KR20120015814A - Multi transformer and method of make it - Google Patents

Abstract

PURPOSE: A multi transformer and a method thereof are provided to improve the durability of a product by combining more than two lead pins into a conductive pattern and reducing heating of a man board and a multi-transformer. CONSTITUTION: A conductive pattern(210) is formed into a coil shape. A wire coil(220) is arranged between conductive patterns. An insulating member(230) is inserted between the conductive pattern and the wire coil. A mounting hole(310) corresponding to a ferrite core(100) is formed in the center of a mount(300) The mount comprises a lead pin(320) in which the conductive pattern and wire coil are linked.

Description

MULTI TRANSFORMER AND METHOD OF MAKE IT}

The present invention relates to a multi-transformer, and more particularly, a transformer composed of a ferrite core and a transformer means, the transformer is provided on the main board, the ferrite core is mounted in a mounting hole formed in the center and the transformer means is connected to the peripheral surface The present invention relates to a multi-transformer configured to include a mount having a plurality of lead pins to increase the production efficiency by simplifying the assembly process, and to reduce the defective rate when the transformer is mounted on the main board.

Transformers and inductors are well known electromagnetic devices used in electrical devices and power supply units. In general, electrostatic electromagnetic devices such as transformers and inductors have been made using windings of common wires having a circular cross section.

The conventional transformer has an insulation gap between the primary coil and the secondary coil, and the voltage generated in the secondary coil is determined by the voltage applied to the primary coil and the turns ratio between the primary coil and the secondary coil.

Fabrication of such conventional structures involves the winding of wires around the core or bobbin structure, which is often costly and manual.

In addition, as many electrical devices are miniaturized, the size of a transformer is also miniaturized. Accordingly, there are problems to be solved first, such as a new operation condition regarding a miniaturized circuit size and power density.

In order to solve the above problem, Planar Magnetic Components manufactured using a flexible circuit and a multilayer printed circuit board (PCB) have been introduced. Spiral conductors are printed on a printed circuit board and the width of the conductors depends on the current transfer requirements. In other words, if the current transfer requirement is large, the width of the conductor is also large. After printing the conductors in this manner, each printed circuit board is laminated and bonded with glass epoxy. A plurality of via holes are processed in the printed circuit board to connect the circuits.

In order to manufacture a transformer using the above-described printed circuit board, a printed circuit board, an insulator and a winding coil for inducing electromagnetic waves are laminated and manufactured by covering with a ferrite core, wherein the printed circuit board, the insulator and the winding coil are manufactured. There is a problem in that the defect rate of the product is high because the process of wiring through the via hole in the state of stacking the laminate or mounting the transformer thus manufactured to the electrical device is mainly performed by the above-mentioned manual work. And there is a problem that the production efficiency is lowered because the manufacturing process is delayed in the step of fixing to connect the winding coil and the like.

An object of the present invention is to provide a multi-transformer that is provided with a mount having a mounting hole in the center thereof to fix a ferrite core to simplify the manufacturing process of the transformer.

Another object of the present invention is provided with at least two fixing protrusions protruding downward from the periphery of the mounting hole to simplify the multi-transformer manufacturing process by fixing the ferrite core and the transformer means, mounting the multi-transformer on the motherboard It is to provide a multi-transformer to improve the stability while reducing the stability by fixing the position of the multi-transformer at the time or the ferrite core and the transformer means is separated from the surface of the main board.

Still another object of the present invention is to provide a multi-transformer that can be slimmed while being manufactured in a concentric shape in which the first pattern and the second pattern constituting the conductive pattern are bent in opposite directions to each other.

Still another object of the present invention is to provide a multi-transformer having improved durability by reducing heat generation of the main board or multi-transformer by connecting at least two lead pins to the conductive pattern.

As a means for achieving the above object of the present invention, the multi-transformer according to the present invention is a transformer provided on the main board is composed of a ferrite core and transformer means,

The transformer means may include at least two conductive patterns in a coil shape formed concentrically on a plane; A winding coil provided between the conductive patterns to generate an alternating magnetic flux; An insulating member inserted between the conductive pattern and the winding coil is laminated and provided in the ferrite core.

A mounting hole corresponding to the ferrite core is formed in the center, and a mount having a plurality of lead pins connected to the conductive pattern and the winding coil in a circumferential surface thereof.

In the present invention, the mount is provided with at least two fixing protrusions protruding downward from the circumference of the mounting hole is characterized in that for fixing the ferrite core.

In the present invention, the fixing projections, characterized in that the stepped support is further provided on the upper surface of the main board.

The conductive pattern may include: a first pattern having one end connected to any one of the lead pins provided on one side of the mount, and the other end bent in a concentric shape in a forward direction; And a second pattern, one end of which is electrically connected to the other end of the first pattern and the other end of which is bent in a concentric shape in a reverse direction so that one end of the first pattern of the lead pins is connected to a lead pin that is not connected. .

In addition, the method of manufacturing a multi-transformer according to the present invention comprises a ferrite core and a transformer means in the method for manufacturing a transformer provided on the main board,

Preparing the transformer means by stacking a coil-shaped conductive pattern and a winding coil and an insulating member inserted between the conductive pattern and the winding coil formed in a concentric circle on a plane;

Inserting a ferrite core provided with the transformer means into a mounting hole formed in the center of the mount, and connecting the conductive pattern and the winding coil to a lead pin provided on the circumferential surface of the mount; And

And soldering the conductive pattern to the winding coil by immersing the lead pin in liquid lead.

One of the lead pins is connected to one end of one of the conductive patterns, and a lead pin not connected to one end of the conductive patterns among the lead pins connects the other end of the conductive patterns. Lead pins that are not connected to the conductive pattern among the lead pins are respectively connected to one end and the other end of the winding coil.

In the present invention, in the step of connecting the conductive pattern and the winding coil, protruding downward from the periphery of the mounting hole, the lower portion is provided with at least two fixing projections having a stepped step is inserted into the mounting hole ferrite core It characterized in that to fix.

In addition, in the preparing of the transformer means, one end of the conductive pattern is connected to any one of the lead pins provided on one side of the mount, and the other end of the first pattern is curved in a concentric shape in the forward direction, and one end It is electrically connected to the other end of the first pattern, the other end is bent in a concentric circular shape in the reverse direction characterized in that consisting of a second pattern connected to one of the lead pin one end of the first pattern is not connected .

First, the present invention has an effect of simplifying the manufacturing process of the transformer by fixing the ferrite core is provided with a mount having a mounting hole formed in the center.

Second, the present invention is provided with at least two fixing projections protruding downward from the periphery of the mounting hole to simplify the multi-transformer manufacturing process by fixing the ferrite core and the transformer means, multi when mounting the multi-transformer on the motherboard By fixing the position of the transformer or by allowing the ferrite core and the transformer to be spaced apart from the surface of the main board, there is an effect of increasing stability and reducing defects.

Third, the present invention is manufactured in a concentric shape in which the first pattern and the second pattern constituting the conductive pattern are bent in opposite directions to each other, thereby making it possible to slim down while manufacturing at various transformer ratios.

Fourth, the present invention is provided with a plurality of lead pins on the circumferential surface of the mount, it is possible to easily connect the transformer means, there is also an effect that can be easily mounted by immersing the portion with the lead pin in the liquid lead.

Fifth, another object of the present invention is that at least two lead pins are connected to the conductive pattern, thereby reducing heat generation of the main board or multi-transformer, thereby improving durability of the product.

1 is a view showing the configuration of a multi-transformer according to the present invention.
Figure 2 is a perspective view of the top of the multi-transformer according to the present invention.
Figure 3 is a perspective view showing the back of the multi-transformer according to the present invention.
4 is a view showing the back of the multi-transformer according to the present invention.
5 is a side view showing a multi-transformer according to the present invention.
6 is a cross-sectional view taken along the line AA ′ of FIG. 4.
7 is a front view showing a multi-transformer according to the present invention.
8 is a flowchart illustrating a method of manufacturing a multi-transformer according to the present invention.
9 is a perspective view showing another embodiment of a multi-transformer according to the present invention.
10 is a plan view showing another embodiment of a multi-transformer according to the present invention.
11 is a front view showing another embodiment of a multi-transformer according to the present invention.

Hereinafter, a multi-transformer and a method of manufacturing the same according to the present invention will be described with reference to FIGS. 1 to 11.

1 to 7, an embodiment of the multi-transformer 10 according to the present invention will be described, the transformer is composed of a ferrite core 100 and the transformer means 200 is provided on the main board (not shown) In one embodiment, at least two conductive patterns 210 are provided in a coil shape, and a winding coil 220 provided between the conductive patterns 210 and a gap between the conductive patterns 210 and the winding coils 220. The transformer member 200 is formed by stacking the insulating member 230 in the ferrite core 100 and a mounting hole 310 corresponding to the ferrite core 100 is formed at the center thereof. The mount 300 includes a mount 300 having a plurality of lead pins 320 to which the conductive pattern 210 and the winding coil 220 are connected.

The main board is provided in a conventional electric device (not shown) to control the electric device, which is already well known and known, and thus detailed description thereof will be omitted.

The ferrite core 100 includes an upper core 110 and a lower core 120 as shown in FIG. 1 to simplify the manufacturing process of the multi-transformer 10.

The ferrite core 100 by molding the core using a material called ferrite, can be used in the hertz (Hz) to several tens of hertz (Hz), the size is smaller than the capacity due to the high frequency band available It can be light and low loss rate to reduce the eddy current loss at high frequency, which is a well known technique already known, the detailed description thereof will be omitted.

The transformer 200 has a coil shape formed concentrically on a plane and is provided between at least two conductive patterns 210 and a winding coil 220 provided between the conductive patterns 210 to generate alternating magnetic flux. And an insulating member 230 inserted between the conductive pattern 210 and the winding coil 220 is stacked inside the ferrite core 100.

The conductive pattern 210 is a circuit in which a primary current or a secondary current flows, and is curved in a concentric shape from one side to the other side on the same plane.

Referring to the conductive pattern 210 in more detail with reference to Figure 1, the conductive pattern 210, one end is connected to any one of the lead pin 320 provided on one side of the mount 300 The other end is first pattern 211 is curved in a concentric shape in the forward direction, one end is electrically connected to the other end of the first pattern 211, the other end is concentric in a reverse direction corresponding to the first pattern 211 The second pattern 212 is bent to one end of the first pattern 211 of the lead pin 320 is connected to the lead pin 320 is not connected.

The first pattern 211 and the second pattern 212 may be manufactured by bending a bar-shaped conductive wire, but in the present invention, a mold of the first pattern 211 and the second pattern 212 may be manufactured. It is preferable to make mass production possible by manufacturing by a press process.

The winding coil 220 is provided between the conductive pattern 210 provided at the top and the bottom of the winding coil 220 to generate an electromagnetic induction phenomenon. For example, when a primary current flows through the conductive pattern 210 positioned above the winding coil 220, magnetic flux is generated by the primary current in the winding coil 220, and the winding coil is generated by the magnetic flux generated therein. In the conductive pattern 210 positioned below the 220, the magnetic flux is generated in a direction that prevents the change of the magnetic flux caused by the primary current so that the electromotive force is generated and the current flows.

In this case, the secondary current with respect to the primary current is proportional to the number of turns of the conductive pattern 210, and this is called a transformer ratio, and the winding coil 220 is a well-known conventional technique and will not be described in detail. Shall be.

The insulating member 230 is disposed between the ferrite core 100 and the conductive pattern 210, between the conductive pattern 210 and the winding coil 220, and the first pattern 211 and the second pattern. In the embodiment of the present invention, the insulating paper made of paper material is used as provided between 212 and electrically spaced apart from each other, but an insulator capable of expecting the same effect may be used.

The mount 300 has a mounting hole 310 corresponding to the ferrite core 100 at the center thereof, and a plurality of lead pins 320 are provided at the circumferential surface thereof.

The lead pin 320 is preferably made of a conductive material as the conductive pattern 210 and the winding coil 220 are connected. In addition, as shown in Figure 5, extending from the circumferential surface of the lead pin 320 in a direction perpendicular to the conductive pattern 210 to simplify the manufacturing process of the multi-transformer 10 according to the present invention It is preferable that the details thereof will be described later.

Part of the mount 300 except for the lead pin 320 is preferably made of a non-conductive material for the electrical stability of the multi-transformer 10 according to the present invention.

At least two fixing protrusions 330 protruding downwardly are provided around the mounting hole 310 to fix the ferrite core 100.

A step 331 is formed below the fixing protrusion 330 to prevent the ferrite core 100 from contacting the surface of the main board when the multi-transformer 10 is mounted on the main board. The electrical stability of the main board and the multi-transformer 10 is improved.

Referring to Figures 9 to 11 another embodiment of the multi-transformer 10 according to the present invention, a transformer composed of a ferrite core 100 and the transformer means 200 provided on the main board, in the coil shape At least two conductive patterns 210 and the winding coil 220 provided between the conductive pattern 210 and the insulating member 230 inserted between the conductive pattern 210 and the winding coil 220. ) Is formed in the transformer means 200 is stacked in the ferrite core 100, the mounting hole 310 corresponding to the ferrite core 100 is formed in the center, the conductive pattern ( 210 includes a multi-transformer 10 that includes a mount 300 having a plurality of lead pins 320 to which the winding coil 220 is connected.

Here, the conductive pattern 210, one end is connected to at least two or more lead pins 320 of the lead pins 320 provided on one side of the mount 300, the other end is bent in a concentric shape in the forward direction Losing the first pattern 211 and one end is electrically connected to the other end of the first pattern 211, the other end is bent in a concentric shape in the opposite direction so that one end of the first pattern 211 of the lead pin 320 The second pattern 212 is connected to at least two lead pins 320 which are not connected.

In one embodiment of the present invention, in order to reduce the depth of the mounting hole 310 in which the ferrite core 100 is mounted, that is, the thickness of the mount 300 in order to slim down the multi-transformer 10, the mount ( The circumferential area of the mount 300 fixing the lead pin 320 coupled to the circumferential surface of 300 may decrease, which may damage the mount 300. Accordingly, the damage of the mount 320 can be prevented by reducing the thickness of the lead pin 320, but heat is generated when current flows through the thin lead pin 320, so that not only the transformer means 200 but also the main board The electrical stability of the is reduced, there is a problem that the durability of the multi-transformer 10 is also reduced.

Therefore, in another embodiment of the multi-transformer 10 according to the present invention by connecting two lead pins 320 on both sides of the conductive pattern 210 as described above, the conductive pattern 210 and the lead pin ( Increasing the contact area of the 320 may reduce the heat generation phenomenon.

The lead pins 320 connected to the conductive patterns 210 are not limited in thickness or the number of wires connected to the conductive patterns 210 according to the current input or output to the multi-transformer 10 according to the present invention. Various implementations are possible.

Hereinafter, an embodiment of a method of manufacturing the multi-transformer 10 according to the present invention will be described with reference to FIG. 8. In the method for manufacturing a transformer provided on the main board consisting of the ferrite core 100 and the transformer means 200, the coil-shaped conductive pattern 210 and the winding coil 220 formed in a concentric circle on a plane and the Stacking the insulating member 230 inserted between the conductive pattern 210 and the winding coil 220 to prepare the transformer means 200, and in the mounting hole 310 formed in the center of the mount 300. Inserting a ferrite core 100 having a transformer means 200, and connecting the conductive pattern 210 and the winding coil 220 to the lead pin 320 provided on the circumferential surface of the mount 300 And, the lead pin 320 includes a step of immersing the solder in a liquid lead.

In the preparing of the transformer unit 200, one end of the conductive pattern 210 is connected to one of the lead pins 320 provided on one side of the mount 300, and the other end thereof has a concentric shape in a forward direction. The curved paper is first lead 211, one end is electrically connected to the other end of the first pattern 211, the other end is bent in a concentric shape in the opposite direction to the bending direction of the first pattern 211 and the lead pin The second pattern 212 is connected to one of the lead pins 320 to which one end of the first pattern 211 is not connected.

Herein, the other end of the first pattern 211 electrically connected to the second pattern 212 except for one end of the second pattern 212 may be electrically spaced between the first pattern 211 and the second pattern 212. The insulating member 230 is inserted into the.

In the present invention, the winding coil 220 is manufactured by winding the coated wire several times, and in order to prevent the winding coil 220, which is wound several times in a donut shape, from being unwound with an assortment or an insulating tape, the winding coil It is preferable to attach so as to wrap perpendicularly to the winding direction of 220.

As described above, when the conductive pattern 210, the winding coil 220, and the insulating member 230 are prepared, they are assembled as follows.

Turn the mount 300 upside down so that the lower portion of the lead pin 320 and the fixing protrusion 330 is upward to insert the upper core 110. At this time, the upper core 110 is also inserted so that the upper surface is turned upside down.

Next, the insulating member 230, the conductive pattern 210, and the winding coil 220 are stacked on the inverted upper core 110, and the conductive pattern 210 and the insulating member are stacked on the winding coil 220. Finally, the lower core 120 is stacked upward and then the lower core 120 and the upper core 110 are coupled to each other.

In this case, the conductive patterns 210 disposed on the upper and lower portions of the winding coil 220 may include a winding number differently manufactured so that a secondary current (output voltage) having a different size from the primary current (input voltage) is output. Is preferred.

 In the present invention, the conductive pattern 210 may be manufactured as a single winding transformer in which the primary current and the secondary current use one conductive pattern 210, but this is only one embodiment. By increasing the number of stacked layers 210, secondary currents of various sizes may be output.

When the conductive pattern 210 is connected to the lead pin 320, any one of the lead pins 320 is connected to one end of any one of the conductive patterns 210 and the lead pin 320 The lead pins 320, which are not connected to one end of the conductive patterns 210, connect the other ends of the conductive patterns 210 to the conductive patterns 210 of the lead pins 320. Lead pins 320 that are not connected are connected to one end and the other end of the winding coil 220, respectively.

Referring to FIG. 1, for example, in the case of the conductive pattern 210 positioned below the winding coil 220, one end of the first pattern 211 may be formed on a lead pin (one side of the mount 300). The lead pin 320 is connected to any one of the 320, the other end of the second pattern 212 is connected to one end of the first pattern 211 of the lead pin 320 located on one side of the mount 300 Is connected to any one of the lead pins 320.

In addition, in the case of the conductive pattern 210 positioned above the winding coil 220, one end of the first pattern 211 may be wound coil 220 among the lead pins 320 disposed on one side of the mount 300. ) Is connected to any one of the lead pins 320 except for the lead pin 320 connected to the conductive pattern 210, and the other end of the second pattern 212 is positioned under the winding coil 220. The other end of the second pattern of the conductive pattern is connected to the lead pin 320, such as lead pin 320 is connected.

The winding coil 220 is connected to the lead pin 320 located on the other side of the mount 300, when the winding coil 220 is connected to the lead pin 320 to cover the coating of the winding coil 220 The winding coil 220 is wound around the lead pin 320 without being peeled off and fixed to the lead pin 320 without being peeled off.

Finally, the lead pin 320 located on one side of the mount 300 and the lead pin 320 located on the other side are immersed in the liquid lead heated to a high temperature, and at this time, the coating of the winding coil 220 While melting, the winding coil 220 and the lead pin 320 are electrically connected by lead.

As such, by using the multi-transformer 10 according to the present invention and a method of manufacturing the same, when the multi-transformer 10 is manufactured, the ferrite core (B) may be due to the mounting hole 310 and the fixing protrusion 330. When the assembly 100 and the transformer means 200 is assembled, the ferrite core 100 and the transformer means 200 are prevented from flowing, and the assembly of the completed multi-transformer 10 is immersed in a liquid lead to make a simple soldering process. The process is simplified.

In addition, when the manufactured multi transformer 10 is installed on the main board, the multi transformer 10 may be installed before mounting the multi transformer 10 on the main board due to the step 331 formed in the fixing protrusion 330. ) Is prevented from flowing, and by preventing the ferrite core 100 from contacting the surface of the main board, it is possible to improve electrical stability and reduce defects.

In addition, the multi-transformer 10 and the main board generate heat when the thickness of the lead pin 320 is reduced in order to reduce the durability of the mount 300 while slimming the multi-transformer 10. Can be prevented from being damaged.

The present invention is not limited to the above-described specific preferred embodiment, and any person having ordinary skill in the art to which the present invention pertains may make various modifications without departing from the gist of the present invention as claimed in the claims. Of course, such changes will fall within the scope of the claims.

10: multi transformer
100: ferrite core 110: upper core
120: lower core
200: transformer means 210: conductive pattern
211: first pattern 212: second pattern
220: winding coil 230: insulation member
300: mount 310: mounting hole
320: lead pin 330: fixing protrusion
331: step

Claims (10)

In the transformer composed of a ferrite core and the transformer means provided on the main board,
The transformer means,
The ferrite is a coil shape formed concentrically on a plane and includes at least two conductive patterns, a winding coil provided between the conductive patterns to generate an alternating magnetic flux, and an insulating member inserted between the conductive patterns and the winding coils. Are stacked and provided inside the core,
A mounting hole corresponding to the ferrite core is formed in the center, and a mount having a plurality of lead pins connected to the conductive pattern and the winding coil in a circumferential surface thereof. The method of claim 1, wherein the mount,
And at least two fixing protrusions protruding downward from the circumference of the mounting hole to fix the ferrite core. The method of claim 2, wherein the fixing projections,
A multi-transformer, characterized in that a stepped support is further provided on the upper surface of the main board at the bottom of the fixing projections. The method of claim 1, wherein the conductive pattern,
A first pattern, one end of which is connected to any one of the lead pins provided on one side of the mount, and the other end of which is bent in a concentric shape in a forward direction; And
One end is electrically connected to the other end of the first pattern, and the other end is bent in a concentric shape in a reverse direction, so that one end of the first pattern of the lead pins is connected to an unconnected lead pin; Multi transformer. The method of claim 1, wherein the conductive pattern,
A first pattern, one end of which is connected to at least two or more lead pins of the lead pins provided on one side of the mount, and the other end of which is bent in a concentric shape in a forward direction; And
A second pattern, one end of which is electrically connected to the other end of the first pattern and the other end of which is bent in a concentric shape in a reverse direction so that one end of the first pattern of the lead pins is connected to at least two or more lead pins which are not connected; Multi-transformer, characterized in that configured. In the method for manufacturing a transformer comprising a ferrite core and transformer means, which is provided on the main board,
Preparing the transformer means by stacking a coil-shaped conductive pattern and a winding coil and an insulating member inserted between the conductive pattern and the winding coil formed in a concentric circle on a plane;
Inserting a ferrite core provided with the transformer means into a mounting hole formed in the center of the mount, and connecting the conductive pattern and the winding coil to a lead pin provided on the circumferential surface of the mount; And
And immersing the lead pin in liquid lead;
One of the lead pins is connected to one end of one of the conductive patterns, and a lead pin not connected to one end of the conductive patterns among the lead pins connects the other end of the conductive patterns. Lead pins that are not connected to the conductive pattern of the lead pins are connected to one end and the other end of the winding coil, respectively. According to claim 6, In the step of preparing the transformer means,
One end of the conductive pattern is connected to any one of the lead pins provided on one side of the mount, the other end of the first pattern is curved in a concentric shape in the forward direction, and one end is electrically connected to the other end of the first pattern And the other end is bent in a concentric shape in a reverse direction so that one end of the first pattern of the lead pins is connected to a lead pin which is not connected. In the method for manufacturing a transformer comprising a ferrite core and transformer means, which is provided on the main board,
Preparing the transformer means by stacking a coil-shaped conductive pattern and a winding coil and an insulating member inserted between the conductive pattern and the winding coil formed in a concentric circle on a plane;
Inserting a ferrite core provided with the transformer means into a mounting hole formed in the center of the mount, and connecting the conductive pattern and the winding coil to a lead pin provided on the circumferential surface of the mount; And
And immersing the lead pin in liquid lead;
At least two lead pins of the lead pins are connected to one end of any one of the conductive patterns, and at least two lead pins not connected to one end of the conductive patterns among the lead pins are connected to the other end of the conductive patterns. And a lead pin that is not connected to the conductive pattern among the lead pins is connected to one end and the other end of the winding coil, respectively. According to claim 8, In the step of preparing the transformer means,
The conductive pattern has one end connected to at least two or more lead pins of the lead pins provided on one side of the mount, the other end of which is bent in a concentric shape in the forward direction, and one end of which is electrically connected to the other end of the first pattern. Connected to each other, and the other end is bent in a concentric shape in a reverse direction, and the second pattern is connected to two or more lead pins of which one end of the first pattern is not connected. . The method of claim 7 or 9, wherein in the step of connecting the conductive pattern and the winding coil,
Protruding downward from the periphery of the mounting hole, the lower portion is provided with at least two fixing projections having a stepped step of manufacturing a multi-transformer, characterized in that for fixing the ferrite core inserted into the mounting hole.

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