DE102009023977A1 - Stirling cooler - Google Patents

Abstract

A Stirling cooling device is specified with a drive device (2) which has a housing (47-49) and at least one piston (5, 6) driven by a linear motor (8, 9) along a piston axis (7) in a cylinder ( 29), and a displacer unit, which is connected to the drive device (2) via a gas-conducting connection (24) and has at least one displacer which is movable in a Verdrängergehäuse along a Verdrängerachse, wherein the linear motor (8, 9) with a the armature (10, 11) connected to the piston (5, 6), which is arranged between an inner stator (31) and an outer stator (32), and a coil arrangement (35, 35 ').
One would like to be able to achieve a good efficiency.
For this purpose, it is provided that the coil arrangement (35, 35 ') is arranged in the radial direction within the armature (10, 11).

Description

The The invention relates to a Stirling cooling device with a Drive device comprising a housing and at least one piston driven by a linear motor along a piston axis in a cylinder, and a displacer unit, the with the drive device via a gas leading Connection is connected and at least one displacer having, in a Verdrängergehäuse along a displacer axis is movable, wherein the linear motor an armature connected to the piston, between an inner stator and an external stator, and a coil assembly having.

Such a Stirling cooling device is made, for example EP 1 348 918 A1 known.

A Cooling device that works according to the Stirling principle, has a relatively good ratio of achievable cooling capacity and mass. It is therefore well suited for the type of mobile applications.

There one in mobile applications, such as a cooling device for a portable cooler, but also the energy supply to move with, one is particularly dependent on that the cooling device has a good efficiency. The good efficiency is of course also for stationary Applications a goal.

Of the Invention is based on the object of good efficiency achieve.

These Task is at a Stirling cooling device of the beginning mentioned type solved in that the coil assembly is arranged in the radial direction within the armature.

The Arrangement of the coil arrangement in the radial direction within the armature As a result, you have the length of the ladder through which the current within the coil assembly flows, shorter can hold. This has two advantages. For one thing needed less copper, so you can save mass. On the other hand you have at the same current intensity, lower ohmic losses. Within the anchor has enough space, so that the coil arrangement with a relatively large Conductor cross-section can form, so that the current with sufficient Amperage can be sent through. The electricity is generated So a magnetic field that provides the necessary forces for can generate the movement of the piston. The anchor, usually is provided with permanent magnets, lies on a relatively large Radius, so that one can generate relatively much force.

Preferably the coil assembly is received in the inner stator. The coil arrangement becomes So mechanically held by the inner stator. This one achieves one good coupling of the magnetic field generated by the coil assembly to the inner stator and thus a good efficiency.

Preferably The inner stator is composed of two parts that go along the piston axis are arranged one behind the other. This facilitates the Production. It is easily possible, the coil assembly to integrate into the inner stator. For this only needs at least one of the two parts that make up the inner stator, have a recess in which arranged the coil assembly can be. The other part then acts as a kind of cover. Of course it is also possible to provide both parts with recesses, which then together form a cavity in which the coil assembly can accommodate.

in this connection It is preferred that the two parts are identical. This facilitates the production. You have to use the two parts then only in the opposite direction to the necessary To provide recess for the coil assembly. In certain circumstances It may be necessary to have the two parts around the piston axis still to twist 180 ° to each other, for example, then if the two parts openings for carrying having electrical connections.

Preferably is the inner stator and / or the outer stator as a sintered element educated. A sintered part is relatively expensive to produce. By the use of a sintered or sintered element results but a good space utilization and a good magnetic flux. It is also in the shape of the sintered parts or sintered elements free, so that you can almost any shapes within certain limits can realize.

preferably, the inner stator and the housing are connected by a joining element arrangement, having at least one forming zone. The joining element arrangement may have as a joining element, for example, a rivet, in which the forming zone is then formed by a closing head becomes. The joining element arrangement can also by a pin be formed, which is provided at one end with a head. On This pin can then pressed at the other end a ring element become. When you make the connection by reshaping a joining element reach, then it is enough to make the connection, exert an axial force on the joining element arrangement. This can be done in a simple press. Complicated movements for establishing the connection between housing and inner stator are not required.

Preferably the joining element is designed as an electrical conductor, which is connected to the coil assembly. The joining element then fulfills a second task, namely the Conduction of electrical current to the coil arrangement. When the joining element has been passed through the housing, then the electric current can be supplied from the outside become.

alternative or additionally, it may be provided that the joining element arrangement a joining element which is connected to the inside of the housing is. This avoids an opening of the housing, which is particularly advantageous if the recorded in the interior of the cooling device Gas is already biased to a certain pressure and / or this Gas has relatively small molecules, such as Helium. In this case it is beneficial to have all the unnecessary openings in the case can avoid.

Preferably is the outer stator by a radially resilient element axially fixed in the housing. A radially resilient element can be formed for example by a snap ring or a ring spring be. The radially resilient element may be on the inner wall of the Wedge housing or dig into it. You can also do one Provide groove in the inner wall of the housing in which the radially resilient element is arranged.

Preferably is the outer stator in the radial direction inside the housing supported, being between the outer stator and the housing is provided at least one channel. The housing holds the outer stator so radially fixed. There at the float's reciprocation but a certain volume of gas from the gap between the inner stator and the outer stator, in which the anchor is moving, must be displaced is provided at least one channel through which the displaced Gas can flow axially past the outer stator, to get into an area between the linear motor and the piston. There is a sufficiently large buffer space available, into which the gas can enter without appreciably increasing the pressure. The movement of the anchor is thus not hindered by a gas cushion.

Preferably is at least a portion of the channel through a groove on the outer stator educated. One can provide such a groove without problems, without the magnetic flux through the outside stator excessively to hinder. The arrangement of a groove in the outer stator is in many cases easier than the housing accordingly reshape.

Preferably is at least a portion of the channel by a molding of a Formed front side of the housing. Here, too, you have one a path through which the gas displaces which is pushed out by the movement of the anchor in the gap becomes. In the front of the case can be in particular, to produce a molding in a simple manner, if the case at least in this area as a deep-drawn part made of sheet metal. In thermoforming (or another type of forming) can you then form the formations with the same.

Preferably the anchor is designed as a cylinder with a bottom wall, wherein arranged in the bottom wall at least one passage opening is. With the bottom wall receives the cylindrical anchor a relatively high mechanical stability. In the Bottom wall then the fasteners are arranged, with where the armature is connected to the piston. By doing that in the bottom wall at least one passage opening, in The rule also provides several passages, is also here created a way that the gas between the anchor and the inner stator is included, in one movement escape the armature or can flow. So you avoid it Again, the formation of a pressure pad or a negative pressure, which has a positive effect on the efficiency, because the anchor at no additional forces to his movement got to.

Preferably has the drive device two in a common cylinder arranged pistons, each of which is movable by a linear motor is. The two linear motors then work in push-pull. The two Pistons are thus at the same time to each other or from each other moved away. Since you have two pistons, each piston needs only half Promote gas volume. Accordingly, you need even half the stroke amplitude and half of the electromotive Power in every linear motor. This allows the size keep the linear motors small, which in turn has a positive effect on the Size of the entire drive device affects.

Preferably the coil arrangements of the two linear motors are arranged that they have opposite effects when the same current is applied demonstrate. This can be done in the simplest case by that the coil assemblies are in opposite directions flowing through current. In this case, the opposite movement of the two results Piston automatically when both Spu lenanordnungen with the same Power connection are connected.

The Invention will be described below with reference to a preferred embodiment described in conjunction with a drawing. Herein show:

1 a schematic cross section through a Stirling cooling device,

2 a partial section II-II after 1 and

3 a perspective view of a modified embodiment, partially in section.

A Stirling cooling device 1 has a drive unit 2 and a cooling device 3 on. The drive unit 2 has in the present case a cylinder 4 on, in which two pistons 5 . 6 are arranged. The two pistons 5 . 6 are out of phase along a piston axis 7 movable. They are driven by electromagnets 8th . 9 on anchor 10 . 11 act, in turn, via piston rods 12 . 13 with the pistons 5 . 6 are connected. The piston axis 7 runs in 2 from left to right and in 1 perpendicular to the drawing plane.

The cooling device 3 has a displacer 14 on, in a displacement housing 15 along a displacer axis 16 is movable. The displacer 15 and the pistons 5 . 6 are not mechanically linked. They work with a phase shift of about 90 ° to each other.

The displacer housing 15 is through an insulating wall 17 guided. It protrudes from the insulating wall on both sides 17 out. Here, the drive unit 2 facing side as "warm side" and on the other side of the insulating wall 17 arranged side of the displacer housing 15 referred to as the "cold side". On the warm side is a first heat exchanger 18 and on the cold side is a second heat exchanger 19 intended. Between the two heat exchangers 18 . 19 is a regenerator 20 arranged. The heat exchangers 18 . 19 and the regenerator 20 are arranged in an annular gap between the displacer housing 15 and a liner 21 of the displacer housing 15 is trained.

The two heat exchangers 18 . 19 and the regenerator 20 However, they do not necessarily have to be in the displacer housing 15 be arranged, provided that in other ways it is ensured that the displacement housing 15 has a cold side and a warm side.

On the cold side of the displacer housing 15 is a heat sink 22 attached, being a fan 23 for a flow of air through the heat sink 22 provides. Because the heat sink 22 in heat conductive connection with the cold side of the displacer housing 15 stands over the heat sink 22 Heat to the displacer housing 15 discharged and transferred by the Stirling process to the warm side of the displacer housing.

The displacer housing 15 and the drive unit 2 are over a line 24 connected together, the line 24 a curved section 25 having. The administration 24 opens into an end face of the displacer housing 15 that is substantially perpendicular to the displacer axis 16 stands. The administration 24 flows into the drive unit 2 in an area starting from a vertex 26 the drive unit 2 about 45 °.

On the hot side of the displacer housing 15 is another heat sink 27 arranged with a fan 28 connected is. The ventilator 28 generates an air flow through the heat sink 27 to heat, with the help of the cooling unit 3 has been transported from the cold side to the warm side to guide.

The two linear drives 8th . 9 are mirror images of the same, with a median plane 30 serves as a plane of symmetry. In the following, therefore, only the linear drive 8th explained in more detail. The linear drive 8th has an inner stator 31 and an outside stator 32 on. Between the inner stator 31 and the outside stator 32 is an annular circumferential gap 33 provided in the anchor 10 is used. The anchor 10 wears in the gap 33 permanent magnets 34 ,

In the inner stator 31 is a coil arrangement 35 received, ie the inner stator 31 holds the coil assembly 35 mechanically strong. At the same time the inner stator forms 31 a path for the magnetic flux coming from the coil assembly 35 is generated when current through the coil assembly 35 is directed. The coil order 35 has two connections for this purpose 36 . 37 on. The coil arrangement 35 is so traversed by electricity, that by the connection 36 incoming stream enters the row level (based on the representation of the 2 ), and then circular about the piston axis 7 is guided around. Would you right from the coil arrangement 35 look, the current would therefore flow counterclockwise.

The inner stator 31 is from two parts 38 . 39 assembled, which are identical. Around the inner stator 31 to form one of the two parts 38 . 39 folded by 180 ° and by 180 ° relative to the piston axis 7 turned. After that, the two parts 38 . 39 assembled and by a joining element 40 on which a disc 41 is pressed together with each other in the axial direction. The joining element 40 is synonymous with the connection 37 the coil arrangement 35 connected.

Each of the parts 38 . 39 has an annular recess 42 . 43 on. If the two parts 38 . 39 have been assembled, then form the two recesses 42 . 43 an annular Cavity in which the coil arrangement 35 can accommodate. Each of the two parts 38 . 39 has a radially inner passage opening 44 and a radially outer passage opening 45 in a front page. Both passage openings 44 . 45 are through a depression 46 connected with each other. The inner passage opening 44 serves at the part 38 to the connection 37 to lead through. The radially outer passage opening 45 serves at the part 39 to the connection 36 to lead through.

Both parts 38 . 39 are formed as sintered elements. With sintered elements, one has relatively great freedom in shaping. In addition, sintered material without much additional effort in many cases has a good magnetic conductivity.

The outside stator 32 may also be formed as a sintered element. The outer stator is formed so as to be radially inward on a housing member 47 supported. The housing element 47 forms together with a housing element 48 that the other linear actuator 9 surrounds, and a ring element 49 that the two housing elements 47 . 48 connects the housing. Through the ring element 49 are the lead 24 in the cylinder block 4 flows and with the cylinder 29 communicates, and an electrical connection 50 led, who with the connection 36 the coil arrangement 35 connected is.

The outside stator 32 is in the axial direction by a radially resilient element 58 in the housing element 47 held. The radially resilient element may be formed as an annular spring, which due to their spring force on the inner wall of the housing element 47 digs. You can in the inner wall of the housing element 47 but also provide a groove or a projection, so that the outer stator 32 with the help of a snap ring, which springs radially outward, can attach.

The outside stator 32 has an axially parallel groove 51 on that together with the housing element 47 forms an axially extending channel. The housing element 47 has an end face 52 on, the formations 53 has, through the radial grooves 54 are formed. The grooves 51 . 54 then form a channel through which gas can flow, during a movement of the armature 10 in the gap 33 is displaced or sucked. The gas can be in one area 55 between the anchor 10 and the cylinder block 4 stream. There is a sufficient buffer volume available, so that the movement of the armature 10 is not hindered by the construction of a gas cushion.

The anchor 10 is as a hollow cylinder with a bottom wall 56 educated. The bottom wall has several openings 57 on. The breakthroughs 57 allow that gas, which is between the anchor 10 and the inner stator 31 is located, with a movement of the armature in the direction of the inner stator 31 to in the room 55 can escape. When moving in the opposite direction, the gas can pass through the openings 57 be sucked.

As mentioned above, the drive means 2 two pistons 5 . 6 on, which are driven in phase opposition. This can be achieved in a simple manner in that the coil arrangement 35 Current flows through a first current direction while the coil arrangement 35 ' of the other linear motor 9 flows through with opposite current direction. So you can both coil arrangements 35 . 35 ' over the same electrical connection 50 supply electricity. This current is an alternating current, which then automatically leads to the out-of-phase movement of the two pistons 5 . 6 leads. The current is then passed over the joining elements 40 through the front wall 52 the housing elements 47 . 48 dissipated. This only requires that the joining element 40 is able to conduct the electricity. It can often be beneficial in the joining element 40 to provide an electrical conductor, not shown, which is insulated in the circumferential direction. In this case it is avoided that the housing elements 47 . 48 energized. However, a lack of insulation is uncritical when the joining elements 40 be connected to a ground terminal.

The cooling device 1 works according to the Stirling process as follows:
The Stirling process is a thermodynamic cycle that consists of two isothermal and two isochoric state changes of a gas. If the two pistons 5 . 6 be moved towards each other, then bring gas out of the cylinder 29 through the pipe 24 in the cooling unit 3 , There it flows through the regenerator 20 that absorbs heat from the gas. The temperature of the gas decreases at a constant volume (1st isochoric change of state). The then colder gas on the "cold side" of the displacer housing 15 absorbs heat from the outside. Its volume increases at constant temperature (1st isothermal state change). The gas pushes the displacer 14 against the force of a spring in the direction of the drive device 2 , When the displacer 14 moved back, then pushes the gas back through the regenerator 20 , The gas absorbs the heat stored there. The temperature is rising. The volume remains constant (2nd isochoric change of state). The gas releases heat to the environment on the warm side at a constant temperature while the volume decreases (second isothermal state change). The cycle process begins again. The necessary drive power is provided by the pistons 5 . 6 generated that the Gas in the cooling unit 3 displace and suck back from there. The pistons move 5 . 6 on the one hand and the displacer on the other 14 on the other hand with a phase shift of 90 °.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• EP 1348918 A1 [0002]

Claims (15)

Stirling cooling device with a drive device ( 2 ), which is a housing ( 47 - 49 ) and at least one of a linear motor ( 8th . 9 ) along a piston axis ( 7 ) driven piston ( 5 . 6 ) in a cylinder ( 29 ), and a displacer unit ( 3 ) connected to the drive device ( 2 ) via a gas-conducting compound ( 24 ) and at least one displacer ( 14 ), which in a displacement housing ( 15 ) along a displacement axis ( 16 ) is movable, wherein the linear motor ( 8th . 9 ) one with the piston ( 5 . 6 ) connected anchors ( 10 . 11 ), which is located between an inner stator ( 31 ) and an external stator ( 32 ), and a coil arrangement ( 35 . 35 ' ), characterized in that the coil arrangement ( 35 . 35 ' ) in the radial direction within the armature ( 10 . 11 ) is arranged. Cooling device according to claim 1, characterized in that the coil arrangement ( 35 . 35 ' ) in the inner stator ( 31 ) is recorded. Cooling device according to claim 1 or 2, characterized in that the inner stator ( 31 ) of two parts ( 38 . 39 ) which is along the piston axis ( 7 ) are arranged one behind the other. Cooling device according to claim 3, characterized in that the two parts ( 38 . 39 ) are the same. Cooling device according to one of claims 1 to 4, characterized in that the inner stator ( 31 ) and / or the outer stator ( 32 ) is formed as a sintered element. Cooling device according to one of claims 1 to 5, characterized in that the inner stator ( 31 ) and the housing ( 47 - 49 ) by a joining element arrangement ( 40 . 41 ), which has at least one forming zone. Cooling device according to claim 6, characterized in that the joining element ( 40 ) is designed as an electrical conductor, which is connected to the coil arrangement ( 35 ) connected is. Cooling device according to claim 6 or 7, characterized in that the joining element arrangement ( 40 . 41 ) has a joining element which is connected to the inside of the housing. Cooling device according to one of claims 1 to 8, characterized in that the outer stator by a radially resilient element ( 58 ) axially in the housing ( 47 - 49 ). Cooling device according to one of claims 1 to 9, characterized in that the external stator ( 32 ) in the radial direction inside the housing ( 47 - 49 ) is supported, wherein between the outer stator ( 32 ) and the housing ( 47 - 49 ) at least one channel is provided. Cooling device according to claim 10, characterized in that at least a portion of the channel through a groove ( 51 ) on the outer stator ( 32 ) is formed. Cooling device according to claim 10 or 11, characterized in that at least a portion of the channel by a molding ( 53 ) an end face ( 52 ) of the housing ( 47 - 49 ) is formed. Cooling device according to one of claims 1 to 12, characterized in that the armature ( 10 ) as a cylinder with a bottom wall ( 56 ) is formed, wherein in the bottom wall ( 56 ) at least one passage opening ( 57 ) is arranged. Cooling device according to one of claims 1 to 13, characterized in that the drive device ( 2 ) two in a common cylinder ( 29 ) arranged piston ( 5 . 6 ), each of which is controlled by a linear motor ( 8th . 9 ) is movable. Cooling device according to claim 14, characterized in that the coil arrangements ( 35 . 35 ' ) of the two linear motors ( 8th . 9 ) are arranged so that they show opposite effects with the same current application.