DE102005059074A1 - Linear motor`s Iron body for refrigerant compressor, has plates that are combined in respective groups to segments, where plates of segment are arranged parallel to radial beam through center of segments in circumferential direction - Google Patents

Abstract

The body has a set of plates (16), which forms a body with an axis. The plates are combined in respective groups to a set of segments (17). The plates of the segments are stacked parallel to each other. The plates of the segments are arranged parallel to a radial beam (28) through the center of segments in circumferential direction. The adjacent segments collide at contact surfaces (29), which are defined by radial beams (30). The plates of the segment are held together by a fastening element (22).

Description

The The invention relates to an iron body a linear motor for a refrigerant compressor, the has a plurality of sheets that form a body having an axis.

Such an iron body is for example made US Pat. No. 6,741,008 B2 known. The linear motor shown there has an outer stator, an inner stator and a reciprocable armature between the inner stator and the outer stator. In the inner stator, a coil arrangement is arranged which generates a magnetic field when current flows through it. Both the outer stator and the inner stator are formed by a plurality of sheets extending radially from inside to outside. The sheets are held together by rings on the two end faces. Even if the plates abut together at their radially inner end, an air gap forms between each adjacent plate, which becomes larger and larger with increasing distance from the axis in the circumferential direction.

at such an iron body There is a relatively bad ratio of iron to air. this has result that the Magnetic field, which is generated in a linear motor and its Operation is necessary, not always optimally managed. Accordingly is a relatively large one Size required, to the desired To provide drive services.

at Refrigerant compressors, especially those used in household refrigerators and freezers would be one the space, the one for the Refrigerant compressor and his drive is required to keep as small as possible. The outer dimensions such household appliances are usually limited by other components of a kitchen. ever smaller therefore the compressor and its drive, the more usable space is in such a refrigerator to Available.

Of the Invention has for its object to reduce the size of the linear motor.

These Task is at an iron body of mentioned type achieved in that the sheets each group are combined into several segments and the sheets of a Segments are stacked parallel to each other, wherein the sheets of a Segment parallel to a radial beam through the middle of a segment are arranged in the circumferential direction.

With This configuration can be achieve that iron body in the axial, radial and circumferential direction virtually continuous Eiser is formed. Air gaps are practically not or only where flat adjacent plates due to roughness or manufacturing tolerances locally smallest distances to each other. These distances are but unavoidable and acceptable. Above all, there are no radial inside to radially outside increasing air gaps, which worsen the ratio of iron to air. The sheets are arranged so that a parallel to the axis running Magnetic field are guided virtually continuously in the plane of a sheet can. The magnetic field must therefore over the biggest part the axial length of the iron body not even from one sheet to another. If such a transfer is required, then that must Magnetic field at this crossing only very minor disturbances overcome by air gaps. By doing that the sheets in groups in groups summarizes and the iron body forming multiple segments, one can achieve that much of the Sheets, basically even all sheets, with a justifiable deviation can be arranged to the radial direction. If you have at least three Segments used, then none of the sheets has an orientation perpendicular to a radial direction. This results in excellent magnetic relationships which lead to a good efficiency of the linear motor. Vice versa can one at a desired Power the size of the linear motor with such an iron body or reduce sheet metal package.

preferably, bump adjacent segments at interfaces together, which are defined by radial rays. This facilitates it, the segments total to a body, in particular to a essentially cylindrical Body, summarize. You can, for example, the segments by a Hold clamping ring together, which is arranged in the circumferential direction. If the segments collide at radial interfaces, then arise in this clamping only forces that act perpendicular to the interfaces, but not forces, which are directed in the radial direction.

Preferably are the sheets of a segment by at least one fastening device held together. So you can each segment as a separate component handle. The segments can prefabricated. If all segments are the same, This facilitates the production, because in a first phase of the Manufacturing only segments must be finished and only in a second Phase of making several segments into one body Circumference be assembled.

Preferably, the sheets of a segment openings on which overlap each other, wherein the fastening means at least one Be having fastening element, which is guided by a channel formed through the openings. The openings can be made when punching the sheets. It is also possible to combine the sheets into a stack and then to produce the channel by drilling. Once the channel is present, you can pass a fastener.

in this connection is particularly preferred that the Fastener is designed as a rivet. A rivet is a fastener, which is suitable for clamping the sheets perpendicular to their areal extent, where parts of the rivet that look out of the stack thus formed can be kept relatively small.

in this connection it is preferred that the Fastener is designed as a hollow rivet. When it comes to a longer one Rivet acts, one can also speak of a "Rohrniet". A tubular rivet is hollow. If the tubular rivet is formed from an electrically conductive material, then he provides only a relatively small conductive area, in the eddy currents can train. This holds Losses small.

In another embodiment may be provided that the fastening element is designed as a bolt. Leave with a bolt high forces generate to clamp the sheets into a stack. Also the Bolt can be hollow or made of an electrically bad or non-conductive material may be formed to prevent the formation of eddy currents to diminish.

Finally is it alternatively or additionally possible that the fastening device a weld having. A weld can be produced after the sheets have been combined into a stack are.

Also is advantageous if the weld on at least one end face the laminated core of a segment is arranged. At the front let yourself make the laminated core flat, i. Here are the ends of the sheets all the same position in terms of a spatial dimension. One can the weld then simply by moving a corresponding one welder produce.

Preferably is in each case a fastening device in the axial Ends of the segments provided. This has two advantages. For one thing the sheets of a segment over their entire axial length reliable held together. On the other hand, you do not need any additional Fasteners or an additional fastening device in the axial center of the sheets of a segment, so that the training a magnetic field is not disturbed there.

Also is advantageous if the sheets are glued together. The Gluing can be done over the entire surface. It is also possible, to partially bond the sheets together with an adhesive For example, only at the edges or only at the edges.

Preferably rejects the body at the periphery in an area where two segments collide, respectively a cross-sectionally triangular recess. This has the advantage that he The sheets can always form with a certain minimum size. By the Triangular recess is indeed lost a certain cross-section, otherwise for the direction of the magnetic field would be available. This Cross-sectional loss is acceptable, however, considering the benefits in Consideration that results in manufacturing.

preferably, For example, the sheets of a segment in an area where two segments collide, one newly machined surface on. If you create a stack of sheets in which two interfaces on Radial rays should lie, then results without further processing first a stepped interface. If two graded interfaces collide, then inevitably arise small air gaps. If you also avoid these small air gaps wants, then you can edit the appropriate area, for example, milling or abrade, so that one can create adjacent segments just together. The editing conveniently takes place after assembling the sheets to a laminated core. One can but if the corresponding angle for the sides of each Sheets is known, the sheets also previously edit, so that the machined surface automatically results after assembling the sheets to the laminated core.

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

1 a schematic section through a linear motor with external stator, stator and armature,

2 a cross section through a first embodiment of the inner stator,

3 the inner stator off 2 in perspective,

4 a second embodiment of the inner stator and

5 an enlarged view V of the inner stator after 4 ,

1 schematically shows a linear motor 1 for driving a refrigerant compressor shown only schematically 2 ,

The linear motor has an external stator 3 and an indoor stator 4 on. Between the outer stator 3 and the inner stator 4 is a gap 5 formed in which an anchor 6 is arranged. The anchor 6 has permanent magnets in a manner not shown and is opposite to the outer stator 3 and the inner stator 4 movable. During the movement he drives movable elements of the refrigerant compressor 2 on, for example, a piston in a cylinder.

The outside stator 3 has a coil arrangement 7 with a coil wound in a ring 8th and a bobbin holder 9 on. The coil holder 9 is made of a plastic and insulates the coil 8th electrically against the external stator 3 ,

When a current passes through the coil 8th is passed, then this current generates a magnetic field, which is annular through the outer stator 3 , the gap 5 , the anchor 6 and the inner stator 4 closes. This will be the anchor 6 pulled in one direction. When the direction of the current through the coil is reversed, the magnetic field also changes its direction of circulation and the armature 6 is moved to another position. By a periodic switching of the current direction can thus be a corresponding periodic movement of the armature 6 which can be used to drive a piston in the refrigerant compressor 2 can use.

In order to be able to guide the magnetic field, has the outside stator 3 a yoke 10 on, which may be formed for example from a wound into a roll of sheet metal strip. The yoke 10 is parallel to a longitudinal axis 11 aligned. The longitudinal axis 11 agrees with the direction of movement of the yoke 6 match. At the two end faces of the yoke are tooth sections 12 . 13 intended. The outside stator 3 So it has two teeth, so to speak. At the radially inner end of the tooth sections 12 . 13 each is a Zahnfußanordnung 14 . 15 intended.

In the area of the yoke 10 the magnetic field becomes substantially parallel to the longitudinal axis 11 guided. Also in the inner stator 4 the magnetic field is over a relatively large part of the length parallel to the longitudinal axis 11 guided. In order to ensure the leadership of the magnetic field loss possible, the inner stator has 4 a structure that is schematically in 2 and 3 is shown.

2 shows the inner stator 4 in a schematic sectional view. It can be seen that the inner stator 4 through a variety of sheets 16 is formed, wherein in each case a plurality of sheets in groups to form a segment 17 are summarized. The sheets 16 all have the same length parallel to the longitudinal axis 11 , But they have at least for the most part different widths, so that the sheet stack 18 , by the stacked th sheets 16 is formed, an approximately cylindrical outer side 19 having. The sheets 16 form small steps 20 that can be readily accepted.

The sheets 16 all have a hole 21 on, where are the holes 21 all sheets 16 overlap or cover so that a continuous channel is formed, in which a fastener 22 is arranged. The fastener 22 is formed in the present embodiment as a hollow rivet, that is, it surrounds a cavity 23 , At both ends, the fastener 22 closing heads 24 . 25 on, through which the sheets 16 be compressed perpendicular to their areal extent.

Instead of a rivet-shaped fastener can of course also use a bolt, in which the sheets 16 can be clamped together by tightening a nut perpendicular to its planar extension. A bolt can also be hollow. Both rivet and bolt can be made of electrically non-conductive or poorly conductive material.

It is also possible on one end face 26 ( 3 ) of a segment 17 a weld 27 to attach to the sheets 16 to connect with each other. You can get the sheets 16 also by gluing together.

The sheets 16 a segment 17 are all parallel to a first radial ray 28 formed by the middle of a segment 17 runs in the circumferential direction. Because all the sheets 16 Are arranged parallel to each other, air gaps between individual sheets 16 a segment 17 avoided.

Neighboring segments 17 bump into a contact surface 29 together, on a second radial 30 lies.

There, where two segments 17 collide, so in the range of every other radial beam 30 , indicates the inner stator 4 on its outer circumference an approximately triangular recess 31 on, so that the respective outer sheets of a segment 17 can keep a certain width.

The in the embodiment according to 4 provided see three segments are at their contact surfaces 29 assembled and then by ligaments or rings 32 running circumferentially around the segments 17 can be stretched, fixed to each other. Because the contact surfaces 29 on a radial beam 30 lie, results from this fixation force application of the segments 17 in which forces only perpendicular to the contact surfaces 29 Act. A shift of the segments 17 against each other in the radial direction is therefore not to be feared. The bands or rings 32 can be provided in grooves not shown in detail. They are preferably formed of electrically non-conductive material.

The fasteners 22 are each only in axial end portions of the inner stator 4 provided, so for example in a section between 0 and 10% of the axial length of the inner stator 4 and in a range between 90% and 100% of the axial length of the inner stator 4 , A middle range between 10 and 90% of the axial length of the inner stator 4 can of such fasteners 22 be kept free, without the function or the construction of the inner stator 4 is negatively affected.

In the embodiment according to 2 have the sheets 16 such a width that the inside 33 the segments 17 also a curved course with steps 34 Has. The recess thus formed 35 , which passes through the inner stator lengthwise, can be used, for example, to store and fasten the inner stator. In addition, through the recess 35 saved a certain amount of material and weight.

The 4 and 5 show a modified embodiment of an inner stator 4 , which first of the embodiment of the 2 and 3 differs in that not three, but four segments 17 are provided. In addition, the recess is missing 35 in the radial center, which is the inner stator 4 interspersed in length. Of course, but also a training with four segments 17 such a recess 35 exhibit. An embodiment with three segments can also without recess 35 , so be executed massive. In any case, the segments are through stacks of sheets 16 educated.

In addition, especially in 5 to realize that the segments 17 at their contact surfaces 29 a ebe ne, so do not have graduated education. This training can be achieved, for example, that the segments 17 initially by stacking the sheets 16 and joining the sheets 16 getting produced. Thereafter, the contact surfaces are ground or milled off so that the steps disappear. By flat contact surfaces 29 can be air gaps between adjacent segments 17 further reduce, which would have to be overcome by the magnetic field.

Of course you can also do more than the four segments shown 17 use.

The sheets are in the 2 to 5 not necessarily drawn to scale. It will use a sheet thickness, on the one hand sufficiently prevents the formation of eddy currents, on the other hand, but provides a sufficient line cross-section for the magnetic field.

Claims (13)

Iron body of a linear motor for a refrigerant compressor, comprising a plurality of sheets forming a body with an axis, characterized in that the sheets ( 16 ) in groups of several segments ( 17 ) and the sheets ( 16 ) of a segment ( 17 ) are stacked parallel to each other, wherein the sheets ( 16 ) of a segment ( 17 ) parallel to a radial jet ( 28 ) through the middle of a segment ( 17 ) are arranged in the circumferential direction. Iron body according to claim 1, characterized in that adjacent segments ( 17 ) at interfaces ( 29 ) caused by radial rays ( 30 ) are defined. Iron body according to claim 1 or 2, characterized in that the sheets ( 16 ) of a segment ( 17 ) by at least one fastening device ( 22 . 27 ) are held together. Iron body according to claim 3, characterized in that the sheets ( 16 ) of a segment ( 17 ) Have openings that overlap each other, wherein the fastening device at least one fastening element ( 22 ) through a channel formed by the openings ( 21 ) is guided. Iron body according to claim 4, characterized in that the fastening element ( 22 ) is designed as a rivet. Iron body according to claim 5, characterized in that the fastening element ( 22 ) is designed as a hollow rivet. Iron body according to claim 4, characterized in that the fastening element ( 22 ) is designed as a screw bolt. Iron body according to one of claims 3 to 7, characterized in that the fastening device is a weld ( 27 ) having. Iron body according to claim 8, characterized in that the weld seam ( 27 ) on at least one end face ( 26 ) of the laminated core of a segment ( 17 ) is arranged. Iron body according to one of claims 3 to 9, characterized in that in each case a fastening device ( 22 . 27 ) in the region of the axial ends of the segments ( 17 ) is provided. Iron body according to one of claims 1 to 10, characterized in that the metal sheets ( 16 ) are glued together. Iron body according to one of claims 1 to 11, characterized in that the body in each case in the region in which two segments collide, in each case a cross-sectionally triangular recess (Fig. 31 ) having. Iron body according to one of claims 1 to 12, characterized in that the sheets ( 16 ) of a segment ( 17 ) in one area ( 29 ), in which two segments collide, have a newly machined surface.