RU105009U1 - MAGNETIC HEATING MACHINE - Google Patents

Abstract

1. Magnetic heat machine, containing in its working circuit a magnetic working fluid, hot and cold heat exchangers, devices that move and change the direction of the flow of the coolant, and a magnet installed with the ability to move relative to the working fluid for its magnetization / demagnetization, characterized in that the working circuit is made open and contains at least two hot heat exchangers, at least four uncontrolled check valves are used as devices for changing the direction of the coolant flow in the working fluid, and a reversible blower is used as a device for moving the coolant. ! 2. The machine according to claim 1, characterized in that a material with high values of the magnetocaloric effect in the temperature range of 100-350 K is used as a working fluid, for example, transition, rare-earth and other metals and their alloys, oxides, hydrides and other compounds. ! 3. Machine according to claim 1, characterized in that the working fluid is placed in a container containing one or more sections and in the form of a disk, cylinder or parallelepiped.

Description

The utility model relates to refrigeration or thermal technology, namely to magnetic heat engines (refrigerators or heat pumps) using solid-state magnetic material with magnetocaloric effect as a working medium.

The magnetocaloric effect (FEM) is manifested in the reversible absorption or release of heat in a magnetic material when the magnetic field is turned on and off. Magnetization / demagnetization cycles of magnetic material are similar to gas expansion / compression cycles and can be used in magnetic heat engines and in magnetic refrigerators [1].

To implement thermodynamic cycles of heat transfer from the working fluid to the hot and cold heat exchangers of the devices, it is possible to use heat carrier fluids (liquid or gas) after thermal regeneration of the working fluid by them when the magnetic field is turned on and off.

Various methods and devices for the implementation of such magnetic heat engines based on technical thermodynamic cycles such as Stirling, Brighton and other active magnetic regeneration cycles are described in detail in [2-6].

The designs of these devices usually include closed cold and hot circuits with two pumps for moving the coolant and a large number of electrically controlled switches for the direction of flow of the coolant through the working fluid.

A disadvantage of the known magnetic thermal machines is also that at the moments of magnetization and demagnetization of the working fluid, the movement of the coolant stops, which leads to a significant complication of the design.

The closest in technical essence and the achieved effect to the claimed solution is a magnetic heat engine (magnetic refrigerator or heat pump) [2], containing in its working circuit a magnetic working fluid, hot and cold heat exchangers, pumps to create a flow of coolant, valves, direction switches coolant flow, as well as a magnet moving relative to the working fluid for its magnetization / demagnetization, in which changing the direction of flow of coolant in the working fluid provides it is controlled by flow direction switches controlled mechanically or electrically using magnet position sensors, and limit switches, optical, magnetic (Hall sensors, magnetoresistive sensors), piezoelectric, magneto-piezoelectric and other sensors can be used to determine the position of the magnet relative to the working fluid in the machine .

The design of the prototype contains two independent closed circuits with two pumps for moving the coolant, a large number of electrically controlled switches of the flow direction of the coolant, which complicates the design of the machine and reduces its reliability. In the device at the moments of magnetization and demagnetization of the working fluid, the movement of the coolant stops, which reduces its thermodynamic efficiency and specific refrigerating capacity.

The objective of the utility model is to simplify the design of a magnetic heat engine, increase its reliability, thermodynamic efficiency and specific refrigerating capacity.

The problem is solved due to the fact that in a magnetic heat engine containing in its working circuit a magnetic working fluid, hot and cold heat exchangers, devices for moving and changing the direction of flow of the coolant, and a magnet installed with the ability to move relative to the working fluid to magnetize / demagnetization, the circuit is open and contains at least two hot heat exchangers, as devices for changing the direction of flow of the coolant in the At least four uncontrolled check valves were used, and a reversible supercharger was used as a device for moving the coolant.

As the working fluid in the machine, material with high values of the magnetocallor effect in the temperature range of 100 - 350 K can be used, for example, transition, rare-earth and other metals and their alloys, oxides, hydrides and other compounds, and the working fluid itself is placed in a container containing one or more sections and shaped like a disk, cylinder or parallelepiped

The essence of the proposed utility model is illustrated by graphic materials, where

figure 1 shows a General view of the machine in the first stage of the cycle;

figure 2. shows a general view of the machine in the second stage of the cycle.

Magnetic heat engine, contains (Fig.1. And Fig.2.): 1 - cold heat exchanger - a refrigerating chamber; 2, 3 - containers containing a magnetic working fluid; 4 - a magnet moving relative to the working fluid for its magnetization / demagnetization; 5, 6, 7, 8 - check valves; 9, 10 - hot heat exchangers - radiators; 11 - reversible supercharger.

The flow direction of the coolant is shown by arrows.

The coil of the refrigerating chamber 1 and the radiators 9, 10 are made of a material having high thermal conductivity, for example, copper or aluminum alloy. Containers 2, 3 containing the working fluid are made of non-magnetic material, for example, caprolon, in the form of disk sectors. The permanent magnet 4 can perform a reverse rotational or reciprocating motion relative to the working fluid.

The working circuit is filled with coolant, which can be used, depending on the operating temperature range, liquids or gases. In particular, water, an aqueous solution of alcohol, etc. can be used in the region of room temperatures, and gaseous helium in the temperature range of about 20 K.

The material of the working fluid can be used in a form that ensures the passage of the flow of coolant, for example: a set of plates and balls, dispersed powder, bulk material with channels and holes and other types.

The working cycle of the device consists of two stages, in each of which the magnetization or demagnetization of the working fluid and the flow of coolant through it are simultaneously carried out.

Magnetic heat engine operates as follows.

At the first stage of the cycle, the piston of the supercharger 11 moves to the right (Fig. 1), squeezing the coolant through the check valve 6, the working fluid in the container 3, the coil of the refrigerating chamber 1, the working fluid in the container 2, the check valve 7 and the radiator 9 into the released volume of the supercharger 11 In this case, the front of the permanent magnet 4 heats the working fluid in the container 2, and the slice of the magnet 4 cools the working fluid in the container 3. The coolant heated by the working fluid in the container 2 enters the radiator 9 through valve 7, and the coolant cooled by the working fluid in the circuit biner 3, accumulates in the coil of the refrigerator 1, taking some heat ΔQ ₁ from it. In figure 1. shows the location of the parts of the machine at the time preceding the completion of the first stage of the cycle.

After completion of the first stage of the cycle, the movements of the supercharger 11 and magnet 4 are reversed and the second stage of the cycle begins, similar to the first, but in the opposite direction. In figure 2. shows the position of magnet 4, and the direction of coolant flows for a point in time preceding the completion of the second stage of the cycle. At this point, the coolant heated by the working fluid in the container 3 has been squeezed into the radiator 10 and gives it the heat received from the working fluid. It is assumed that the coolant takes away from the working fluid all the allocated amount of heat. Cooled coolant entered the container 3 with the working fluid from the coil of the refrigerating chamber 1, which lowered the temperature of the working fluid in the container 3 below the initial one, taking the amount of heat ΔQ ₃ from it. Obviously, ΔQ ₃ <ΔQ ₁ . During the time of this stage of the cycle, the coolant cooled to the initial temperature entered the working fluid in the container 2 from the opposite output of the radiator 9. At the same time, the coolant cooled by the working fluid in the container 2 entered the coil of the refrigerating chamber 1, additionally taking some heat from it, slightly less than ΔQ ₁ . As a result, an additional decrease in the temperature of the coil of the refrigerating chamber 1 will occur. In the next cycle, this volume of the coolant is returned to the container 2 with the working fluid, taking heat from it, ΔQ ₂ ≈ΔQ ₃ and lowering its temperature below the original one. In the second stage of the current cycle, the temperature of the working fluid in the container 3 will also decrease and a further decrease in the temperature of the refrigerating chamber 1 will occur.

The described process of heat transfer from the refrigerator to the radiators will continue until the amount of heat ΔQ ₁ is equal to the heat brought into the system by spurious heat inflows. The decrease in ΔQ ₁ is due to the fact that the magnitude of the magnetocaloric effect decreases with the temperature of the working fluid outside the temperature range of the magnetic phase transition. To prevent a decrease in ΔQ _1, it is advisable to compose a working fluid from several alloys with FEM maxima in different temperature ranges. In this case, bodies with low temperature ranges should be located closer to the outlet of the container, connected to the refrigerating chamber 1.

The proposed model of an open-loop magnetic heat engine with two hot heat exchangers and a reversible supercharger instead of a liquid pump and uncontrolled non-return valves made it possible to significantly simplify the design of the magnetic heat engine, increase its reliability, thermodynamic efficiency, and specific refrigerating capacity.

Information sources.

1. Belov K.P. Magnetothermal phenomena in rare-earth magnets, Moscow: Nauka, 1990, 96 pp.

2. Patent of Russia №2252375, IPC F25B 21/00, published on 05/20/2005

3. US patents US 3413814, US 4107935, US 4408463, US 4507928, US 5934078, US 6526759

4. French Patent FR 2580385

5. C. Vasile, C. Muller. Innovative design of a magnetocaloric system. International Journal of Refrigeration 29 (2006) 1318-1326.

6. K.A. G.schneidner, Jr., V.K. Pecharsky. Thirty years of near room temperature magnetic cooling: Where we are today and future prospects. International Journal of Refrigeration 31 (2008) 945-961.

Claims (3)

1. Magnetic heat engine, containing in its working circuit a magnetic working fluid, hot and cold heat exchangers, devices for moving and changing the direction of flow of the coolant, and a magnet mounted to move relative to the working fluid to magnetize / demagnetize, characterized in that the working circuit is made open and contains at least two hot heat exchangers, used as devices for changing the direction of flow of the coolant in the working fluid, at least four uncontrolled non-return valves, and a reversing supercharger is used as a coolant transfer device. 2. The machine according to claim 1, characterized in that the material with high values of the magnetocaloric effect in the temperature range of 100-350 K, for example, transition, rare earth and other metals and their alloys, oxides, hydrides and other compounds, is used as a working fluid. 3. The machine according to claim 1, characterized in that the working fluid is placed in a container containing one or more sections and having the form of a disk, cylinder or parallelepiped.