CN216592306U - Stirling refrigerator - Google Patents

Abstract

The utility model relates to a refrigeration plant technical field discloses a stirling refrigerator, including stirling refrigerator cold head device, it includes that inside cavity is formed with the first casing of compression chamber, is equipped with the piston head in the compression chamber, and stirling refrigerator still includes the double-acting-wire linear compression device who is used for compressing first working medium, and double-acting-wire linear compression device includes: the second shell is fixedly connected with the first shell, and a first channel which is coaxial with the compression cavity is arranged in the second shell; the first rotor assembly is arranged in the first channel and defines an expansion cavity with the first shell; and the second rotor assembly is arranged inside the first rotor assembly, one end of the second rotor assembly is fixedly connected with the first rotor assembly, and the other end of the second rotor assembly is connected with the piston head through a connecting rod. According to the Stirling refrigerator provided by the embodiment of the disclosure, the motion phase and the displacement of the first mover assembly and the motion phase and the displacement of the piston head can be different by controlling the difference of the driving force and the motion phase of the first mover assembly and the second mover assembly.

Description

Stirling refrigerator

Technical Field

The application relates to the technical field of refrigeration equipment, for example to a Stirling refrigerator.

Background

With the development of military, medical and aerospace technologies, cryogenic cooling equipment has been developed in great quantities. The stirling cryocoolers have different requirements, and include various types, including rotary type integrated type, linear separated type, and linear integrated type. However, the existing rotary integral Stirling refrigerating machine has large volume and large vibration, and a counterweight is also added for reducing the vibration; the linear split type Stirling refrigerator is divided into a compressor and an expander, the middle of the compressor and the expander is connected through a pipeline, vibration is reduced to a certain extent due to the fact that the linear compressor is separated from a cold head, but an expansion piston of the expander can only be in a passive driving state, the efficiency of the whole machine is reduced, if the expansion piston of the expander is also driven actively, the other compressor is driven, although the middle connecting pipeline is omitted, the compressor and the cold head are integrally connected, vibration is increased to a certain extent, the efficiency is improved to a certain extent, and the problem that the expansion piston cannot be driven actively exists.

SUMMERY OF THE UTILITY MODEL

The following presents a simplified summary in order to provide a basic understanding of some aspects of the disclosed embodiments. This summary is not an extensive overview nor is intended to identify key/critical elements or to delineate the scope of such embodiments but rather as a prelude to the more detailed description that is presented later.

The embodiment of the disclosure provides a Stirling refrigerator, which is used for reducing the noise and vibration of the Stirling refrigerator and controlling the operation displacement and phase of a double-stator linear compression device and the movement displacement and phase of a piston head in an active driving mode.

In some embodiments, the stirling cooler comprises a stirling cooler cold head device including a first housing having a hollow interior forming a compression chamber, a piston head disposed within the compression chamber, and a dual-stator linear compression device for compressing a first working medium, the dual-stator linear compression device comprising: the second shell is fixedly connected with the first shell, and a first channel which is coaxial with the compression cavity is arranged in the second shell; a first mover assembly disposed in the first passage and defining an expansion chamber with the first housing, the first mover assembly being configured to move in a direction toward the first housing along an axial direction of the expansion chamber under a driving force; the second rotor assembly is arranged inside the first rotor assembly, one end of the second rotor assembly is fixedly connected with the first rotor assembly, the other end of the second rotor assembly is connected with the piston head through a connecting rod, and the second rotor assembly is configured to synchronously drive the piston head to move in the compression cavity in the direction of the first shell inside the first rotor assembly under the action of driving force so as to compress the first working medium.

In some embodiments, the dual-mover linear compression device further comprises: and the stator assembly is fixedly arranged on the second shell, forms clearance seal with the first rotor assembly and is configured to drive the first rotor assembly to reciprocate along the axial direction of the expansion cavity.

In some embodiments, the stator assembly comprises: a stator frame configured as a cylindrical structure; the stator magnetic induction coil is arranged inside the stator framework; the first rotor assembly is provided with a magnetic part which is acted with the stator magnetic induction coil.

In some embodiments, the first mover assembly includes: the permanent magnet is internally hollow and provided with a second channel and is configured to move along the axial direction of the expansion cavity under the driving of the stator assembly; and one end of the first resonance spring is fixedly connected with the second shell, and the other end of the first resonance spring is fixedly connected with the permanent magnet.

In some embodiments, the second mover assembly includes: a mover frame disposed in the second passage and configured as a cylindrical structure, wherein the connecting rod penetrates the permanent magnet to connect the mover frame and the piston head; the rotor magnetic induction coil is arranged inside the rotor framework and is electrically connected with an external driving module; and one end of the second resonance spring is fixedly connected with the permanent magnet, and the other end of the second resonance spring is fixedly connected with the rotor framework.

In some embodiments, the first resonant spring is a plate spring or a flexible spring.

In some embodiments, the stirling cooler cold head device further comprises a hot end heat exchanger, a heat regenerator and a cold end heat exchanger which are connected in sequence, wherein the hot end heat exchanger is arranged in the compression cavity and at one end far away from the second shell.

In some embodiments, the hot-end heat exchanger is a shell-and-tube heat exchanger, a flow channel of a second working medium is arranged inside the shell-and-tube heat exchanger, and the second working medium can exchange heat with the first working medium.

In some embodiments, the regenerator is internally filled with a porous medium, and the porous medium is a stainless steel wire mesh, stainless steel fibers or lead shot.

In some embodiments, the stirling cooler cold head apparatus further comprises: and the third shell is sleeved outside the first shell and defines a third channel together with the first shell, wherein the third channel is communicated with the expansion cavity.

The Stirling refrigerator provided by the embodiment of the disclosure can realize the following technical effects:

the first rotor component and the first shell define an expansion cavity, the first rotor component moves towards the direction of the first shell along the axial direction of the expansion cavity under the action of driving force to compress a first working medium so as to realize the active movement of the first rotor component, and the second rotor component moves towards the direction of the first shell in the compression cavity under the action of driving force to synchronously drive the piston head to move in the first channel so as to compress the first working medium so as to realize the active movement of the piston head; through the difference of the magnitude of the driving force and the motion phase of the first rotor assembly and the second rotor assembly, the difference of the motion displacement and the phase of the first rotor assembly and the motion displacement and the phase of the piston head can be realized, and compared with the existing Stirling refrigerating machine, the refrigerating efficiency of the refrigerating machine is improved while the noise and the vibration are reduced.

The foregoing general description and the following description are exemplary and explanatory only and are not restrictive of the application.

Drawings

One or more embodiments are illustrated by way of example in the accompanying drawings, which correspond to the accompanying drawings and not in limitation thereof, in which elements having the same reference numeral designations are shown as like elements and not in limitation thereof, and wherein:

FIG. 1 is a schematic diagram of a Stirling cooler according to an embodiment of the present disclosure;

FIG. 2 is an enlarged schematic view of section A of FIG. 1 according to an embodiment of the present disclosure;

fig. 3 is an enlarged schematic view of a portion B of fig. 1 according to an embodiment of the disclosure.

Reference numerals:

100. a stirling cooler cold head device;

110. a first housing; 120. a compression chamber; 130. a piston head;

140. a connecting rod; 150. a hot end heat exchanger; 160. a heat regenerator;

170. a cold end heat exchanger; 180. a third housing; 190. a third channel;

200. a double-rotor linear compression device;

210. a second housing; 211. a first channel;

220. a first mover assembly; 221. an expansion chamber; 222. a second channel;

223. a permanent magnet; 224. a first resonant spring;

230. a second mover assembly; 231. a rotor framework; 233. a second resonant spring;

240. a stator assembly; 241. and a stator framework.

Detailed Description

So that the manner in which the features and elements of the disclosed embodiments can be understood in detail, a more particular description of the disclosed embodiments, briefly summarized above, may be had by reference to the embodiments, some of which are illustrated in the appended drawings. In the following description of the technology, for purposes of explanation, numerous details are set forth in order to provide a thorough understanding of the disclosed embodiments. However, one or more embodiments may be practiced without these details. In other instances, well-known structures and devices may be shown in simplified form in order to simplify the drawing.

The terms "first," "second," and the like in the description and in the claims, and the above-described drawings of embodiments of the present disclosure, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It should be understood that the data so used may be interchanged under appropriate circumstances such that embodiments of the present disclosure described herein may be made. Furthermore, the terms "comprising" and "having," as well as any variations thereof, are intended to cover non-exclusive inclusions.

In the embodiments of the present disclosure, the terms "upper", "lower", "inner", "middle", "outer", "front", "rear", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings. These terms are used primarily to better describe the disclosed embodiments and their examples and are not intended to limit the indicated devices, elements or components to a particular orientation or to be constructed and operated in a particular orientation. Moreover, some of the above terms may be used in other meanings besides orientation or positional relationship, for example, the term "upper" may also be used in some cases to indicate a certain attaching or connecting relationship. The specific meanings of these terms in the embodiments of the present disclosure can be understood by those of ordinary skill in the art as appropriate.

In addition, the terms "disposed," "connected," and "secured" are to be construed broadly. For example, "connected" may be a fixed connection, a detachable connection, or a unitary construction; can be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements or components. Specific meanings of the above terms in the embodiments of the present disclosure can be understood by those of ordinary skill in the art according to specific situations.

The term "plurality" means two or more unless otherwise specified.

In the embodiment of the present disclosure, the character "/" indicates that the preceding and following objects are in an or relationship. For example, A/B represents: a or B.

The term "and/or" is an associative relationship that describes objects, meaning that three relationships may exist. For example, a and/or B, represents: a or B, or A and B.

It should be noted that, in the case of no conflict, the embodiments and features in the embodiments of the present disclosure may be combined with each other.

FIG. 1 is a schematic view of a Stirling cooler according to an embodiment of the present disclosure; fig. 2 is an enlarged schematic view of a portion a of fig. 1 according to an embodiment of the disclosure.

Referring to fig. 1 and 2, the embodiment of the present disclosure provides a stirling cooler including a stirling cooler cold head device 100 and a dual-stator linear compression device 200. The stirling cooler cold head apparatus 100 includes a first housing 110 having a hollow interior formed with a compression chamber 120, a piston head 130 disposed within the compression chamber 120. The dual-rotor linear compression device 200 is used for compressing a first working medium and comprises a second shell 210, a first rotor assembly 220 and a second rotor assembly 230. The second housing 210 is fixedly connected to the first housing 110, and a first passage 211 is formed therein and coaxially disposed with the compression chamber 120. The first mover assembly 220 is disposed in the first passage 211, defines a second passage 222 therein, and defines an expansion chamber 221 with the first housing 110, and is configured to move in a direction toward the first housing 110 along an axial direction of the expansion chamber 221 by a driving force. The second mover assembly 230 is disposed inside the first mover assembly 220, one end of the second mover assembly is fixedly connected to the first mover assembly 220, and the other end of the second mover assembly is connected to the piston head 130 through a connecting rod, and is configured to move towards the first casing 110 inside the first mover assembly 220, i.e., inside the second channel 222, under the action of a driving force, so as to synchronously drive the piston head 130 to move in the compression cavity 120, and compress the first working medium.

The stirling cooler includes a stirling cooler cold head device 100 and a dual-stator linear compression device 200. The stirling cooler cold head device 100 includes a first housing 110, the first housing 110 is hollow to form a first channel 211, the first mover assembly 220 defines a second channel 222 inside, a piston head 130 is disposed in the compression cavity 120 and filled with a first working medium, and the first working medium is compressed or expanded when the piston head 130 is driven by the second mover assembly 230 to reciprocate in the compression cavity 120 along the rich-end axis of the compression cavity 120. The first working medium can generate heat under the condition of being compressed.

Optionally, the dual-mover linear compression device 200 includes a second housing 210 having a first passage 211 disposed therein coaxially with the compression chamber 120. The first mover assembly 220 defines an expansion chamber 221 with the first housing 110, and is capable of reciprocating along an axial direction of the expansion chamber 221, that is, the first mover assembly 220 is capable of moving toward the first housing 110 along an axial direction of the first passage 211 under a driving force to compress the first working substance.

Optionally, the second mover assembly 230 is disposed inside the first mover assembly 220, and has one end fixedly connected to the first mover assembly 220 and the other end connected to the piston head 130 through a connecting rod. Under the action of the driving force, the second mover assembly 230 can move in the second channel 222 toward the first housing 110 to synchronously drive the piston head 130 to move in the compression cavity 120, so that the first working medium in the compression cavity 120 can be compressed to generate work capacity.

Alternatively, by controlling the difference between the driving forces of the first mover assembly 220 and the second mover assembly 230, the motion phase of the second mover assembly 230 can be controlled to lag behind the motion phase of the first mover assembly 220, that is, the motion phase of the piston head 130 can be controlled to lag behind the motion phase of the first mover assembly 220, so that the motion phase of the first working medium in the compression cavity 120 can lag behind the motion phase of the first working medium in the expansion cavity 221, thereby improving the refrigeration performance of the stirling refrigerator. In addition, the use of the dual-stator linear compression device 200 also reduces noise and vibration of the stirling cooler.

Optionally, the first working fluid is helium.

With the stirling cryocooler provided by the embodiment of the present disclosure, the first mover assembly 220 and the first housing 110 define an expansion cavity 221, which moves along the axial direction of the expansion cavity 221 toward the first housing 110 under the action of a driving force to compress a first working medium, so as to realize the active motion of the first mover assembly 220, and the second mover assembly 230 moves in the compression cavity 120 toward the first housing 110 under the action of the driving force to synchronously drive the piston head 130 to move in the compression cavity 120, so as to compress the first working medium, so as to realize the active motion of the piston head 130; by controlling the difference of the driving force of the first mover assembly 220 and the second mover assembly 230, the movement phase of the first mover assembly 220 and the movement phase of the piston head 130 can be different, and compared with the existing stirling refrigerator, the refrigerating efficiency of the refrigerator is improved while noise and vibration are reduced.

In some embodiments, the dual-stator linear compression device 200 further includes a stator assembly 240. The stator assembly 240 is fixedly disposed on the second housing 210, forms a gap seal with the first mover assembly 220, and is configured to drive the first mover assembly 220 to reciprocate along an axial direction of the expansion chamber 221.

The stator assembly 240 is fixedly disposed on the second housing 210, and can drive the first mover assembly 220 to reciprocate along the axial direction of the expansion chamber 221, and a gap is formed between the stator assembly 240 and the first mover assembly 220, so that the first mover assembly 220 can reciprocate more stably.

In some embodiments, the stator assembly 240 includes a stator backbone 241 and stator magnetic induction coils. And a stator frame 241 configured as a cylindrical structure. The stator magnetic induction coil is provided inside the tubular structure of the stator frame 241. The first mover assembly 220 includes a magnetic member that interacts with the stator magnetic induction coil.

After the stator magnetic induction coil is energized with current, an alternating current is generated, and then an alternating magnetic field is generated, so that a magnetic loop is formed in the stator assembly 240. Stator module 41 sets up in the outside of first active cell subassembly 220, and first active cell subassembly 220 is equipped with magnetic part, and when the magnetic circuit attracted magnetic part, drive first active cell subassembly 220 and remove to the direction of being close to first casing 110, and magnetic part can cut the magnetic circuit, and when the magnetic circuit rejected magnetic part, drive first active cell subassembly 220 and remove to the direction of keeping away from first casing 110. Through the arrangement of the stator magnetic induction coil and the magnetic member, the first mover assembly 220 can be driven to linearly reciprocate in the expansion chamber 221.

In some embodiments, the first mover assembly 220 includes a permanent magnet 223 and a first resonant spring 224. And a permanent magnet 223 which is hollow inside to form a second passage 222, the second passage 222 being coaxially disposed with the first passage 211 and configured to move in an axial direction of the expansion chamber 221 by being driven by the stator assembly 240. One end of the first resonant spring 224 is fixedly connected to the second housing 210, and the other end thereof is fixedly connected to the permanent magnet 223.

The first mover assembly 220 includes a permanent magnet 223 having a second passage 222 formed hollow therein. The permanent magnet 223 may serve as a magnetic member that interacts with the stator magnetic induction coil, facilitating the stator assembly 240 to drive the first mover assembly 220. The permanent magnet 223 is hollow inside with a second passage 222. Optionally, second passage 222 is coaxially disposed with compression chamber 120. In this way, the coaxiality of the first mover assembly 220, the second mover assembly 230, and the piston head 130 can be improved.

Alternatively, one end of the first resonant spring 224 is fixedly connected to the second housing 210, and the other end is fixedly connected to the permanent magnet 223. Thus, on one hand, the first resonant spring 224 can generate a certain supporting effect on the hollow permanent magnet, so that the permanent magnet is kept stable; on the other hand, when the first mover assembly 220 is driven by the stator assembly 240 to reciprocate, radial shaking of the first mover assembly 220 in the first passage 211 is reduced by the first resonant spring 224, thereby preventing radial displacement of the first mover assembly 220 in the first passage 211 and ensuring gap sealing between the first mover assembly 220 and the stator assembly 240.

In some embodiments, the second mover assembly 230 includes a mover bobbin 231, a mover magnetic induction coil, and a second resonant spring 233. The mover bobbin 231, disposed within the second channel 222, is constructed in a cylindrical structure in which the connection rod 140 penetrates the permanent magnet 223 to connect the mover bobbin 231 and the piston head 130. And a mover magnetic induction coil provided inside the tubular structure of the mover frame 231 and electrically connected to an external driving module. One end of the second resonant spring 233 is fixedly connected to the permanent magnet 223, and the other end is fixedly connected to the mover frame 231.

The second mover assembly 230 includes a mover frame 231 having a cylindrical structure and a mover magnetic induction coil provided inside thereof. The rotor magnetic induction coil is electrically connected with an external driving module. Therefore, when the external driving module is introduced with the alternating current, the alternating current can be generated, and then an alternating magnetic field is generated to form a magnetic loop. The mover frame 231 is disposed outside the mover magnetic induction coil and can cut a magnetic loop, so that the second mover assembly 230 makes a linear reciprocating motion in the second channel 222 relative to the first mover assembly, and further drives the compression head 130 to make a linear reciprocating motion in the compression cavity 120, so that the first working medium in the compression cavity is expanded or compressed.

Alternatively, one end of the second resonant spring 233 is fixedly connected to the permanent magnet 223, and the other end is fixedly connected to the mover frame 231. In this way, on the one hand, the second resonant spring 233 can generate a certain supporting effect on the mover frame 231 having the cylindrical structure, so that the mover frame 231 can be kept stable; on the other hand, when the second mover assembly 220 reciprocates, the radial shaking of the second mover assembly 230 in the second channel 222 is reduced by the second resonant spring 233, and thus the radial displacement of the second mover assembly 230 in the second channel 222 is reduced.

In some embodiments, the first resonant spring 224 is a plate spring or a flexible spring. Optionally, the first resonant spring 224 is a plate spring. In this way, an axially elastic support of the first mover assembly 220 may be ensured.

Alternatively, for the motion of first and second mover assemblies 220 and 230, the motion phase thereof conforms to the following equation:

wherein x is the displacement of the rotor, alpha is the specific thrust coefficient of the motor, I is the current, I is the imaginary unit, Z_mIs mechanical impedance, A is the cross-sectional area of the mover, Z_aIs the gas impedance, Z, to the mover front face_bIs the gas impedance of the back of the mover. In actual use, the displacements of the first rotor assembly 220 and the second rotor assembly 230 can be calculated according to actual mechanical impedance and gas impedance, the second rotor can move just behind the 90-degree phase of the first rotor through calculation adjustment, the relationship that the motion phase of the first working medium in the compression cavity 120 lags behind the motion phase of the first working medium in the expansion cavity 221 by 90 degrees is met, and the overall efficiency of the Stirling refrigerating machine is improved.

In some embodiments, the stirling cooler cold head apparatus 100 further comprises a hot side heat exchanger 150, a regenerator 160 and a cold side heat exchanger 170 connected in series. Wherein, the hot side heat exchanger 150 is disposed in the compression chamber 120 and away from one end of the second shell 210.

Optionally, the first working medium is compressed by the piston head 130 in the compression chamber 120 to generate heat, and then is pushed into the hot-end heat exchanger 150, and after a heat release process, is pushed into the heat regenerator 160 to continue cooling, and then is pushed into the cold-end heat exchanger 170 to transfer the cold energy contained therein to an external place requiring cold energy, so as to achieve the purpose of refrigeration.

In some embodiments, hot side heat exchanger 150 is a shell and tube heat exchanger having a fluid channel for a second working medium therein, the second working medium being capable of exchanging heat with the first working medium.

Optionally, a fluid channel is disposed in the hot side heat exchanger 150, and a second working medium flows in the fluid channel. The first working medium is pushed into the hot side heat exchanger 150 after the compression chamber 120 is compressed by the piston head 130 to generate heat, and the heat is transferred to the second working medium in the hot side heat exchanger 150. Preferably, the second working medium is water, and the water flows in the fluid channel to take away the heat of the first working medium. The first working medium exchanges heat with the second working medium and then is pushed into the heat regenerator 160, and the temperature of the first working medium is continuously reduced in the heat regenerator 160. And then pushed into the cold-end heat exchanger 170 to transfer the cold energy therein to the external place needing the cold energy, thereby achieving the purpose of refrigeration. Optionally, the cold end heat exchanger 170 is provided with a cold end head for transferring cold to the outside.

In some embodiments, regenerator 160 is filled with a porous medium, which is a stainless steel mesh, stainless steel fibers, or lead shot.

Fig. 3 is an enlarged schematic view of a portion B of fig. 1 according to an embodiment of the disclosure.

Referring to fig. 1 and 3, in some embodiments, the stirling cooler cold head apparatus 100 further comprises a third housing 180. The third casing 180 is sleeved outside the first casing 110, and defines a third channel 190 together with the first casing 110, wherein the third channel 190 is communicated with the expansion cavity 221. Therefore, after cold energy is discharged from the cold-end heat exchanger, the first working medium can flow back to the expansion cavity 221 through the third channel 190, so as to work in a reciprocating cycle mode.

In the embodiment of the present disclosure, the first working medium in the expansion cavity 221 moves along with the alternating motion of the first mover assembly 220, and the first working medium in the compression cavity 120 can move along with the alternating motion of the second mover assembly 230, and by controlling the difference between the magnitude of the driving force of the first mover assembly 220 and the magnitude of the driving force of the second mover assembly 230, the movement of the second mover assembly 230 lags behind the first mover assembly 220, and further the movement phase of the first working medium in the compression cavity 120 lags behind the movement phase of the first working medium in the expansion cavity 221, so as to improve the refrigeration performance of the stirling refrigerator.

The above description and drawings sufficiently illustrate embodiments of the disclosure to enable those skilled in the art to practice them. Other embodiments may include structural and other changes. The examples merely typify possible variations. Individual components and functions are optional unless explicitly required, and the sequence of operations may vary. Portions and features of some embodiments may be included in or substituted for those of others. The embodiments of the present disclosure are not limited to the structures that have been described above and shown in the drawings, and various modifications and changes may be made without departing from the scope thereof. The scope of the present disclosure is limited only by the appended claims.

Claims (10)

1. A Stirling cryocooler, includes Stirling cryocooler cold head device (100), and it includes that inside cavity is formed with first casing (110) of compression chamber (120), be equipped with piston head (130) in compression chamber (120), characterized by, Stirling cryocooler still includes dual-mover linear compression device (200) that is used for compressing first working medium, dual-mover linear compression device (200) includes:

the second shell (210) is fixedly connected with the first shell (110), and a first channel (211) which is coaxial with the compression cavity (120) is arranged in the second shell;

a first mover assembly (220) disposed in the first passage (211) and defining an expansion chamber (221) with the first housing (110), and configured to move in a direction toward the first housing (110) along an axial direction of the expansion chamber (221) by a driving force;

the second rotor assembly (230) is arranged inside the first rotor assembly (220), one end of the second rotor assembly is fixedly connected with the first rotor assembly (220), the other end of the second rotor assembly is connected with the piston head (130) through a connecting rod (140), and the second rotor assembly is configured to synchronously drive the piston head (130) to move in the compression cavity (120) towards the direction of the first shell (110) inside the first rotor assembly (220) under the action of driving force so as to compress the first working medium.

2. A stirling cooler according to claim 1, wherein the dual mover linear compression device (200) further comprises:

and the stator assembly (240) is fixedly arranged on the second shell (210), forms a gap seal with the first rotor assembly (220), and is configured to drive the first rotor assembly (220) to reciprocate along the axial direction of the expansion cavity (221).

3. A stirling cooler according to claim 2, wherein the stator assembly (240) comprises:

a stator frame (241) configured as a cylindrical structure;

a stator magnetic induction coil disposed inside the stator frame (241);

the first rotor assembly (220) is provided with a magnetic part which interacts with the stator magnetic induction coil.

4. A stirling cooler according to claim 3, wherein the first mover assembly (220) comprises:

a permanent magnet (223) having a second channel (222) formed in the hollow interior thereof and configured to move in the axial direction of the expansion chamber (221) under the driving of the stator assembly (240);

and one end of the first resonance spring (224) is fixedly connected with the second shell (210), and the other end of the first resonance spring is fixedly connected with the permanent magnet (223).

5. A Stirling cooler according to claim 4, wherein the second mover assembly (230) comprises:

a mover frame (231) disposed within the second channel (222), configured as a cylindrical structure, wherein the connecting rod (140) penetrates the permanent magnet (223) to connect the mover frame (231) and the piston head (130);

the mover magnetic induction coil is arranged inside the mover framework (231) and is electrically connected with an external driving module;

and one end of the second resonance spring (233) is fixedly connected with the permanent magnet (223), and the other end of the second resonance spring is fixedly connected with the rotor framework (231).

6. A Stirling cooler according to claim 4,

the first resonant spring (224) is a plate spring or a flexible spring.

7. A stirling cooler according to claim 1, wherein the stirling cooler cold head arrangement (100) further comprises a hot end heat exchanger (150), a regenerator (160) and a cold end heat exchanger (170) connected in series, wherein the hot end heat exchanger (150) is disposed within the compression chamber (120) at an end remote from the second housing (210).

8. A Stirling cooler according to claim 7,

the hot end heat exchanger (150) is a shell-and-tube heat exchanger, a fluid channel of a second working medium is arranged in the hot end heat exchanger, and the second working medium can exchange heat with the first working medium.

9. A Stirling refrigerator according to claim 7,

porous media are filled in the heat regenerator (160), and the porous media are stainless steel wire meshes, stainless steel fibers and lead shots.

10. A Stirling cooler according to claim 7, wherein the Stirling cooler cold head arrangement (100) further comprises:

and the third shell (180) is sleeved outside the first shell (110) and defines a third channel (190) together with the first shell (110), wherein the third channel (190) is communicated with the expansion cavity (221).

Images