may result in changes in phase equilibrium between different physical states of the material, temperature changes may result in changes in chemical equilibrium between different fluids, and other effects.

Depending on the intended use of the device incorporating the system of the invention, either reversible or irreversible reactions may be employed.

Radiation, such as natural ultraviolet light provided by the sun or some type of illumination, may be used to trigger the chemical reaction, in which case at least a portion of the fluid container may be made of an ultraviolet light transparent material.

Incorporated herein by reference and in accordance with the contents of U.S. patent No. 10,031,481, entitled "temperature driven winding system," filed on 3/17/2014.

It should be understood that the particular embodiments shown and described herein are representative of the invention and its best mode and are not intended to limit the scope of the invention in any way.

The present invention can be summarized as including the following feature sets:

1. an energy harvesting system (100) comprising a rigid reservoir (4, 204), a piston system (10) and a temperature range setting system (30), the energy harvesting system (100) containing a fluid (2), the reservoir being in fluid communication with:

(a) a piston system (10) which converts the volume change of the fluid into a mechanical movement, an

(b) A temperature range setting system (30) comprising at least a flexible chamber (22) and a range setting mechanism (20), wherein the flexible chamber (22) is connected with the range setting mechanism (20) to engage the movement of the piston system (10) within a given temperature range to manage the reactions of the fluid to its environmental changes to convert these reactions to a collection of energy, while protecting the device from damage or malfunction when environmental conditions exceed a predetermined threshold, thereby automatically ensuring that the energy conversion is effective within the operating temperature range and protecting the system from under/over pressure outside the operating temperature range.

2. The system according to feature set 1, wherein the piston system (10) comprises a bellows (132, 136, 142, 146).

3. The system according to feature set 1, wherein the piston system (10) comprises at least two bellows (132, 136, 142, 146) having different effective surfaces, arranged such that the resulting effective surface of the piston system is the difference between the effective surfaces of the at least two bellows.

4. The system according to feature set 1, wherein the at least two bellows (132, 136, 142, 146) are concentric.

5. The system according to feature set 1, wherein the mechanical movement generated by the piston system (10) is then stored in the form of potential mechanical energy.

6. The system according to feature set 5, wherein the potential mechanical energy is stored by compressing or expanding a spring (36).

7. The system according to feature set 5, wherein the potential mechanical energy is stored by winding barrel springs (74) or bending flexure beam springs (224).

8. A system according to any one of the feature sets 1, 2, 3 or 4, wherein the mechanical energy is used for generating electricity directly by a generator (58) or for animating mechanical functions in the wearable device (500).

9. The system of any of the above feature sets, wherein the wearable device (500) is a timepiece (500).

10. The system according to any of the above feature sets, wherein the flexible chamber (22) comprises a bellows (24), which bellows (24) is limited in its expansion by a follower (32) resting on a range setting cam (34), which is held in a defined position.

11. The system according to feature set 10, wherein said defined position is maintained by a combination of its own shape, the shape of the follower (32) and a torsion spring (36) providing a pretension moment.

12. The system according to any one of feature sets 10 or 11, wherein the interface between the follower (32) and the range setting cam (34) is a simple mechanical contact.

13. A system according to any one of the feature sets 10, 11 or 12, wherein the friction is controlled such that the range setting cam (34) can still rotate even under pressure.

14. System according to any one of the set of characteristics 10 to 13, wherein the range setting cam (34) has several positions with different heights forming steps to define several filling levels of the flexible chamber (22).

15. The system according to the set of features 14, wherein the fill level corresponds to a total volume of the fluid (2) in the energy harvesting system (100) or a predetermined pressure threshold of the chamber (22).

16. System according to any of the above feature sets, wherein the total volume of the fluid (2) corresponds to the temperature of the fluid (2) so that the flexible chamber (22) behaves like a rigid chamber as long as the flexible chamber (22) is limited in its expansion by the follower (32) resting on the range setting cam (34), any increase in volume of the fluid (2) being converted into a mechanical expansion movement by the piston system (10).

17. System according to any of the above feature sets, wherein if the temperature of the fluid (2) increases, the volume of the fluid (2) increases, this volume increase being converted into mechanical work by the piston system (10) through the expansion movement (12) of the shaft (126) subject to the reaction force of the mechanism to be wound.

18. The system according to any of the above feature sets, wherein if the temperature of the fluid (2) increases until the mechanical movement (12) approaches its maximum height, the finger (42) attached to the shaft (126) of the piston system triggers the rotation of the range setting cam (34), either directly or through the secondary means (44), so that with careful selection of the stiffness and surface of the piston system (10) and the stiffness and surface of the flexible chamber (22), and optionally the pre-tensioned spring and torsion spring (36), the flexible chamber expands until the next volume step defined by the range setting cam (34) is reached, at which time the flexible chamber behaves like a rigid chamber.

19. The system according to feature set 18, wherein any further increase in the volume of the fluid (2) is converted by the piston system (10) into mechanical movement, such that when the temperature of the fluid (2) decreases, the volume of the fluid (2) decreases, and any decrease in the volume of the fluid (2) is converted into mechanical retraction movement of the piston system (10) and the flexible chamber (22).

20. The system according to feature set 19, wherein further, if the temperature of the fluid (2) decreases until the mechanical movement 12 reaches a minimum height defined by hard dead center, e.g. the finger (42) contacts the body (162) of the piston system, further contraction of the fluid (2) is fully converted to contraction of the flexible chamber (22).

21. The system according to any one of feature sets 17 or 18, wherein a hard stop is reached when the finger (42) contacts the body (162) of the piston system.

22. The system according to any of the above feature sets wherein the pretension torque of the range setting cam (34) provided by the torsion spring (36) ensures that the range setting cam (34) follows the retraction of the flexible chamber (22) and presents the nearest cam step in front of the follower (32) thereby returning the system to its previous volumetric range setting with a lower flexible chamber (22) volume.

23. The system according to any of the above feature sets, wherein the range setting mechanism (20) is constructed as a plurality of knee lever mechanisms (60), the knee being deflected by a finger (42) attached to the piston system (10) when the maximum position is reached and being spring-reset once the flexible chamber (22) retracts after the temperature of the fluid (2) decreases.

24. The system according to any of the above feature sets, wherein the fluid (2) is selected from one of the group of fluids comprising a liquid, a colloidal liquid, a gas or any combination or mixture of any number of these elements.

25. A system according to any of the above feature sets, wherein the fluid (2) comprises a solid element designed to react to changes in its environment, said solid element being selected from one of the group of solid elements comprising particles, colorants, dyes, salts, any other dissolved material, lattice structure, ballast weight and agitators.

26. The system according to any of the above feature sets, wherein the temperature range setting system (30) is a flexible chamber (222) having a stiffness higher than a stiffness of the piston system.

27. The system according to feature set 26, wherein the temperature range setting system (30) is a flexible chamber (222) maintained in a first position by a spring system (224, 226) having non-linear characteristics when the ambient temperature is within the operating range, the spring system suddenly losing stiffness when the temperature increases and the resulting pressure in the system exceeds a predetermined threshold, the spring system returning to its original position when the temperature decreases and the resulting pressure in the system falls below a predetermined threshold.

28. A system according to any of the above feature sets, wherein the variable heat exchanger produces a thermal conductivity variation between the fluid (2) and its environment.

29. The system according to any of the above feature sets, wherein the temperature range setting system (30) is a flexible chamber (420, 421) connected to the primary fluid reservoir (402) through a passive relief valve.

As will be appreciated by one skilled in the art, the present invention may be embodied as a system, apparatus or method.

Further, the system contemplates the use, sale, and/or distribution of any goods, services, or information having functionality similar to that described herein.

The specification and figures are to be regarded in an illustrative rather than a restrictive sense, and all such modifications are intended to be included within the scope of present invention. The scope of the invention should, therefore, be determined with reference to the appended claims, whether presently existing or later to be amended or added, and their legal equivalents, rather than by merely the examples described above. The steps recited in any method or process claims, unless explicitly stated otherwise, may be performed in any order and are not limited to the specific order presented in any claims. Furthermore, the elements and/or components recited in the apparatus claims may be assembled or otherwise functionally configured in various permutations to produce substantially the same result as the present invention. Accordingly, the invention should not be construed as limited to the particular configurations set forth in the claims.

The benefits, advantages, and solutions to problems that may be caused by the operation of any and all of the following claims should not be construed as critical, required, or essential features or elements of any or all of the claims.

As used herein, the terms "comprises," "comprising," or any other variation thereof, are intended to refer to a non-exclusive list of elements such that any apparatus, process, method, article, or composition of the invention that comprises a list of elements does not include only those elements recited, but may include other elements such as those elements recited in the specification. The use of the term "comprising" or "containing" or "consisting essentially of, unless otherwise expressly stated, is not intended to limit the scope of the invention to the elements listed thereafter, unless otherwise specifically indicated. Other combinations and/or modifications of the above-described elements, materials or structures used in the practice of the invention may be varied or adapted by those skilled in the art without departing from the general principles of the invention.

Unless otherwise indicated, the above patents and articles are intended to be within the scope of the present disclosure, which is incorporated herein by reference.

Other features and embodiments of the invention are described in the appended claims.

Furthermore, the invention should be considered to include all possible combinations of each of the features described in the present specification, appended claims and/or drawings, which may be considered new, inventive and industrially applicable.

Additional features and functions of the invention are described in the claims and/or abstract that follow the description. Such claims and/or abstract are hereby incorporated by reference in their entirety into this specification, and are to be considered a part of the filed application.

Many variations and modifications are possible in the embodiments of the invention described herein. While certain exemplary embodiments of the present invention have been shown and described herein, a wide range of changes, modifications, and substitutions is contemplated in the foregoing disclosure. While the above description contains many specifics, these should not be construed as limitations on the scope of the invention, but rather as exemplifications of one or another preferred embodiment thereof. In some instances, some features of the present invention may be employed without a corresponding use of the other features. Accordingly, it is appropriate that the foregoing description be construed broadly and understood as being given by way of illustration only, the spirit and scope of the invention being limited only by the claims which ultimately issue in this application.