RU2054721C1 - Line transformer - Google Patents

Abstract

FIELD: television. SUBSTANCE: line transformer has ferromagnetic core which carries frame fitted with connection panel with contacts on to which at least one low-voltage winding is applied. Sectionalized high-voltage winding which sections are put on separate cylindrical frames and insulated by mica tape applied on to each section is positioned over low-voltage winding. Tape is laid in one layer with overlapping in radial directions along generating lines of outer and inner surfaces of frame. It is put in similar manner over all sections taken together positioned in axial direction. Above tape insulation covering sections there is placed connection plate with diodes through which winding sections are connected in series. Frame with primary winding, frames with sections are connected in series. Frame with primary winding, frames with sections of high-voltage winding and connection plate are integrated as a unit with the use of impregnating compound which simultaneously enhances electric strength of mica tape. Invention provides for insertion of frame with variable resistors into transformer which is anchored on connection plate of transformer by means of compound which ensures insulation of diodes, variable resistors and output leads. Usage of elastic compound for this purpose makes it possible to replace these elements in case of failure. Mechanical and electric strengths of leads are achieved by fabrication of output leads of sections of high-voltage winding folded several times along length and wrapped in mica tape. Manufacture of ferromagnetic core from amorphous material makes it possible to decrease number of turns and consequently to diminish dimensions of transformer, to enhance adaptability to manufacture and save copper. EFFECT: increased electric strength, diminished dimensions and adaptability to manufacture. 5 cl, 5 dwg

Description

 The invention relates to television and can be used in line scan units of television receivers and video monitors.

 Known horizontal transformer [1] containing a ferromagnetic core on which a low-voltage winding is located, located on a cylindrical frame with ribs, above which a sectioned high-voltage winding is placed, sections of which are isolated from each other by the ribs of another cylindrical frame and a thermosetting compound that fills the cavities between the windings , sections and the housing in which the windings are located.

 The common essential features of the claimed device are the following features of the analogue: the presence of a ferromagnetic core on which the frame with at least one low-voltage winding is placed, a sectioned high-voltage winding located on top of the low-voltage winding, and the sections of the high-voltage winding are isolated from each other and from the low-voltage winding.

 In the known design, compactness and manufacturability are not achieved due to the presence of an external insulated casing, complex shaped frames, the difficulty of placing and winding windings on the frame. In addition, a sufficiently high dielectric strength is not ensured, since the casting compound used as insulation contains air bubbles and other local defects, has a relatively low dielectric strength, and does not fill point defective spots in the varnish insulation of winding wires.

 Known horizontal output transformer [2] containing a ferromagnetic core, on which there is a frame with ribs, with at least one low-voltage winding wound on it, over which sections of the high-voltage winding are concentrically located, each of which is insulated from the underlying winding by thin film insulation, tightly concentrically wound in several layers, and on the outside of the high-voltage winding, insulated concentrically with film insulation, there are diodes through which the sections okovoltnoy windings are connected in series.

 Among the features of this transformer, adopted as a prototype, coinciding with the essential features of the claimed device include the presence of a ferromagnetic core on which the frame is placed with at least one low-voltage winding wound on it, on which a sectioned high-voltage winding is located, the sections of which are isolated from a friend and from a low-voltage winding with film insulation, and from the outside of the high-voltage winding, diodes are located isolated from it, through which the high-voltage sections -voltage windings are connected in series.

 The prototype does not achieve a sufficiently high electric strength between the high-voltage and low-voltage windings, as well as between the sections of the high-voltage winding, between the last winding and the ferromagnetic core due to air gaps between the windings and the film insulation, especially along the edges of the windings along the layers and at the ends of the film insulation.

 The increased length of the sections of the high-voltage winding and the insulation edges between them, the need for additional insulation of the conclusions of the sections passing along the insulation edges through the ends of the sections, which leads to a significant increase in the thickness of the layers of the windings, does not allow to obtain sufficiently small dimensions of the transformer. The frameless concentric arrangement of the sections of the high-voltage winding on the primary winding does not allow the execution of sections of the high-voltage winding independent of the low-voltage winding, which negatively affects the processability.

 The purpose of the invention is the creation of a horizontal transformer with increased electrical strength, relatively small dimensions and high adaptability.

 The goal is achieved by the fact that in the scan transformer containing a ferromagnetic core, on which the frame is placed with at least one low-voltage winding wound on it, on which a sectioned high-voltage winding is located, the sections of which are isolated from each other and from the low-voltage winding by film insulation, and On the outside of the high-voltage winding, isolated from it, there are diodes through which sections of the high-voltage winding are connected in series, cylindrical frames of the sections are inserted, installing connected one after the other in the axial direction, on which the corresponding sections of the high-voltage winding are placed, a connecting panel with contacts, which is equipped with a low-voltage winding frame, a connecting board on which diodes are mounted, and a connecting tape that is wound on each high-voltage section is used as film insulation windings of at least one layer in radial directions along the generatrices of the outer and inner cylindrical surfaces of the frame of the corresponding section and similarly to Amotan for all sections of the high-voltage winding combined, while the frame with the low-voltage winding, the frames of the sections with the high-voltage winding and the connection board are combined into a single unit impregnating with a high-voltage compound.

 In addition, the connection board from the location of the diodes is filled with a compound, mainly elastic.

 Adjusting resistors are also introduced into the transformer, electrically connected to the terminals of the high-voltage winding, and the adjustment resistors are installed in a box-shaped case, which covers the connection board and is mounted on it with a compound, mainly elastic, filling the space between the connection board and the case.

 The findings of the sections of the high-voltage winding are made by a winding wire folded several times along its length, and wrapped with mica tape, as well as the implementation of a ferromagnetic core from atmospheric material.

 The introduction of sectional cylindrical frames to accommodate the sectioned high-voltage winding located axially one after another made it possible to isolate the high-voltage winding sections from each other, from the low-voltage winding and from the ferromagnetic core by winding mica tape on each cylindrical section frame in radial directions along the outer and the inner surfaces of the frame, followed by impregnation. This eliminates the inherent in the prototype reduced electric strength, consisting in the presence of air gaps along and along the edges of concentrically arranged windings, along the layers and at the ends of the film insulation wound on them.

 Winding mica tape on all sections of the high-voltage winding structurally combines and fixes their location along a common axis. Tape insulation, uniting the frame sections, increases the electrical strength and serves as an insulating base for the placement of the connection board on which the diodes are located.

 The use of mica tape as a film insulation made it possible to combine all structural elements into one, without any intermediate elements, using a high-voltage impregnating compound, which simultaneously increases the transformer's electrical strength both by increasing the electric strength of the mica tape subjected to impregnation, and as a result filling places of local defects in winding, interlayer and intersection isolation, as well as in varnish insulation of winding wires.

 Along with an increase in electrical strength, a reduction in the dimensions of the transformer is achieved due to the rejection of the concentrically arranged sections of the high-voltage winding used in the prototype, having an increased length of the windings and edges of the air and film insulation between them, as well as a significant thickness of the layers of the windings caused by additional insulation of the terminals passing along the insulation edges through the ends of the sections, and the transition to the structure with sections located on the frames mounted in a row in the axial direction and isolated lyudinitovoy both ribbon winding surface and side ends, in the claimed device.

 The design of the transformer makes it possible to increase manufacturability, since the low-voltage winding and sections of the high-voltage winding made on separate frames can be made independently of each other, and the combination of all structural elements is achieved as a result of one operation of impregnation with a high-voltage compound.

 Filling the connection board with a compound ensures isolation of the diodes and the leads of the high-voltage winding connected to them, and if the compound is elastic, the device maintains maintainability at the same time, due to the possibility of replacing failed diodes or output terminals.

 In the case when the transformer is equipped with adjusting resistors installed in a box-shaped case covering the connection board, an elastic compound introduced into the space between the connection board and the case secures the case with resistors on the transformer structure combined with the impregnating compound and at the same time provides isolation of diodes, resistors and associated electrical connections, compatible with maintainability, due to the possibility of replacing resistors, diodes and output terminals.

 The implementation of the findings of the sections of the high-voltage winding with a winding wire folded several times along its length and wrapped with mica tape increases the mechanical and electrical strength of the terminals.

 The implementation of the core of the transformer from an amorphous material, which, as is known, has several times greater magnetic permeability compared to frits, allows to reduce the number of turns (2-4 times), and therefore, reduce the dimensions of the transformer, increase manufacturability and save copper. The use of a core made of amorphous material has become possible in the inventive transformer, due to the design having increased electrical strength, which is necessary when placing the windings on the core of a material having high electrical conductivity on the housing.

 In FIG. 1, 2 shows a transformer, a General view; in FIG. 3, section AA in FIG. 1; in FIG. 4 its electrical circuit; in FIG. 5 shows a section of a high voltage winding.

 The horizontal scanning transformer contains a ferromagnetic core 1, which is formed of two U-shaped halves made of ferrite М2500 НМС1-20 (a ferromagnetic core can also be made of an amorphous alloy of the filemet type), and joined to a fixed gap placed on the core 1 of the frame 2 made of insulating material at the same time with the connecting panel 3 in the form of a base with contact pins 4. The connecting panel can also be made as a separate part connected to the frame 2, for example, with parts of the transformer impregnating compound. On the cylindrical surface of the frame 2, made smooth (without ribs), low-voltage windings 5 are wound (I, II, III in the electrical diagram of Fig. 4), which are located along the length of the frame in a row with a certain interval, but not wound along the length of the frame of the winding in the form of the next row, separated from the windings of the underlying row by a layer of tape insulation. The findings of the low voltage windings are connected to the pins 4, and the wires of the conclusions laid along the surface of the low voltage windings, being separated from it by a strip of tape insulation.

 On top of the frame 2 with low voltage windings there are three cylindrical frames of 6 sections, on which multilayer windings 7 of the corresponding sections of the high-voltage winding are wound, and polyethylene eterephthalate film is used as the interlayer insulation 8 (see Fig. 5). The winding 7 is wound with a deviation from the edge of the frame, and the interlayer insulation 8 is laid over the entire width of the frame in order to avoid breakdown between the layers along the edges of the winding.

It is possible to use mica tape as an interlayer insulation, however, it has a smaller electrical strength along the tape surface (in the width direction) than the film. Due to the smooth (without ribs) cylindrical surface of the frame of the low voltage windings and the frames of the sections of the high voltage winding, the placement of the windings on them is of technological simplicity. Each frame 5 with the winding 7 located on it is wrapped with a mica tape 9 overlapping along the generatrices of the external and internal cylindrical surfaces, covering the ends of the section in all radial directions. The number of layers of the mica tape is selected from the condition that the working gradient of the tape impregnated with epoxy high-voltage compound should be 13-17 mm ² . Frames with sections of the high-voltage winding are combined by common winding of mica tape 10 overlapping along the outer and inner surfaces of adjacent ends of the frames 6 with windings 7 covered with mica tape 9, with coverage of the ends of the first and third sections in all radial directions. This ensures a fixed arrangement of sections of the high-voltage winding along a common axis concentrically to the high-voltage windings. On top of the insulation 10, there is a connecting board 11 with contact tabs 12, to which the leads of the diodes 13, 14 are connected. The leads 15 of the sections of the high-voltage winding (see Fig. 2) to give them the mechanical strength of formation directly by the winding wire, folded several times along the length of the wires times (5-7 layers of wire), and for electrical strength they are wrapped with several layers 16 of mica tape overlapping, passed through holes in the connection board 11 and attached to the petals 12 to connect sections of the high-voltage winding through diodes 13 (see Fig. 1), as well as for connecting one free end of the high-voltage winding to the output diode 14, the other free end of the high-voltage winding of the case to the corresponding pin 4 on the connection panel.

 The frame 2 with low voltage windings, the frame 6 with sections of the high voltage winding connected by mica tape and the connection board 11 are integrated into a single impregnating epoxy high voltage compound. The impregnation is carried out in a vacuum-pressure way. By choosing the impregnation mode, the necessary mechanical and electrical strength of the transformer is achieved with the elimination of local insulation defects.

 The resulting design is supplemented by adjusting (variable) resistors 17 installed in a box-shaped case 18, which covers the connection board 11, and the series-connected resistors 17 are connected to the output ends of the high-voltage winding through the corresponding petals 12 on the board 11, and the insulated output wires are removed from the housing 18 conclusions for supplying high voltages to external devices (see Fig. 1, electrical circuit, conclusions A, O, F, Y), providing the ability to control variable resistors 17 focusing and accelerating stresses. At the same time, an elastic high-voltage compound 19 is introduced into the space enclosed between the connecting board 11 and the housing 18, due to which the housing with resistors is fixed to the structure connected by the impregnating compound and the insulation of all elements, contacts and connections enclosed in this space is ensured. The elasticity of the compound allows, if necessary, to replace diodes, resistors or repair damage in the switching circuits.

The use of cylindrical frames of a sectioned high-voltage winding, mica tape as insulation of sections from each other and from low-voltage windings and a core, winding mica tape in radial directions along the generatrix of the outer and inner cylindrical surfaces of the frame of each section, as well as sections combined, and the combination of all elements together with the help of an impregnating high-voltage compound allows, in comparison with the prototype, to increase the electric strength of the transformer. At the same time, a reduction in the dimensions of the structure and an increase in manufacturability are achieved. The proposed design has heat resistance and fire safety, as it is made on materials whose working temperatures are 120-140 ^about C.

Claims (5)

 1. LINEAR TRANSFORMER, comprising a ferromagnetic core on which a frame is arranged with at least one low voltage winding wound thereon, on which a sectioned high voltage winding is located, the sections of which are insulated one from the other and from the low voltage winding by film insulation, and on the outside of the high voltage the windings are isolated from it and from the environment, diodes are located through which sections of the high-voltage winding are connected in series, characterized in that they are introduced into it axial section frames mounted one after the other in the axial direction, on which the corresponding sections of the high-voltage winding are placed, a connection panel with terminal pins, which is equipped with a low-voltage winding frame, a connection board on which diodes are mounted, and film insulation is wound on each section of the high-voltage winding at least one overlap layer in radial directions along the generatrices of the outer and inner cylindrical surfaces of the frame of the corresponding section and is similar It is wound together on all sections of the high-voltage winding, moreover, the frame with the low-voltage winding, the frames of the sections with the high-voltage winding and the connection board are combined as a whole by the impregnating high-voltage compound.  2. The transformer according to claim 1, characterized in that the connection board from the location of the diodes is filled with a compound, mainly elastic.  3. The transformer according to claim 1, characterized in that the regulating resistors are introduced into the transformer, electrically connected to the terminals of the high-voltage winding, and the regulating resistors are installed in a box-shaped case, which covers the connection board and is fixed on it with a casting compound, mainly elastic, filling the space between the connection board and the housing.  4. The transformer according to claim 1, or 2, or 3, characterized in that the conclusions of the sections of the high-voltage winding are made by a winding wire folded several times along its length and wrapped with mica tape.  5. The transformer according to claim 1, or 2, or 3, or 4, characterized in that the ferromagnetic core is made of amorphous material.

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