CN212320122U

CN212320122U - Novel pulse tube refrigerator

Info

Publication number: CN212320122U
Application number: CN202021965679.5U
Authority: CN
Inventors: 付柏山
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-09-10
Filing date: 2020-09-10
Publication date: 2021-01-08
Anticipated expiration: 2030-09-10

Abstract

The utility model discloses a novel pulse tube refrigerator, which comprises a cold head body and an air inlet pipe, wherein the air inlet pipe is arranged on the side wall of the cold head body, a primary refrigerating system is arranged at the bottom of the cold head body, a spiral pipeline and an expansion cavity are arranged in the cold head body, two ends of the spiral pipeline are respectively communicated with the upper ends of the air inlet pipe and the expansion cavity, and the bottom of the expansion cavity is communicated with the primary refrigerating system; a secondary refrigeration system is also included. The spiral pipeline is arranged between the air inlet pipe and the expansion cavity, and through the transition of the spiral pipeline, the high-pressure helium directly and suddenly enters the expansion cavity from the air inlet pipe to cause vortex loss and total pressure loss, so that the flow of the high-pressure helium in the spiral pipe is close to adiabatic isentropic flow, the flow loss is small, the energy of a high-pressure air source is utilized to the maximum extent, and the refrigeration efficiency is improved; the primary refrigeration system and the secondary refrigeration system are arranged, so that graded refrigeration is realized, and the refrigeration effect is improved.

Description

Novel pulse tube refrigerator

Technical Field

The utility model relates to a refrigerator technical field specifically is a novel pulse tube refrigerator.

Background

The new pulse tube refrigerator uses high pressure gas to be insulated and pumped out to achieve the purpose of refrigeration. After high-pressure helium enters a cold head body, the high-pressure helium directly and suddenly enters a large expansion cavity through an air inlet pipe, so that great eddy current loss and total pressure loss are caused, and the volume and space of the expansion cavity at the upper part of the whole cold head body are limited, so that the refrigeration efficiency is influenced; and the flow layout of linear gradual transition cannot be directly adopted due to the restriction of the space size of the existing cold head, and a great deal of inconvenience exists in the use process.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a novel pulse tube refrigerator to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme:

a novel pulse tube refrigerator comprises a cold head body and an air inlet pipe, wherein the air inlet pipe is arranged on the side wall of the cold head body, a primary refrigerating system is arranged at the bottom of the cold head body and comprises a primary heat storage pipe, a primary heat exchanger, a primary cold disc and a primary pulse tube, the primary heat storage pipe is sleeved at the bottom of the primary heat storage pipe, the primary cold disc is arranged at the bottom of the primary heat exchanger, the primary pulse tube is communicated with the primary cold disc, and a primary air reservoir joint communicated with the primary pulse tube is arranged at the top end of the cold head body; the cold head is internally provided with a spiral pipeline and an expansion cavity, two ends of the spiral pipeline are respectively communicated with the air inlet pipe and the upper end of the expansion cavity, and the bottom of the expansion cavity is communicated with a primary heat storage pipe.

As a further aspect of the present invention: still include second grade refrigerating system, second grade refrigerating system includes second grade heat accumulation pipe, secondary heat exchanger, second grade cold dish and second grade pulse pipe, second grade heat accumulation pipe is connected with the one-level cold dish, second grade heat accumulation socle portion cover is equipped with the secondary heat exchanger, the second grade heat exchanger bottom is equipped with the second grade cold dish, the intercommunication has the second grade pulse pipe on the second grade cold dish, cold head body top is equipped with the second grade gas storehouse joint with second grade pulse pipe intercommunication.

As a further aspect of the present invention: and a bidirectional branched channel is arranged in the primary cooling disc, and two ends of an outlet of the bidirectional branched channel are respectively communicated with the primary pulse tube and the secondary heat storage tube.

As a further aspect of the present invention: and a cold head cover is arranged at the upper end of the cold head body.

As a further aspect of the present invention: the primary heat exchanger and the secondary heat exchanger are made of oxygen-free copper plates.

As a further aspect of the present invention: the first-stage heat exchanger and the second-stage heat exchanger are formed by rolling and soft soldering oxygen-free copper plates.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the spiral pipeline is arranged between the air inlet pipe and the expansion cavity, and through the transition of the spiral pipeline, the high-pressure helium directly and suddenly enters the expansion cavity from the air inlet pipe to cause vortex loss and total pressure loss, so that the flow of the high-pressure helium in the spiral pipe is close to adiabatic isentropic flow, the flow loss is small, the energy of a high-pressure air source is utilized to the maximum extent, and the refrigeration efficiency is improved;

2. the device is provided with a primary refrigeration system and a secondary refrigeration system to realize graded refrigeration, helium can reach 40K temperature and corresponding refrigeration capacity on a primary cold plate through expansion cooling, and then 4K temperature and required refrigeration capacity on a secondary cold plate are realized;

3. the primary heat exchanger and the secondary heat exchanger are formed by rolling and soft soldering oxygen-free copper plates, so that the heat exchange area is increased, the heat exchange and conduction performances are good, the rapid heat conduction can be realized, the refrigeration effect is improved, and the manufacture and the processing are convenient;

4. because the pulse tube is not internally provided with a reciprocating component, the fluctuation and pulsation influence of the airflow is small, so that the vibration and interference amplitude is reduced, and the precision of a related precision measurement experiment with a magnetic field is improved.

Drawings

Fig. 1 is an external view of a novel pulse tube refrigerator;

fig. 2 is an internal view of the novel pulse tube refrigerator.

In the figure: 1. a cold head body; 2. an air inlet pipe; 3. a primary heat storage pipe; 4. a primary heat exchanger; 5. a primary cold plate; 6. a primary pulse tube; 7. a primary gas reservoir joint; 8. a coiled pipe; 9. an expansion chamber; 10. a secondary heat storage tube; 11. a secondary heat exchanger; 12. a secondary cooling plate; 13. a secondary pulse tube; 14. a secondary gas reservoir joint; 15. and (5) a cold head cover.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that, if there is a directional indication (such as up, down, left, right, front, and back) in the embodiment of the present invention, it is only used to explain the relative position relationship between the components, the motion situation, etc. in a certain specific posture, and if the specific posture is changed, the directional indication is changed accordingly.

In addition, if a description of "first", "second", etc. is referred to in the present invention, it is used for descriptive purposes only and not to be construed as indicating or implying relative importance or implicit to the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

Example 1

Referring to fig. 1-2, a novel pulse tube refrigerator comprises a cold head body 1 and an air inlet tube 2, wherein the air inlet tube 2 is arranged on the side wall of the cold head body 1, a primary refrigerating system is arranged at the bottom of the cold head body 1, the primary refrigerating system comprises a primary heat storage tube 3, a primary heat exchanger 4, a primary cold plate 5 and a primary pulse tube 6, the primary heat storage tube 3 is sleeved at the bottom of the primary heat storage tube 3, the primary heat exchanger 4 is arranged at the bottom of the primary heat exchanger 4, the primary cold plate 5 is communicated with the primary pulse tube 6, and a primary air reservoir joint 7 communicated with the primary pulse tube 6 is arranged at the top end of the cold head body 1; a spiral pipeline 8 and an expansion cavity 9 are arranged in the cold head body 1, two ends of the spiral pipeline 8 are respectively communicated with the upper ends of the air inlet pipe 2 and the expansion cavity 9, and the bottom of the expansion cavity 9 is communicated with the primary heat storage pipe 3;

high-pressure helium gas compressed by the compressor enters a spiral pipeline 8 in the cold head body 1 through the air inlet pipe 2, then flows into an expansion cavity 9, then flows into the first-stage heat storage pipe 3, then enters the first-stage heat exchanger 4, and flows into the first-stage cold plate 5 through the first-stage heat exchanger 4;

the spiral pipeline 8 in the cold head body 1 can reduce the total pressure loss caused by the high-pressure helium gas entering the pipeline, so that the high-pressure helium gas is gradually transited into the expansion cavity 9 through the spiral pipeline 8, thereby solving the problem that the high-pressure helium gas directly and suddenly enters the large expansion cavity 9 from the air inlet pipe 2 to cause great eddy loss and total pressure loss, leading the flow of the high-pressure helium gas in the spiral pipeline 8 to be close to adiabatic isentropic flow, having small flow loss, and being capable of utilizing the energy of a high-pressure gas source to the maximum extent, thereby improving the refrigeration efficiency;

the novel pulse tube refrigerator further comprises a secondary refrigerating system, wherein the secondary refrigerating system comprises a secondary heat storage tube 10, a secondary heat exchanger 11, a secondary cold plate 12 and a secondary pulse tube 13, the secondary heat storage tube 10 is connected with a primary cold plate 5, the bottom of the secondary heat storage tube 10 is sleeved with the secondary heat exchanger 11, the bottom of the secondary heat exchanger 11 is provided with the secondary cold plate 12, the secondary cold plate 12 is communicated with the secondary pulse tube 13, and the top end of the cold head body 1 is provided with a secondary air reservoir joint 14 communicated with the secondary pulse tube 13;

a bidirectional branched channel is arranged in the primary cooling disc 5, and two ends of an outlet of the bidirectional branched channel are respectively communicated with the primary pulse tube 6 and the secondary heat storage tube 10;

the high-pressure helium which is led to the primary pulse tube 6 through the bidirectional branched channel flows into the primary gas reservoir from a primary gas reservoir joint 7 at the other end of the primary pulse tube 6;

the high-pressure helium gas led into the secondary heat storage tube 10 through the bidirectional branched channel continuously flows into the secondary heat exchanger 11, then flows into the secondary pulse tube 13 through the secondary cooling disc 12, and finally enters the diode gas reservoir at the secondary gas reservoir joint 14 at the other end of the secondary pulse tube 13;

in order to further improve the heat exchange performance and the refrigeration effect of the primary heat exchanger 4 and the secondary heat exchanger 11, the primary heat exchanger 4 and the secondary heat exchanger 11 are made of oxygen-free copper plates, so that the heat exchange performance and the conduction performance are good, the rapid heat conduction can be realized, and the refrigeration effect is improved;

the specific manufacturing method of the primary heat exchanger 4 and the secondary heat exchanger 11 is not limited, and in this embodiment, preferably, the primary heat exchanger 4 and the secondary heat exchanger 11 are formed by rolling and soft soldering oxygen-free copper plates, so that the heat exchange area is increased, and the manufacturing and the processing are convenient;

in order to ensure the sealing performance of the inner cavity of the cold head body 1 and avoid helium leakage of the cold head body 1, the upper end of the cold head body 1 is provided with a cold head cover 15.

The working principle of the embodiment is as follows:

high-pressure helium gas compressed by the compressor enters a spiral pipeline 8 in the cold head body 1 through the air inlet pipe 2, then flows into an expansion cavity 9, then flows into the first-stage heat storage pipe 3, then enters the first-stage heat exchanger 4, and flows into the first-stage cold plate 5 through the first-stage heat exchanger 4; the high-pressure helium which is led to the primary pulse tube 6 through the bidirectional branched channel flows into the primary gas reservoir from a primary gas reservoir joint 7 at the other end of the primary pulse tube 6; the high-pressure helium gas led into the secondary heat storage tube 10 through the bidirectional branched channel continuously flows into the secondary heat exchanger 11, then flows into the secondary pulse tube 13 through the secondary cooling disc 12, and finally enters the diode gas reservoir at the secondary gas reservoir joint 14 at the other end of the secondary pulse tube 13.

According to the novel pulse tube refrigerator, the spiral pipeline 8 is arranged between the air inlet pipe 2 and the expansion cavity 9, and through transition of the spiral pipeline 8, vortex loss and total pressure loss caused by the fact that high-pressure helium directly and suddenly enters the expansion cavity 9 from the air inlet pipe 2 are avoided, so that the flow of the high-pressure helium in the spiral pipeline 8 is close to adiabatic isentropic flow, the flow loss is small, the energy of a high-pressure air source is utilized to the maximum extent, and the refrigeration efficiency is improved; a primary refrigeration system and a secondary refrigeration system are arranged to realize graded refrigeration, helium is expanded and cooled to reach 40K temperature and corresponding refrigeration capacity on a primary cold plate 5, and then 4K temperature and required refrigeration capacity are realized on a secondary cold plate 12; the primary heat exchanger 4 and the secondary heat exchanger 11 are formed by rolling and soft soldering oxygen-free copper plates, so that the heat exchange area is increased, the heat exchange and conduction performances are good, the rapid heat conduction can be realized, the refrigeration effect is improved, and the manufacture and the processing are convenient; because the pulse tube is not internally provided with a reciprocating component, the fluctuation and pulsation influence of the airflow is small, so that the vibration and interference amplitude is reduced, and the precision of a related precision measurement experiment with a magnetic field is improved.

The above description is only an example of the present invention, and the common general knowledge of the known specific structures and characteristics of the embodiments is not described herein. It should be noted that, for those skilled in the art, without departing from the structure of the present invention, several modifications and improvements can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the patent. The scope of the claims of the present application shall be determined by the contents of the claims, and the description of the embodiments and the like in the specification shall be used to explain the contents of the claims.

Claims

1. The novel pulse tube refrigerating machine comprises a cold head body (1) and an air inlet pipe (2), wherein the air inlet pipe (2) is arranged on the side wall of the cold head body (1), a primary refrigerating system is arranged at the bottom of the cold head body (1), the primary refrigerating system comprises a primary heat storage pipe (3), a primary heat exchanger (4), a primary cold plate (5) and a primary pulse tube (6), the primary heat storage pipe (3) is sleeved with the primary heat exchanger (4), the primary cold plate (5) is arranged at the bottom of the primary heat exchanger (4), the primary cold plate (5) is communicated with the primary pulse tube (6), and a primary air reservoir joint (7) communicated with the primary pulse tube (6) is arranged at the top end of the cold head body (1); the heat-accumulating type refrigerating head is characterized in that a spiral pipeline (8) and an expansion cavity (9) are arranged in the refrigerating head body (1), two ends of the spiral pipeline (8) are respectively communicated with the upper ends of the air inlet pipe (2) and the expansion cavity (9), and the bottom of the expansion cavity (9) is communicated with the primary heat-accumulating pipe (3).

2. The novel pulse tube refrigerator according to claim 1, further comprising a secondary refrigeration system, wherein the secondary refrigeration system comprises a secondary heat storage tube (10), a secondary heat exchanger (11), a secondary cooling disc (12) and a secondary pulse tube (13), the secondary heat storage tube (10) is connected with the primary cooling disc (5), the secondary heat exchanger (11) is sleeved at the bottom of the secondary heat storage tube (10), the secondary cooling disc (12) is arranged at the bottom of the secondary heat exchanger (11), the secondary pulse tube (13) is communicated with the secondary cooling disc (12), and a secondary gas storage joint (14) communicated with the secondary pulse tube (13) is arranged at the top end of the cold head body (1).

3. The novel pulse tube refrigerator as claimed in claim 2, wherein a bidirectional branch channel is arranged in the primary cooling plate (5), and two outlet ends of the bidirectional branch channel are respectively communicated with the primary pulse tube (6) and the secondary heat storage tube (10).

4. A novel pulse tube refrigerator according to claim 1, characterized in that the upper end of the cold head body (1) is provided with a cold head cover (15).

5. A novel pulse tube refrigerator according to claim 2 or 3, characterized in that said primary heat exchanger (4) and said secondary heat exchanger (11) are made of oxygen-free copper plates.

6. A novel pulse tube refrigerator according to claim 5, wherein said primary heat exchanger (4) and said secondary heat exchanger (11) are made of oxygen-free copper plates by rolling and soldering.