DE112015002586T5 - Winding body and method for producing the wound body - Google Patents

Abstract

Use free space created in the container to extend the winding material of the bobbin, and increase the strength of the units by reducing the dead space. Winding body (1), which is formed by winding the winding material (2) several times on a predetermined axis; In certain areas of the wound wrapping material (2) spacers (3) are provided.

Description

Technical area

The invention relates to a wound body and a method for producing the wound body.

background art

Winding bodies formed by winding wrapping material on a core are well known. Winding bodies have a predetermined number of turns, and are accommodated in a container.

The geometry of a bobbin depends on the geometry of the core on which the wrapping material is wound, but regardless of which geometry the core has, the bobbin becomes more and more round as the number of turns increases, and the bobbin approaches a cylinder (cf. Patent Documents 1, 2).

Containers which receive the bobbins, may be cylindrical according to the final shape of bobbins, or be formed cuboid in view of the fact that the containers are stacked on each other.

citations

Patent documents

• Patent Document 1: Japanese Laid-Open Patent Application 2002-42854
• Patent Document 2: Japanese Laid-Open Patent Application 2003-157888

Disclosure of the invention

Technical tasks to be solved

However, placing a bobbin in a cylindrical container creates gaps between the adjacent containers because the outside of the container is arcuate. And here is a problem that when stacking a plurality of units consisting of containers and housed therein bobbins, the space can not be used optimally.

On the other hand, as in 14 shown when taking a cylindrical bobbin 102 in a cuboid container 101 accommodates, arises between the inner wall of the container 101 and the winding body 102 a room 103 , Here there is the problem that the number of turns of the bobbin 102 is limited, although in the container 101 the space 103 is available. Furthermore, there is a problem that the strength of containers 101 when they are stacked because of the creation of the room 103 in the container 101 , can not be sustained.

Therefore, the present invention has been made in view of the above objects, and has an object to a bobbin, which can be extended by efficiently using a space in the container, the wrapping material, and by reducing the space, the strength of the unit can be improved, and a method to provide for the production of the winding body.

Means of solving the tasks

To achieve the above objects, the present invention relates to a bobbin which is formed by winding the winding material several times on a predetermined axis, characterized in that spacers are provided in certain areas of the wound wrapping material.

Said wrapping material advantageously has a plurality of corners bent through the spacers and rectilinear portions between the corners.

The spacers are advantageously arranged at equal intervals.

The spacers are advantageously, if one sees the winding body in longitudinal section in the winding direction of the winding material, arranged around the predetermined winding axis as the center at intervals of 90 °.

The spacers are advantageously, if one sees the winding body in longitudinal section in the winding direction of the winding material, arranged around the predetermined winding axis as the center at intervals of 60 °.

The spacers are advantageously, when looking at the winding body in longitudinal section in the winding direction of the winding material, arranged around the predetermined winding axis as the center at intervals of 120 °.

The spacers are advantageously made of hardenable ink or gel.

The spacers are advantageously made of plastic.

The spacers are advantageously all made in the same size.

The spacers are advantageously at least partially all made in a different size than other spacers.

The wrapping material is advantageously a laminate tape.

The wrapping material is advantageously a power generating element consisting of a positive layer, a negative layer and a separating layer arranged between the positive layer and the negative layer.

The wrapping material is advantageously a wire material.

The present invention relates to a method of manufacturing a bobbin, characterized in that the method comprises the step of transporting the wrapping material to the core on which the wrapping material is wound; the step of successively mounting the spacers on the surface of the wrapping material at predetermined intervals during transportation of the wrapping material; and the step in which the spacer-provided wrapping material is successively wound on the core.

The spacer is advantageously formed by spraying a hardenable ink onto the surface of the wrapping material and hardening the ink.

The spacer is advantageously formed by adhering a spacer held in the holder to the surface of the core.

The present invention relates to a method of manufacturing a bobbin, characterized in that the method comprises the step of transporting the wrapping material to the core on which the wrapping material is wound; the step of successively attaching the spacers to the surface of the wrapping material at predetermined intervals before transporting the wrapping material; and the step in which the spacer-provided wrapping material is successively skewed onto the core material.

The present invention relates to a method of manufacturing a bobbin, characterized in that the method comprises the step of transporting the wrapping material to the core on which the wrapping material is wound; the step in which supplied wrapping material is sequentially wound on the core; and the step of inserting the spacers at predetermined intervals between the wrapping material during winding of the wrapping material onto the core.

Effect of the invention

According to the invention, the winding material for the bobbin can be extended by effectively utilizing the space formed in the container, and by reducing the space, the strength of the unit can be improved.

Brief description of the drawings

Show it

( 1 ) an approximately quadrangular winding body from one side in the direction of Aufwiklungsachse.

( 2 ) is a schematic representation explaining a method of manufacturing the bobbin.

( 3 ) Sketches explaining the geometry of spacers.

( 4 ) An enlarged view of a portion of a wound without spacers wrapping material.

( 5 ) is an enlarged view of a portion of a wound with spacers wound material, wherein the n-th and the n + 1-th surface of the wrapping material have the same curvature.

( 6 ) An enlarged view of a portion of a spacer material wound with winding material, wherein the n-th and the n + 1-th surface of the winding material have different curvatures.

( 7 ) is a schematic representation of stacked units, each consisting of an approximately quadrangular winding body and a container containing the winding body.

( 8th ) An approximately hexagonal bobbin from one side in the direction of Aufwicklungsachse.

( 9 ) is a schematic representation of stacked units, each consisting of an approximately hexagonal bobbin and a container containing the bobbin

( 10 ) an approximately triangular bobbin from one side in the direction of Aufwicklungsachse.

( 11 ) is a schematic representation of stacked units, each consisting of an approximately triangular bobbin and a container containing the bobbin.

( 12 ) is a schematic diagram showing another example of the method of attaching spacers to the wrapping material.

( 13 ) is a schematic diagram showing another example of the method of attaching spacers to the wrapping material.

( 14 ) is a schematic representation explaining the state of a conventional bobbin accommodated in a container.

Embodiment of the invention

Hereinafter, advantageous embodiments of the present invention will be described with reference to the drawings. The bobbins according to the invention comprise all bobbins, whether they are intended for which technical fields, as long as it is wound body, which are formed by winding a winding material several times on a predetermined axis; however, the following embodiments will be explained by way of examples in which the bobbins are batteries.

(Bobbin)

1 shows an approximately quadrangular bobbin from one side in the direction of Aufwicklungsachse. As 1 shows, the winding body is a body by rewinding a winding material several times 2 was formed on a predetermined axis. The winding body consists of a winding material 2 and spacers 3 ,

The wrapping material 2 is for example a plate-shaped laminate tape. The laminate tape consists of four layers - a positive layer, a negative layer, and a release layer interposed between the positive layer and the negative layer - layered on top of each other. The laminate tape functions as a power generating element of a battery.

By winding up this wrapping material 2 to a roll (core) by a predetermined length, a power generation element having a certain capacity can be produced.

spacer 3 are on one side of the wrapping material 2 provided, and several of them are after winding the wrapping material 2 in an area between the wrapping material adjacent in the thickness direction (radial direction) of the former 2 arranged. The spacers 3 are all the same size and arranged at equal intervals. The spacers 3 are not arranged so that it fills the entire surface of one side of the wrapping material, but how 1 shows, the bobbin 1 in longitudinal section along the winding direction of the winding material 2 seen to the winding axis O arranged at intervals of 90 °. By this arrangement of the spacers 3 become the spacers 3 with intermediate wrapping material 2 straight in the thickness direction of the bobbin 1 arranged, and the lines L1, L2, the centers of the opposite to the winding axis O spacers 3 connect, each will be straight lines. These straight lines L1, L2 intersect orthogonally on the winding axis O. The wrapping material 2 will be in the areas where the spacers 3 are arranged to the thickness of the Abtandshalter 3 shifted outwards so that the curvatures in these areas are larger, and a little bit more pointed than the arc of a circle. Therefore, the four areas in which the spacers are lined up in the thickness direction are curved by the spacers, and as angular areas 21 educated. By training these angular areas 21 become the remaining areas of the wrapping material 2 (the areas that make up the angular areas 21 connect) to rectilinear stretches 22 so that is a roughly quadrangular bobbin 1 Although not a complete four corners, but four angular areas 21 having.

The spacers 3 are formed, for example, by having a hardenable ink on one side of the wrapping material 2 sprayed and hardened. The material for the spacers 3 is not limited to curable inks, but it can also gel materials, plastic, metals, paper, yarn, ceramics, rubber, etc. are used. In short, any material can be used as far as it is by creating spaces between them in the thickness direction of the bobbin 1 adjacent turns of the wrapping material 2 the curvatures of the wrapping material 2 can change.

(Method for producing the wound body)

Now, the method for producing the bobbin 1 described.

2 is a schematic diagram which explains a method for producing the bobbin, and 3 are sketches that explain the geometry of spacers.

As in 2 shown, the wrapping material 2 from one end of the roll-wound wrapping material 2 pulled out and the wrapping material 2 becomes the role 10 that as the core to Winding up the wrapping material 2 serves, transports. When transporting to the roll 10 becomes the wrapping material 2 along the surface direction conveyed rectilinear, and on the transport path are spacers 3 on the upper side of the wrapping material 2 educated. The spacers 3 are formed by a liquid curable ink from a nozzle 11 on the wrapping material 2 is sprayed and the ink hardens.

As the hardenable ink, UV-hardening type, thermosetting type and the like may be used. be chosen freely.

The ink is injected at a pre-set time interval, leaving the wrapping material 2 Spacers are arranged successively at preset intervals. The distances between the spacers 3 are adjusted so that the spacers 3 when winding up the wrapping material 2 on the role 10 in the thickness direction of the bobbin 1 be strung together in a straight line, with the necessary distances in each winding is taken into account.

As 3 shows, the spacers can 3 along the width direction (transverse direction orthogonal to the longitudinal direction) of the wrapping material 2 be formed straight (see 3 (a) ), or be arranged pointwise along the width direction of the Wickelmaerials with preset distances (see 3 (b) ).

The ink sprayed onto the wrapping material hardens to the roll at the time of winding 10 , and that with the spacers 3 provided wrapping material 2 then becomes suksessive to the role 10 wound. Since the winding up of the wrapping material 2 on the role 10 under a certain, on the wrapping material 2 acting tension, the winding is on the roll 10 executed without slack or gaps in the wound body. However, in the areas where the spacers 3 are arranged, free space is created around the spacers 3 , and the curvature of the wrapping material 2 changes.

(Extension of the wrapping material by placing spacers)

Now, an increase in the total length of the wrapping material 2 by placing spacers 3 described.

4 is an enlarged view of a part without a spacer 3 wound wrapping material 2 , 5 is an enlarged view of a portion of one with spacers 3 wound wrapping material 2 in which the nth and n + 1st surface of the wrapping material 2 have the same curvature. 6 is an enlarged view of a portion of one with spacers 3 wound wrapping material 2 in which the nth and n + 1st surface of the wrapping material 2 have different curvatures.

As in 4 Shown is a section of the bobbin 1 (1/4 of the circumference) considered. Let's call the radius to the outer circumference of the n-th winding of the winding material 2 as r, and the thickness of the wrapping material 2 as t, the length of the outer circumference of the nth turn of the wrapping material becomes 2 LN ₁ , and the length of the outer circumference of the n + 1-th winding of the wrapping material 2 LN ₂ : LN ₁ = 2πr / 4 LAN ₂ = 2π (r + t) / 4

As in 5 shown, will be the case in which between the nth turn of the wrapping material 2 and the n + 1-th winding of the wrapping material 2 spacer 3 are arranged, at a portion of the bobbin 1 (1/4 of the circumference) considered. The radius of the arc of the nth turn of the wrapping material 2 is the radius of the arc of the n + 1-th turn of the wrapping material 2 equal. Namely, if the turns are made to have equal curvatures, and the radius is designated to the outer circumference of the nth turn of the wrapping material 2 as r, and the thickness of the wrapping material 2 as t, the length of the outer circumference of the nth turn of the wrapping material becomes 2 LA ₁ , and the length of the outer circumference of the n + 1-th winding of the wrapping material 2 LA ₂ : LA ₁ = 2πr / 4 LA ₂ = 2πr / 4 + 2t

Assuming for the length LA ₂ and the length LN ₂ that the relation LA ₂ > LN ₂ exists, the equation can be reshaped and simplified as follows: 2πr / 4 + 2t> 2π (r + t) / 4 2πr + 8t> 2πr + 2πt 8t> 2πt (8-2π) t> 0 1.7168t> 0

Since t> 0, it is confirmed that this relation exists.

Consequently, by comparing bobbins 1 with the same number of turns, one can notice that the total length of the wrapping material 2 through the spacers 3 is extended.

As in 6 shown, will be the case in which between the nth turn of the wrapping material 2 and the n + 1-th winding of the wrapping material 2 spacer 3 be arranged as in 4 and 5 at a portion of the bobbin 1 (1/4 of the circumference) considered. The radius of the arc of the n + 1-th turn of the wrapping material 2 is smaller than the radius of the arc of the nth turn of the wrapping material 2 , Namely, if the turns are made to increase in curvature, and the radius is designated to the outer circumference of the nth turn of the wrapping material 2 as r ₂ , the length of the two ends of the arc of the n + 1-th winding of the wrapping material 2 extending straight section as s, and the thickness of the wrapping material as t, so become the length of the outer circumference of the n-th winding of the wrapping material 2 LB ₁ , and the length of the outer circumference of the n + 1-th winding of the wrapping material 2 LB ₂ : LB ₁ = 2πr _1/4 LB ₂ = 2πr _2/4 + 2s

Assuming for the length LB ₂ and the length LN ₂ that the relation LB ₂ > LN ₂ exists (assuming r1> r2, s = t + r1 - r2), the equation can be reshaped and simplified as follows : 2πr _2/4 + 2s> 2π (r + t) / 4 2πr _2/4 + 2 (t + r ₁ -r ₂ )> 2π (r ₁ + t) / 4 2πr ₂ + 8 (t + r ₁ -r ₂ )> 2π (r ₁ + t) 2πr ₂ + 8t + 8r ₁ - 8r ₂ > 2πr ₁ + 2πt 8t - 2πt> 2πr ₁ - 2πr ₂ - 8r ₁ + 8r ₂ (8-2π) t> (8-2π) r ₂ - (8-2π) r ₁ t> r ₂ - r ₁ t - (r ₂ -r ₁ )> 0

Since t> 0, r ₁ > r ₂ , it is confirmed that this relation exists.

Consequently, by comparing bobbins 1 with the same number of turns, one can notice that the total length of the wrapping material 2 , even with ever-increasing curvature, by the spacers 3 is extended.

(Effect)

In the above-described bobbin 1 and in the process for producing the bobbin 1 becomes the wrapping material 2 in that between between in the thickness direction of the bobbin 1 adjacent turns of the wrapping material 2 spacer 3 be arranged in the areas where the spacers 3 are arranged to the thickness of the Abtandshalter 3 shifted outwards so that the curvatures in these areas are larger, and a little bit more pointed than the arc of a circle.

Therefore, the four areas in which the spacers are lined up in the thickness direction, through the spacers 3 curved, and as angular areas 21 educated. By training these angular areas 21 become the remaining areas of the wrapping material 2 (the areas that connect the angular areas) to straight sections 22 so that is a roughly quadrangular bobbin 1 Although not a complete four corners, but four angular areas 21 having.

This causes, as in 7 shown when looking at the winding body 1 in a conventional cuboid container 4 accommodates the rectilinear sections 22 almost on the inner wall of the container 4 is present, and there the angular areas 21 more pointed than the arc, the dead space in the container is largely reduced.

Therefore, it is possible to produce a bobbin adapted to the container, and in the container 4 resulting space to use the wrapping material 2 to extend the bobbin. In addition, the strength of the unit can be increased by reducing the dead space, a winding body 1 which is also suitable for stacking the units can be realized.

Furthermore, as described above, can be by attaching spacers 3 the total length of the wrapping material 2 extend with the same number of turns, so that the capacity of the battery can be increased.

(Examples of modifications)

The above embodiment has been explained by way of example of an approximately quadrangular bobbin. But, as described below, the bobbin may also be made approximately hexagonal or approximately triangular.

8th shows an approximately hexagonal bobbin from one side in the direction of Aufwicklungsachse, and 9 shows a schematic representation of stacked units, each consisting of an approximately hexagonal bobbin and a container containing the bobbin.

As in 8th shown are the spacers 3a when you take the bobbin 1a in longitudinal section in the winding direction of the winding material 2a looks to the winding axis O as the center at intervals of 60 °. By this arrangement of the spacers 3a become the spacers 3a with intermediate wrapping material 2a straight in the thickness direction of the bobbin 1a arranged, and the six areas where the spacers 3a strung together in the thickness direction, by the spacers 3a curved, and as roundish angular areas 21a educated. By training these angular areas 21a become the remaining areas of the wrapping material 2a (the areas that make up the angular areas 21a connect) to rectilinear sections 22a , leaving an approximately hexagonal bobbin 1a Although not complete corners, but six angular areas 21 having.

As in 9 is shown by housing the bobbin 1a in a hexagonal columnar container 4a In the stacking of the units, a honeycomb structure is realized which permits gapless stacking of the units, so that the strength of the units can be greatly increased.

10 shows an approximately triangular bobbin from one side in the direction of Aufwicklungsachse, and 11 shows a schematic representation of stacked units, each consisting of an approximately triangular bobbin and a container containing the bobbin.

As in 10 shown are the spacers 3 when you take the bobbin 1b in longitudinal section in the winding direction of the winding material 2 B sees to the winding axis O as the center at intervals of 120 °. By this arrangement of the spacers 3b become the spacers 3b with intermediate wrapping material 2 B straight in the thickness direction of the bobbin 1b arranged, and the three areas where the spacers 3b strung together in the thickness direction, by the spacers 3b curved, and as roundish angular areas 21b educated. By training these angular areas 21b become the remaining areas of the wrapping material 2 B (the areas that make up the angular areas 21b connect) to rectilinear sections 22b , leaving an approximately triangular bobbin 1b Although not complete corners, but three angular areas 21b having.

As in 11 it is shown by housing such a bobbin 1b in a container 4b It is possible to stack the units without gaps so that the strength of the units can be greatly increased.

(Miscellaneous)

The present invention is not limited to the above-described embodiments. Geometry of the bobbin is not limited to the above examples; rather, the bobbin may exhibit the above-described effects insofar as it has an approximately polygonal shape with a plurality of corners.

12 and 13 show other examples of providing the wrapping material with Abstandashaltern.

As in 12 shown, can be used for attaching spacers 3 to the wrapping material 2 also use a method in which on the surface of the belt B of the spacer holder 12 spacer 3 stick with preset intervals, and the tape B with a predetermined time setting the wrapping material 2 is approached to the located on the band B spacers 3 to the wrapping material 2 is glued.

Continue, as in 13 It is also possible to attach spacers 3 to the wrapping material 2 to use a method in which before the transport of the wrapping material 2 to the role 10 , Spacers 3 at preset intervals on the surface of the wrapping material 2 are attached, and then the pulled out winding material 2 sukzessilv transported and on the role 10 is wound up.

Attaching spacers does not necessarily, as in 2 and 12 shown to take place during the transport of the wrapping material; Spacers may also be inserted during winding of the wrapping material onto the core, at preset distances, between the adjacent turns, the nth turn, and the n + 1th turn of the wrapping material.

The wrapping material has been described here as a band-shaped material, but as a wrapping material, a wire material used for coils may be used. In this case, a bar or a sheet may be used as spacers, and spacers may be realized by inserting spacers before winding the n-th turn on the winding axis, and before winding the n + 1-th turn again Spacers are used on the nth turn.

In addition, spacers need not be disposed between all the thicknesswise adjacent turns of the wrapping material; Mounting positions for spacers can be changed as required. As far as the size of spacers is concerned, at least part of spacers may be of a different size than the other spacers. Namely, depending on the geometry of the container, attachment positions and size of spacers can be arbitrarily changed.

Claims (18)

Winding body, which is formed by winding the winding material several times on a predetermined axis, characterized in that spacers are provided in certain areas of the wound winding material. The winding body according to claim 1, characterized in that said wrapping material has a plurality of corners bent through the spacers and rectilinear portions between the corners. Winding body according to claim 1 or 2, characterized in that the spacers are arranged at equal intervals. Winding body according to one of claims 1 to 3, characterized in that the spacers, when one sees the winding body in longitudinal section in the winding direction of the winding material, are arranged around the predetermined winding axis as the center at intervals of 90 °. Winding body according to one of claims 1 to 3, characterized in that the spacers, when one sees the winding body in longitudinal section in the winding direction of the winding material, are arranged around the predetermined winding axis as the center at intervals of 60 °. Winding body according to one of claims 1 to 3, characterized in that the spacers, when one sees the winding body in longitudinal section in the winding direction of the winding material, are arranged around the predetermined winding axis as the center at intervals of 120 °. Winding body according to one of claims 1 to 6, characterized in that the spacers are made of hardenable ink or hardenable gel. Winding body according to one of claims 1 to 6, characterized in that the spacers are made of plastic. Winding body according to one of claims 1 to 8, characterized in that the spacers are all made in the same size. Winding body according to one of claims 1 to 8, characterized in that the spacers are at least partially all made in a different size than other spacers. Winding body according to one of claims 1 to 10, characterized in that the winding material is a laminate tape. The wound body according to claim 11, characterized in that the laminate tape is a power generation element consisting of a positive layer, a negative layer and a release layer interposed between the positive layer and the negative layer. Winding body according to one of claims 1 to 10, characterized in that the winding material is a wire material. A method of manufacturing the bobbin according to any one of claims 1 to 13, characterized in that the method comprises the step of transporting the wrapping material to the core on which the wrapping material is wound; the step of successively mounting the spacers on the surface of the wrapping material at predetermined intervals during transportation of the wrapping material; and the step in which the spacer-provided wrapping material is successively wound on the core. The method of manufacturing the bobbin according to claim 14, characterized in that the spacers are formed by pressing a hardenable ink onto the surface of the wrapping material and hardening the ink. A method of manufacturing the bobbin according to claim 14, characterized in that the spacers are formed by adhering the spacers held in the holders to the surface of the core. A method of manufacturing a bobbin according to any one of claims 1-13, characterized in that the method is the step in which the winding material is transported to the core, on which the wrapping material is wound; the step in which prior to the transport of the wrapping material, the spacers on the surface of the Wickelmaterials be mounted successively with predetermined intervals; and the step in which the spacer-provided wrapping material is successively skewed onto the core. A method of manufacturing a bobbin according to any one of claims 1-13, characterized in that the method is the step in which the winding material is transported to the core, on which the wrapping material is wound; the step in which supplied wrapping material is sequentially wound on the core; and the step of inserting the spacers at predetermined intervals between the wrapping material during winding of the wrapping material onto the core.

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