阅读说明：本技术 一种三位一体联动及往动储能单元装置系统 (Trinity linkage and forward movement energy storage unit device system ) 是由 范海燕 王娜 于 2019-07-18 设计创作，主要内容包括：本发明公开了一种三位一体联动及往动储能单元装置系统,包括能量驱动装置、第一联动装置和第二联动装置,能量驱动装置中设有驱动基板和能量储存介质,第一联动装置中设有第一联动基板,第二联动装置中设有第二联动基板,驱动基板的两侧分别与第一联动基板、第二联动基板通过联动连杆连接；驱动基板与一来动能量传递装置连接,来动能量传递装置用于驱动所述驱动基板挤压所述能量储存介质,并带动第一联动基板和第二联动基板分别做功。本发明将作用于驱动基板的能量通过联动连杆分别同时传递到第一联动装置和第二联动装置,通过联动,实现了在第一联动装置和第二联动装置交替做正功和负功过程。(The invention discloses a three-in-one linkage and forward movement energy storage unit device system which comprises an energy driving device, a first linkage device and a second linkage device, wherein a driving substrate and an energy storage medium are arranged in the energy driving device; the driving substrate is connected with a driving energy transfer device, and the driving energy transfer device is used for driving the driving substrate to extrude the energy storage medium and driving the first linkage substrate and the second linkage substrate to do work respectively. The invention simultaneously transmits the energy acting on the driving substrate to the first linkage device and the second linkage device through the linkage connecting rod respectively, and realizes the process of alternately performing positive work and negative work on the first linkage device and the second linkage device through linkage.)

1. A three-in-one linkage and forward movement energy storage unit device system is characterized by comprising an energy driving device (1), a first linkage device (2) and a second linkage device (3), wherein a driving substrate (11) and an energy storage medium (12) are arranged in the energy driving device (1), a first linkage substrate (21) is arranged in the first linkage device (2), a second linkage substrate (31) is arranged in the second linkage device (3), and two sides of the driving substrate (11) are respectively connected with the first linkage substrate (21) and the second linkage substrate (31) through linkage connecting rods (4); the driving substrate (11) is connected with a driving energy transmission device (5), and the driving energy transmission device (5) is used for driving the driving substrate (11) to extrude the energy storage medium (12) and driving the first linkage substrate (21) and the second linkage substrate (31) to do work respectively.

2. The triune linkage and forward movement energy storage unit device system according to claim 1, wherein the first linkage device (2) and the second linkage device (3) respectively comprise a linkage medium chamber (a) and a linkage working medium (b), one end of the linkage medium chamber (a) is open, the other end of the linkage medium chamber (a) is closed, the first linkage base plate (21) and the second linkage base plate (31) are respectively arranged in the corresponding linkage medium chamber (a) and form a sealing connection with the inner side surface of the corresponding linkage medium chamber (a) in a reciprocating motion, and the linkage working medium (b) is arranged in the linkage medium chamber (a).

3. The triune linkage and forward energy storage unit device system according to claim 2, characterized in that the energy storage medium (12) in the energy driving device (1) is a spring, one end of which is connected to the driving base plate (11) and the other end of which is connected to a bearing unit (13).

4. The triune linkage and forward movement energy storage unit device system according to claim 1, wherein the energy driving device (1) further comprises a sealed cavity (14), the driving substrate (11) is arranged in the sealed cavity (14) and is in sealing connection with the inner side surface of the sealed cavity in a reciprocating manner, and the linkage connecting rod (4) penetrates through the sealed cavity (14) and is fixedly connected with the driving substrate (11); the driving substrate (11) divides the closed cavity (14) into two chambers, the energy storage media (12) are respectively arranged in the two chambers, and an energy storage medium inlet (14a) and an energy storage medium outlet (14b) which are correspondingly communicated with the two chambers are respectively arranged on the closed cavity (14); the motive energy transfer device (5) comprises a motive energy transfer medium access device (51) and a motive energy transfer medium access device (52) which are connected to the respective chambers via the energy storage medium inlet (14a) and the energy storage medium outlet (14b), respectively.

5. The triune linkage and forward movement energy storage unit device system according to claim 4, wherein the first linkage device (2) and the second linkage device (3) respectively comprise a closed linkage medium chamber (a) and a linkage work medium (b), the first linkage base plate (21) and the second linkage base plate (31) are respectively arranged in the corresponding linkage medium chamber (a) and divide the corresponding linkage medium chamber (a) into an inner chamber and an outer chamber, the first linkage base plate (21) and the second linkage base plate (31) are respectively in reciprocating sealing connection with the inner side surface of the corresponding linkage medium chamber (a), and the linkage work medium (b) is arranged in the linkage medium chamber (a); the inner chamber of the first linkage (2) and the inner chamber of the second linkage (3) are communicated through a connecting pipeline (6).

6. The triune linkage and forward energy storage unit device system according to claim 5, wherein the connecting pipeline (6) is further provided with a medium inlet/outlet end with a control valve (7).

7. The triune linkage and forward energy storage cell device system of claim 4, wherein the energy storage medium (12) is one of a gas, a stored energy wave or solution or any other energy storage fluid.

8. The triune linkage and forward energy storage unit arrangement system according to any of claims 1-7, wherein the driving base plate (11), the first linkage base plate (21), and the second linkage base plate (31) are pistons or diaphragms.

9. The triune linkage and forward energy storage unit device system according to claim 8, wherein the linkage link (4) can also be a string or fascia that transmits motion.

Technical Field

The invention relates to the technical field of energy driving and energy exchange, in particular to a three-in-one linkage and forward movement energy storage unit device system.

Background

In the production and life processes of the nature and the mankind, a plurality of medium-low temperature heat sources exist, the heat is concentrated by the existing medium-low temperature heat source utilization technology, the heat is utilized after reaching higher temperature, but the utilization approach is very limited, and the utilization efficiency is extremely low.

Disclosure of Invention

Therefore, the energy storage unit device system capable of improving the energy utilization efficiency and solving the technical problem of low energy exchange efficiency in the prior art is provided.

A three-in-one linkage and forward movement energy storage unit device system comprises an energy driving device, a first linkage device and a second linkage device, wherein a driving substrate and an energy storage medium are arranged in the energy driving device; the driving substrate is connected with a driving energy transfer device, and the driving energy transfer device is used for driving the driving substrate to extrude the energy storage medium and driving the first linkage substrate and the second linkage substrate to do work respectively.

The first linkage device and the second linkage device respectively comprise a linkage medium chamber and a linkage acting medium, one end of the linkage medium chamber is open, the other end of the linkage medium chamber is closed, the first linkage base plate and the second linkage base plate are respectively arranged in the corresponding linkage medium chambers and form a sealing connection capable of reciprocating with the inner side surfaces of the corresponding linkage medium chambers, and the linkage acting medium is arranged in the linkage medium chambers. .

The energy storage medium in the energy driving device is a spring, one end of the spring is connected with the driving substrate, and the other end of the spring is connected with a bearing unit.

Or preferably, the energy driving device further comprises a closed cavity, the driving substrate is arranged in the closed cavity and is in reciprocating sealed connection with the inner side surface of the closed cavity, and the linkage connecting rod penetrates through the closed cavity and is fixedly connected with the driving substrate; the driving substrate divides the closed cavity into two chambers, the energy storage media are respectively arranged in the two chambers, and the closed cavity is respectively provided with an energy storage medium inlet and an energy storage medium outlet which are correspondingly communicated with the two chambers; the driving energy transmission device comprises a driving energy transmission medium access device and a driving energy transmission medium access device which are respectively connected with the corresponding chambers through the energy storage medium inlet and the energy storage medium outlet.

The first linkage device and the second linkage device respectively comprise a closed linkage medium chamber and a linkage acting medium, the first linkage substrate and the second linkage substrate are respectively arranged in the corresponding linkage medium chambers and divide the corresponding linkage medium chambers into an inner side chamber and an outer side chamber, the first linkage substrate and the second linkage substrate are respectively in sealing connection with the inner side surfaces of the corresponding linkage medium chambers in a reciprocating manner, and the linkage acting medium is arranged in the linkage medium chambers; the inner side chamber of the first linkage and the inner side chamber of the second linkage are communicated through a connecting pipeline.

And the connecting pipeline is also provided with a medium inlet and outlet end with a control valve.

The energy storage medium is one of gas, stored energy wave or solution or any other energy storage fluid.

The driving substrate, the first linkage substrate and the second linkage substrate are pistons or diaphragms.

The linkage link may also be a pull wire or fascia that transmits motion.

The technical scheme of the invention has the following advantages:

A. the energy acting on the driving substrate is respectively and simultaneously transmitted to the first linkage device and the second linkage device through the linkage connecting rod, and the functions of doing negative work on a linkage work-doing medium in the first linkage device and doing positive work on the linkage work-doing medium in the second linkage device are realized through linkage; or the function of applying negative work to the linkage work-applying medium at the second linkage device and applying positive work to the linkage work-applying medium at the first linkage device is realized, and the process of alternately applying positive work and negative work at the first linkage device and the second linkage device is realized.

B. When the invention is applied to another related conjugation effect, the invention can promote the other pair of conjugation effect and play a miraculous effect similar to the effect of a chemical catalyst.

C. Although the invention is not from the bionics research, after understanding the catalytic effect of the invention, through comparing with the structure of the biocatalysts such as chlorophyll and heme, the invention discovers that the physical structure of the invention has striking similarity with the micro molecular structure of the biocatalysts.

Drawings

In order to more clearly illustrate the embodiments of the present invention, the drawings which are needed to be used in the embodiments will be briefly described below, and it is apparent that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained from the drawings without inventive labor to those skilled in the art.

FIG. 1 is a schematic diagram of a three-in-one linkage and forward motion energy storage unit device system according to a first embodiment of the present invention;

fig. 2 is a schematic diagram of a three-in-one linkage and forward movement energy storage unit device system according to a second embodiment of the present invention.

Description of reference numerals:

1-energy driving device

11-drive base plate, 12-energy storage medium, 13-bearing unit

14-sealed cavity

14 a-energy storage medium inlet, 14 b-energy storage medium outlet

2-first linkage

21-first linkage base plate

3-second linkage

31-second linkage base plate

4-linkage connecting rod

5-motive energy transfer device

51-driven energy transfer medium access device

52-Forward energy transfer Medium Access device

6-connecting a pipeline; 7-control valve

a-a linkage medium chamber; b-linkage working medium.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1, the present invention provides a three-in-one linkage and forward movement energy storage unit device system, which includes an energy driving device 1, a first linkage device 2 and a second linkage device 3, wherein the energy driving device 1 is provided with a driving substrate 11 and an energy storage medium 12, the first linkage device 2 is provided with a first linkage substrate 21, the second linkage device 3 is provided with a second linkage substrate 31, and two sides of the driving substrate 11 are respectively connected with the first linkage substrate 21 and the second linkage substrate 31 through linkage connecting rods 4; the driving substrate 11 is connected to a driving energy transmission device 5, and the driving energy transmission device 5 is used for driving the driving substrate 11 to extrude the energy storage medium 12 and driving the first linkage substrate 21 and the second linkage substrate 31 to work respectively. The driving energy transfer device 5 provides initial power for the driving substrate 11, when the driving substrate is pushed outwards to do work, the driving energy transfer device 5 stops doing work outwards, and the energy storage medium drives the first linkage substrate 21 and the second linkage substrate 31 to reset.

The first linkage device 2 and the second linkage device 3 respectively comprise a linkage medium chamber a and a linkage acting medium b, the linkage medium chamber a is preferably open at one end, the other end is closed, the first linkage base plate 21 and the second linkage base plate 31 are respectively arranged in the corresponding linkage medium chamber a and form a sealing connection capable of reciprocating motion with the inner side surface of the corresponding linkage medium chamber a, and the linkage acting medium b is arranged in the linkage medium chamber a. The energy storage medium 12 in the energy driving device 1 is a spring, one end of the spring is connected to the driving substrate 11, and the other end of the spring is connected to a bearing unit 13.

When the acting force is applied to the driving substrate by the acting energy transfer device 5, the driving substrate descends and the spring is compressed, the first linkage substrate and the second linkage substrate move downwards under the driving of the linkage connecting rod, at the moment, the first linkage substrate performs suction action on the linkage medium chamber a to execute a negative work process, and the second linkage substrate performs extrusion action on the linkage medium chamber to execute a positive work process.

When the acting force applied to the driving base plate by the driving energy transfer device is stopped, the driving base plate can reset under the action of the resilience force of the spring, the first linkage base plate and the second linkage base plate are driven to reset through the linkage connecting rod, and partial energy accumulated by the spring is completely released.

As shown in fig. 2, the energy driving device 1 further includes a sealed cavity 14, the driving substrate 11 is disposed in the sealed cavity 14 and is in a sealing connection with an inner side surface thereof, the driving substrate can reciprocate, and the linkage connecting rod 4 penetrates through the sealed cavity 14 and is fixedly connected to the driving substrate 11; the driving substrate 11 divides the sealed cavity 14 into two chambers, the energy storage media 12 are respectively arranged in the two chambers, and the sealed cavity 14 is respectively provided with an energy storage medium inlet 14a and an energy storage medium outlet 14b which are correspondingly communicated with the two chambers, wherein the energy storage media 12 distributed in the two chambers can be the same medium or different media, and can adopt one of gas, stored energy waves or solution or any other energy storage fluid; the motive energy transmission device 5 includes a motive energy transmission medium access device 51 and a motive energy transmission medium access device 52, which are connected to the respective chambers through the energy storage medium inlet 14a and the energy storage medium outlet 14b, respectively.

The chambers in fig. 2 can be pressurized by the driving energy transmission medium access device 51, and the driving energy transmission medium access device 52 performs suction operation on the corresponding chambers, so that the driving substrate 11 moves downwards, the suction of the linkage medium chamber in the first linkage device is realized, and the extrusion of the linkage medium chamber in the second linkage device is realized; when the forward energy transfer medium inlet and outlet device performs pressurizing operation in the corresponding chamber and the forward energy transfer medium inlet and outlet device performs pumping operation in the corresponding chamber, the linkage medium chamber in the first linkage device is squeezed and the linkage medium chamber in the second linkage device is pumped under the action of the linkage connecting rod.

In fig. 2, the preferred first linkage device 2 and the preferred second linkage device 3 respectively include a closed linkage medium chamber a and a linkage acting medium b, the first linkage base plate 21 and the second linkage base plate 31 are respectively disposed in the corresponding linkage medium chamber a and divide the corresponding linkage medium chamber a into an inner chamber and an outer chamber, the first linkage base plate 21 and the second linkage base plate 31 are respectively in a sealing connection with the inner side of the corresponding linkage medium chamber a, and the linkage acting medium b is disposed in the linkage medium chamber a; the inner chamber of the first linkage 2 and the inner chamber of the second linkage 3 are connected by a connecting line 6. The inner side cavities of the linkage medium chambers of the first linkage device and the second linkage device are communicated through the communication pipeline, and the cavities can be filled with hydraulic oil, water, air and other media, so that the vacuum effect between the linkage base plates at two ends and the inner side cavities can be eliminated, and the linkage working medium and the lubricating effect in cooperation with thrust conduction and sealing can be achieved.

Further preferably, a medium inlet and outlet with a control valve 7 is also provided on the connecting line 6, so that control operations such as medium exchange can be performed.

The drive substrate 11, the first interlocking substrate 21, and the second interlocking substrate 31 are pistons or diaphragms. The linkage link 4 may also be a drawstring or fascia that transmits motion.

The following describes the action process of the entire system in detail.

A. The drive energy transmission device is controlled to transmit external drive action to act on the drive substrate, and the energy acting on the drive substrate has no positive and negative work attributes.

B. After the 'driving' action transmission is obtained, the driving substrate transmits energy to two ends simultaneously through the linkage connecting rod respectively, the first linkage substrate generates a suction effect on a medium in the linkage medium chamber at one end of the first linkage device, and the first linkage substrate applies negative work to the linkage acting medium in the linkage medium chamber; meanwhile, at one end of the second linkage device, the second linkage substrate generates an extrusion effect on the linkage acting medium in the linkage medium chamber, and the second linkage substrate performs positive work on the linkage acting medium; while the energy storage medium accumulates a portion of the energy during the drive.

C. The drive energy transmission device finishes the drive stroke of external drive, part of the energy stored in the energy storage medium starts to be released, and the substrate is driven to start the drive stroke of drive.

D. In the 'forward' stroke, the driving substrate transmits energy to the first linkage device and the second linkage device through the linkage connecting rod respectively and simultaneously, the first linkage substrate generates extrusion effect on a linkage acting medium of the linkage medium chamber, and the first linkage substrate performs positive work on the linkage acting medium; meanwhile, at the end of the second linkage device, the second linkage base plate generates a suction effect on the linkage acting medium of the linkage medium chamber, and the second linkage base plate applies negative work to the linkage acting medium.

E. And repeating the steps A and D, and continuously realizing the purposes that the system does negative work on the first linkage device, does positive work on the second linkage device in the 'moving' stroke, does positive work on the first linkage device end and does negative work on the second linkage device end in the 'moving' stroke.

Referring to fig. 2, the system continuously achieves the purpose of doing negative work at the first linkage, doing positive work at the second linkage, doing positive work at the first linkage end and doing negative work at the second linkage end in the 'forward' stroke by controlling the in and out of the forward energy transfer medium access devices at the two sides of the driving substrate and the in and out of the forward energy transfer medium access devices respectively to control the forward motion or the forward motion.

It should be understood that the above examples are only for clarity of illustration and are not intended to limit the embodiments. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And obvious variations or modifications therefrom are intended to be within the scope of the invention.