JP2006519318A - High temperature paper containing aramid component - Google Patents

Abstract

A paper structure comprising an aramid component comprising cellulosic pulp fibers, a polymeric binder, and aramid fibers / fibrids is provided. The paper structure can also include multiple layers of different composition, but at least one layer must include an aramid component and a polymeric binder.

Description

[Cross-reference of related applications]
This application claims the benefit of US Provisional Application No. 60 / 409,230, filed Sep. 10, 2002, which is incorporated herein in its entirety.

  The present invention relates to a high-temperature paper, particularly a high-temperature paper containing an aramid component. Such high temperature paper can include single or multiple layers.

[Description of related technology]
High temperature electrical insulation paper is used in transformers and has two functions. First, the electrical insulating paper is electrically insulating and prevents short circuits of the coils in the transformer. Second, the paper has mechanical strength. When a large current flows through the transformer, a force that moves the paper bonded to the coil acts on each layer of the coil. Since the paper is bonded to the coil, various coils are prevented from expanding and contracting. Each coil behaves like a cylindrical coil and tries to move. The electrical insulating paper (E-board) prevents this expansion and contraction.

  An increase in the mechanical strength of the electrical insulation paper will help to avoid problems with the expanding and contracting coil. The use of reinforced electrical insulation paper to reinforce the paper should help provide the necessary mechanical strength. However, this paper will need to be produced efficiently and effectively.

  It is also of concern to improve the heat resistance of the electrical insulation paper used in the transformer so that a cheaper transformer can be designed. By reducing the coil wire diameter in the transformer, the coil is reduced in size. If a thin coil is used, the iron core and metal container can be made smaller. Smaller containers have less oil. In other words, copper, iron core steel, and insulating oil can be reduced. However, because the wire is thin, the electrical resistance of the transformer will increase and become hot. Therefore, in order to put such a transformer into practical use, it is necessary to improve the heat resistance of the electrical insulating paper.

  If there is paper having such high mechanical strength and high heat resistance, it will be possible to industrially design a transformer that can recognize the above-mentioned advantages in terms of economy and performance.

  Accordingly, one object of the present invention is to provide a paper structure having high heat resistance.

  Yet another object of the present invention is to provide a paper structure having high mechanical strength.

  Another object of the present invention is to provide a hot paper suitable for use in a transformer.

  These and other objects of the present invention will become apparent to those of ordinary skill in the art upon reviewing the following description and the claims appended hereto.

  In accordance with the present invention, a paper structure comprising an aramid component is provided. The paper structure includes aramid fibers and / or fibrids, polymeric binders such as polyvinyl alcohol, and cellulosic pulp fibers.

  In certain preferred embodiments, the paper structure includes two outer layers and at least one inner layer. The two outer layers are preferably substantially composed of cellulosic (woody) pulp fibers. This inner layer contains cellulosic pulp fibers, aramid fibers and / or fibrids and a polymeric binder. In a preferred embodiment, the structure includes at least three inner layers, all of which include cellulosic pulp fibers, an aramid component, and a polymeric binder.

From the obtained paper structure, a very useful paper can be obtained as an electrical insulating paper in a transformer because of its high heat resistance. Furthermore, the present aramid fiber reinforces the paper and helps to avoid coil stretching problems.
Detailed Description of Preferred Embodiments

  The paper structure of the present invention is very useful as a high-temperature electrical insulating paper. The paper has both high heat resistance and good mechanical strength. Good heat resistance will allow this paper to be used in transformers with smaller coils that are prone to high temperatures. Furthermore, since the paper is also reinforced, it will prevent the various coils from expanding and contracting when bonded to the coils. In actual use in a transformer, the paper is coated with an adhesive such as an epoxy adhesive and thermally bonded to the coil wire surface. It is this adhesion to the coil that prevents this paper from expanding and contracting various coils. The mechanical strength of the paper structure of the present invention, which includes an aramid component combined with a polymeric binder, allows the electrically insulating paper to function efficiently and effectively while preventing coil expansion and contraction.

  The paper structure of the present invention includes a polymeric binder and an aramid component, which may be an aramid fiber, fibrid, or a combination thereof, and a cellulosic pulp fiber.

  The aramid fiber can be any commercially available polyaramid fiber such as NOMEX®. The fibers are generally about 1/4 inch long and about 2 denier in thickness. Fibrids are irregularly shaped pieces of aramid polymer that have a very large two-dimensional dimension compared to the third dimension. Its shape is like fine corn flakes. The two larger dimensions are on the order of 5 to 25 micrometers, and the smaller third dimension is about 0.01 to 1 micrometers.

  In paper structures, the amount of cellulosic wood pulp fibers is generally in the range of 50 to 80% by weight, while the amount of aramid component is generally in the range of about 5 to 25% by weight. The amount of polymeric binder, preferably polyvinyl alcohol, generally ranges from about 10 to 25% by weight. The 5 to 25 wt% aramid component may include aramid fibers or aramid fibrids alone or preferably a combination of the two. In the case of a combination, it is preferred to use a fiber / fibrid ratio of about 60/40% by weight. If aramid fibrids are included, it also serves as a binder to the network structure, so the amount of polymeric binder can be reduced. For this reason, it is preferable that aramid fibrid is included to some extent. Since this serves a dual role, the required amount of aramid fibers and binder can be reduced.

  Small amounts of other synthetic fibers may also be present. Such synthetic fibers can be, for example, polyester fibers or nylon fibers.

  The paper structure of the present invention can be a single layer or multiple layers. When a single layer is employed, the paper structure includes cellulosic pulp fibers, an aramid component, and a polymer binder as described above. Multiple layers of such combinations can also be employed, in which case the amount of individual components in a particular layer may vary. Alternatively, a veiled structure can be used. In such a veiled structure, the two outer layers consist essentially of wood pulp fibers and are preferably free of polymeric binder. On the other hand, whether it is a single layer or multiple layers, this inner layer contains various components such as cellulosic wood pulp fiber, an aramid component and a polymer binder. A small amount of synthetic fibers such as polyester fibers or nylon fibers may be present in this outer cellulosic pulp fiber layer.

  Where multiple layers are employed, the paper structure is preferably produced using a cylinder machine with at least three different cylinders as is known in the art. Different raw material compositions can be supplied to each of these cylinders corresponding to a particular layer of paper structure.

  In a preferred embodiment, the paper structure includes five different layers. The two outer layers consist essentially of cellulosic, preferably woody pulp fibers. The inner three layers all contain cellulosic pulp fibers, an aramid component and a polymeric binder. If desired, these inner layers may have different compositions. For example, relatively different amounts of cellulosic pulp fibers, an aramid component, and a polymeric binder can be included. This is because, in producing various layers, different raw material compositions can be supplied to the various cylinders corresponding to that layer. Similarly, if desired, it may have only one layer containing an aramid component and a polymeric binder. Thus, the remaining layers may consist primarily of cellulosic pulp fibers, or the relative amount of fibers / fibrids within the aramid component may vary.

  In another embodiment, the paper structure includes two outer layers consisting essentially of cellulosic pulp fibers, and the inner layer includes an aramid component and a polymeric binder. It is important that both the aramid component and the polymeric binder are present in at least one inner layer of the paper structure. As long as the two outer layers do not contain a polymeric binder, the composition of the remaining layers may be different.

  The preferred polymer binder is polyvinyl alcohol, but other polymer binders such as acrylic can also be used. The binder is added in the form of synthetic fibers or as a dry powder. When the binder is added as a fiber, it is important that the fiber has appropriate chemical properties. Polyvinyl alcohol fibers have a wide temperature range showing water solubility. The temperature at which the polymer is soluble depends on the properties of the polymer such as the degree of polymerization, the degree of hydrolysis and the crystallinity. This melting temperature can range from about 60 ° C. to over 100 ° C. It is important that this melting temperature is consistent with the paper manufacturing method. It is most effective if the polyvinyl alcohol fiber behaves as a binder while maintaining the shape of the fiber. Do not dissolve completely here. The strongest bond is obtained when the fiber surface just begins to melt. Upon subsequent drying, the polyvinyl alcohol fiber will adhere to all other fibers it contacts, whether synthetic or natural.

  This means that polyvinyl alcohol fibers with a low melting temperature should be used for low to medium basis weight paper (approximately 25 to 120 pounds per 3000 square feet) that is typically subjected to high speed machines. Because the machine is faster and the paper weight is lower, the paper is cooled by evaporation. The paper dries before it gets hot. Thus, the highest temperature reached by the paper is likely to be less than 70 ° C.

  For high basis weight paper (more than 200 pounds per 3000 square feet), polyvinyl alcohol fibers with higher melting temperatures can be used. This type of paper is generally run at a lower speed so that the paper temperature is higher.

  When using a powdery polyvinyl alcohol binder, it is necessary to hydrolyze the polymer completely (99% or more) and to grind it to a particle size of 100 mesh or less. The powder can be added to the wood fiber before refining, or it can be added to the system after refining. It is important to swell the powdered polymer after it has been added to the paper manufacturing system. The swelling time depends on the water temperature. In cold water (0-14 ° C.), a swelling time of about 1 hour is required. In warm water (40-50 ° C.), the particles swell in about 20 minutes. It is essential that the process water used in the case of polyvinyl alcohol fibers or powders does not exceed 60 ° C. This is because hot water dissolves the polymer and most of the adhesive properties are lost.

  For the polyvinyl alcohol binder powder, it is advantageous to use a steam shower. The shower needs to be applied to the paper before the drying process. The steam shower is particularly useful for low basis weight paper. This shower heats the paper while it is still wet, thus helping the outside of the swollen polymer particles begin to dissolve.

  In preparing the “veiled” embodiments of the present invention, it is possible and preferred to use a circular paper machine, as is well known in the art. In this circular paper machine, different layers can be created using different raw materials as described above, and thus a paper structure can be customized as needed within the scope of the present invention.

  A method for producing a bale-coated paper structure includes supplying a raw material composition substantially comprising wood pulp fibers to a cylinder corresponding to the outer layer. Thus, the two outer layers of the resulting paper structure consist essentially of cellulosic, preferably wood pulp fibers. A small amount of synthetic fiber may be included in these raw material compositions.

  The cylinder corresponding to the inner layer is then fed with a cellulosic pulp fiber and a raw material solution containing a selected aramid component and a polymeric binder, whether fiber, fibrid or a mixture of the two. . Thus, the inner layer of the paper structure contains cellulosic pulp fibers, an aramid component and a polymeric binder. The resulting paper structure is such that only the inner layer contains the polymeric binder and the outer layer does not contain them, and thus the polymeric binder is preferred due to high temperatures when drying the paper structure on a drying can. Adhesion problems that can arise due to activation of the are avoided. When the polymer binder is activated, the binder acts to bond the aramid component and the wood pulp fiber, but this occurs in the inner layer and does not cause sticking problems.

  The paper structure of the present invention provides a very useful paper as a high temperature paper for a transformer, whether it is a single layer or multiple layers. The paper has excellent heat resistance as well as excellent mechanical strength, and exhibits all the functions required as electrical insulating paper for transformers.

  Although the invention has been described in terms of a preferred embodiment, it is to be understood that changes and modifications are left to the artisan apparent. Such changes and modifications are to be considered within the scope and scope of the claims appended hereto.

Claims (18)

A paper structure comprising cellulosic pulp fibers, a polymeric binder, and an aramid component comprising aramid fibers and / or aramid fibrids. A paper structure comprising two outer layers and at least one inner layer, wherein the two outer layers are substantially composed of cellulosic pulp fibers, and the inner layer is the paper structure according to claim 1. The paper structure according to claim 1, wherein the polymer binder comprises polyvinyl alcohol. The paper structure of claim 1, wherein the aramid component comprises a mixture of aramid fibers and aramid fibrids. The paper structure according to claim 2, wherein the polymer binder contains polyvinyl alcohol. The paper structure according to claim 2, wherein the aramid component comprises a mixture of aramid fibers and aramid fibrids. The paper structure of claim 2, wherein the outer layer further comprises a small amount of synthetic fibers. A paper structure comprising two outer layers consisting essentially of cellulosic pulp fibers and at least two inner layers comprising a cellulosic pulp, a polymeric binder, and an aramid component comprising aramid fibers and / or aramid fibrids. A method of manufacturing a paper structure according to claim 1, comprising using a circular paper machine with at least three different cylinders, wherein the two outer layers of the resulting paper structure are substantially cellulose. A raw material composition consisting essentially of cellulosic pulp fibers is supplied to the cylinder corresponding to the outer layer, and the other cylinder has an inner layer of the paper structure comprising cellulosic pulp fibers, aramid A method comprising providing a raw material solution comprising cellulosic pulp fibers, aramid fibers, aramid fibrids and a polymer binder so as to comprise fibers, aramid fibrids and a polymer binder. Five cylinders are adopted, and a raw material solution consisting essentially of cellulosic pulp fibers is supplied to the cylinder corresponding to the outer layer of the paper structure, and cellulosic pulp fibers, aramid fibers, The method of claim 9, wherein a solution comprising aramid fibrid and a polymeric binder is provided. The method of Claim 9 that the polymer binder in the raw material solution supplied to the cylinder corresponding to an inner layer contains polyvinyl alcohol. A high-temperature transformer paper comprising the paper structure according to claim 1. A high-temperature transformer paper comprising the paper structure according to claim 2. A high-temperature transformer paper comprising the paper structure according to claim 3. A transformer comprising the paper of claim 1. A transformer comprising the paper according to claim 2. A transformer comprising the paper of claim 4. A transformer comprising the paper of claim 8.