JP3113691U - Digital broadcast receiver having a shield structure - Google Patents

Abstract

【Task】
The present invention provides a digital broadcast receiver having a shield structure excellent in heat dissipation of heat-generating components mounted on a circuit board and excellent in shielding of electromagnetic noise.
[Solution]
A digital circuit control microcomputer 20 which is a heat generating component is mounted on the digital circuit board 12 covered with a shield case 30 electrically coupled to the ground, and comes into contact with the heat radiating member 40 mounted on the surface of the microcomputer 20 to thereby shield the shield. A plate spring 41 is also provided that contacts the inside of the case 30 to dissipate the heat of the microcomputer 20 from the heat radiating member 40 to the shield case 30 via the plate spring 41, and the microcomputer 20 mounted on the substrate 12 is transferred to the substrate 12. A shield plate 43 is provided to cover from the back side of the substrate, and a conductive cushion 42 is provided in contact with the shield plate 43 and the shield case 30 to shield electromagnetic noise radiated from the microcomputer 20 and escape to the ground.
[Selection] Figure 8

Description

  The present invention relates to a digital broadcast receiver having a shield structure excellent in heat dissipation of heat-generating components mounted on a circuit board and excellent in shielding of electromagnetic noise.

  Conventionally, a digital board provided in a digital broadcast receiving apparatus such as a digital TV is called a card slot into which a digital control unit such as a digital circuit control microcomputer mounted on the digital board or a card for receiving a billing broadcast is mounted. It was known that the card mounting part generated heat. In addition, when the digital board is electrically connected, the digital control unit, the card mounting unit, and the like have the property of radiating high-frequency electromagnetic noise. For example, the power source unit, the video / audio signal generation unit, the horizontal / vertical deflection Proximity to these circuit boards that make up analog circuits, such as the main board that forms and arranges parts, AV (Audio and Visual) boards that form and arrange input / output control units, and the electronic components that radiate electromagnetic noise As a result, it is often possible to interfere with various electronic components that are mounted in such a way that a metal shield case is used to wrap the digital board on which these electronic components are mounted. It was broken.

  However, wrapping it in a shield case causes the heat from the heat generating parts such as the digital control unit and card mounting part to rise in the shield case, resulting in a high temperature, and malfunction of these heat generating parts and other electronic components mounted in the vicinity. In order to dissipate heat, a heat radiating member having a plurality of heat radiating fins called a heat sink is attached to the heat generating component to dissipate heat. Alternatively, in order to dissipate heat to the outside of the shield case, measures against unnecessary radiation of heat and electromagnetic noise generated from the heat-generating component are taken by forming a vent hole in the shield case.

  As related to such background art, for example, in the “semiconductor element shield device” of Patent Document 1, a heat radiating member having a plurality of heat radiating fins is mounted on the surface of a semiconductor element serving as a heat-generating component, A method of dissipating heat from a radiation fin exposed to the outside of a shield case by covering a generally box-shaped shield member having an exposed hole penetrating the radiation fin from above is disclosed.

Japanese Unexamined Patent Publication No. Hei 8-279689

  However, the above-described conventional technology tends to reduce the electromagnetic resistance of the semiconductor chip itself in a situation where further high-density mounting of the circuit board and miniaturization, miniaturization, and power saving of the semiconductor chip constituting the electronic component are advanced. Therefore, these electromagnetic wave noise countermeasures and heat radiation countermeasures are not sufficient.

  Also, according to the above-mentioned Patent Document 1, it is necessary to ensure a predetermined positional accuracy between the semiconductor element mounted on the circuit board and the exposed hole opened in the shield case by providing a plurality of exposed holes in the shield case. In addition, when the design of the position of the semiconductor element arranged on the circuit board is to be changed, there is a problem that the press die for forming the shield case needs to be modified or remade.

  Accordingly, the present invention has been made in view of the above problems, and further improves countermeasures against electromagnetic wave noise and heat dissipation, and shields that can easily cope with the necessity of design changes in circuit boards. An object of the present invention is to provide a digital broadcast receiving apparatus having a structure.

  A digital broadcast receiving apparatus having a shield structure according to claim 1 is a digital broadcast receiving apparatus including a shield case that encloses at least a digital circuit block formed on a circuit board and is electrically coupled to a ground. A heat dissipating piece that is in contact with a metal heat dissipating member that is thermally coupled to the surface of the digital circuit controller mounted on the circuit block and that also contacts the inside of the shield case is provided between the heat dissipating member and the shield case. It is characterized by being provided in.

  According to the first aspect of the present invention, electromagnetic wave noise radiated from at least the digital circuit block formed on the circuit board and wrapped in the shield case is shielded by the shield case electrically coupled to the ground. Further, the heat radiation piece that contacts the heat radiation member made of metal thermally coupled to the surface of the digital circuit control unit mounted on the digital circuit block and also contacts the inner side of the shield case is connected to the heat radiation member and the shield case. The heat generated in the digital circuit controller is conducted to the shield case through the heat dissipation member thermally coupled to the surface of the digital circuit control unit, and the heat dissipation piece in contact with the heat dissipation member and the shield case. Heat can be radiated from the surface to the outside.

  3. A digital broadcast receiving apparatus having a shield structure according to claim 2, wherein the digital broadcast receiving apparatus having the shield structure according to claim 1 includes a shield plate that covers a digital circuit control unit mounted on the circuit board. The shield plate is disposed between the shield plate and the shield case, and the shield plate is connected to the ground pattern formed on the circuit board and is also in contact with the inner side of the shield case. It is characterized by.

  According to the configuration of the second aspect, the electromagnetic wave noise radiated from the digital circuit control unit is shielded by the shield plate, and the shield plate is electrically coupled to the ground pattern of the circuit board and radiated from the digital circuit control unit. Electromagnetic wave noise that flows into the ground pattern of the circuit board can be effectively released from the shield case to the ground by the shield piece in contact with the shield plate.

  The digital broadcast receiving apparatus having the shield structure according to claim 3 is the digital broadcast receiving apparatus having the shield structure according to claim 1, wherein an attachment piece is formed on an inner surface side of the shield case, and the attachment piece is used as the circuit. In addition to being electrically connected to the ground pattern of the substrate, the mounting piece and the heat radiating member are contacted directly or indirectly through a conductive member.

  According to the configuration of the third aspect, the electromagnetic wave noise radiated from the digital circuit control unit is shielded by the shield case, and the electromagnetic wave noise radiated from the digital circuit control unit is electrically connected to the ground pattern of the circuit board by the mounting piece. It is possible to escape to the ground pattern of the circuit board and to effectively escape the electromagnetic noise from the shield case to the ground via the mounting piece.

  A digital broadcast receiver having the shield structure according to claim 4 is the digital broadcast receiver having the shield structure according to claim 3, wherein a connection terminal connected to an external device is mounted on the circuit board, and the shield case is mounted. Is provided with a component insertion hole for leading the connection terminal to the outside, and a ground pattern of the circuit board is provided with a through hole of the mounting piece, and the direction of the through hole and the insertion direction of the connection terminal with respect to the component insertion hole, Characterized by matching.

  According to the configuration of the fourth aspect, when the circuit board is assembled in the shield case, the connection terminal that is mounted on the circuit board while the mounting piece integrally formed on the shield case is passed through the ground pattern of the circuit board is provided in the insertion hole of the shield case. It is possible to smoothly lead out to the outside.

  The digital broadcast receiving apparatus having the shield structure according to claim 5 is the digital broadcast receiving apparatus having the shield structure according to claim 1 or 2, wherein the circuit board is a digital circuit control unit mounted on the circuit board. The mounting surface side is provided with a card mounting portion for mounting a card capable of receiving a billing broadcast, and a cooling fan is provided in a shield case near the card mounting portion.

  According to the configuration of claim 5, the circuit board is provided with a card mounting part for mounting a card capable of receiving a billing broadcast on the mounting surface side of the digital circuit control unit mounted on the circuit board. By providing the cooling fan in the shield case in the vicinity of the mounting part, both the card mounting part and the digital circuit control part can be cooled by the cooling air generated by the cooling fan.

  The digital broadcast receiving device having a shield structure according to claim 6 is the digital broadcast receiving device having the shield structure according to any one of claims 1 to 3, wherein the heat dissipating piece and the shield piece are made of metal. It is a leaf spring made of metal.

  According to the structure of Claim 6, the said heat radiating piece and the said shield piece are the synthetic resin members which have electroconductivity and heat conductivity, and are elastic, or are rubber members, or metal leaf | plate springs. Thus, the heat radiation piece that urges the pressure by elasticity and has thermal conductivity can contact the heat radiation member and the shield case and reliably conduct the heat generated by the digital circuit control unit to the shield case. Further, the shield piece that energizes the pressing and has conductivity can securely connect the shield plate and the shield case electrically coupled to the ground.

  The digital broadcast receiving device having a shield structure according to claim 7 is the digital broadcast receiving device having a shield structure according to any one of claims 2 to 6, wherein the outer periphery of the shield plate has an edge thereof. Folded to the circuit board side.

  According to the configuration of claim 7, the outer periphery of the shield plate is bent at its edge toward the circuit board, so that no sharp edge is formed on the outer periphery of the shield plate, and electromagnetic noise is radiated from the sharp edge. Can be prevented. In addition, since the outer periphery of the shield plate is merely bent at the edge, a sufficient gap between the shield plate and the circuit board can be secured.

  According to the first aspect of the present invention, the digital broadcast receiver having the shield structure is formed on the circuit board, and at least electromagnetic noise radiated from the digital circuit block enclosed in the shield case is electrically coupled to the ground. Since the shield case is effectively shielded, the digital circuit block and the analog circuit block are formed and arranged on one circuit board. Alternatively, an analog board such as a main board or an AV board is formed and arranged close to the digital board, so that various electronic parts mounted on the digital circuit block and close to the electronic parts that radiate electromagnetic noise are Interference with the analog circuit block and the analog substrate can be prevented. In addition, a heat dissipating piece that is in contact with the heat dissipating member that is thermally coupled to the surface of the digital circuit control unit mounted on the digital circuit block and that also contacts the inside of the shield case is provided between the heat dissipating member and the shield case. The heat generated in the digital circuit control unit is conducted to the shield case through the heat radiation member thermally coupled to the surface and the heat radiation piece contacting the heat radiation member and the shield case. Since heat can be dissipated, it is possible to prevent the digital circuit control unit and other electronic components constituting the digital circuit from overheating and malfunctioning due to heat generated in the shield case. I can do it. In addition, the heat dissipating piece is provided between the heat dissipating member and the shield case, so that it is necessary to change the design of the position of the digital circuit control unit disposed on the digital board. It is only necessary to change the mounting position of the piece, and there is no need to modify or remodel the press die forming the shield case.

  According to the invention of claim 2, the circuit board has a shield plate disposed so as to cover the digital circuit control unit mounted on the circuit board from the back surface of the circuit board, and the shield board is formed on the circuit board. By connecting a shield piece that is connected to the ground pattern and is also in contact with the inside of the shield case between the shield plate and the shield case, electromagnetic wave noise radiated from the digital circuit control unit is caused by the shield piece. It escapes to the ground pattern formed on the circuit board, is effectively primary shielded by a shield plate electrically coupled to the ground of the shield case, is secondarily shielded by a shield case electrically coupled to the ground, and I can miss it to the ground. Therefore, the digital circuit control unit can effectively radiate and cool the heat from the front surface in the shield case, and can effectively shield the electromagnetic noise from the back surface. Furthermore, the shield piece is provided between the shield plate and the shield case, and when it is necessary to change the design of the position of the digital circuit control unit etc. disposed on the circuit board, the shield piece It is only necessary to change the mounting position of the piece, and there is no need to modify or remodel the press die forming the shield case.

  According to the invention of claim 3, the mounting piece is formed on the inner surface side of the shield case, the mounting piece is electrically connected to the ground pattern of the circuit board, and the mounting piece and the heat dissipation member are directly connected. Alternatively, the electromagnetic wave radiation radiated from the digital circuit control unit is shielded by the shield case by being indirectly contacted through the conductive member, and the electromagnetic wave noise radiated from the digital circuit control unit is connected to the ground pattern of the circuit board. It is possible to escape to the ground pattern of the circuit board by the electrically coupled mounting piece, and to effectively escape the electromagnetic noise from the shield case to the ground via the mounting piece. In addition, the number of parts to be assembled can be reduced, and the manufacturing process and the assembly work can be simplified by reducing the number of parts, and the productivity is excellent.

  According to the invention of claim 4, a connection terminal for connecting to an external device is mounted on the circuit board, and a component insertion hole for leading the connection terminal to the outside is provided in the shield case, and a ground pattern of the circuit board is provided. Is provided with a through hole of the mounting piece, and when the circuit board is assembled to the shield case, the component insertion to be formed in the shield case is made by matching the direction of the through hole with the insertion direction of the connection terminal with respect to the component insertion hole. Since the attachment piece formed in the shield case can be smoothly inserted into the through hole while being inserted into the connection terminal mounted on the circuit board in the hole, the assembling workability is excellent.

  According to the invention of claim 5, the circuit board is provided with a card mounting part for mounting a card capable of receiving a billing broadcast on the mounting surface side of the digital circuit control part mounted on the circuit board. By providing a cooling fan in the shield case near the mounting part, both the card mounting part and the digital circuit control part can be cooled by the cooling air generated by the cooling fan. The cooling efficiency can be greatly improved.

  According to the invention of claim 6, the heat dissipating piece and the shield piece are a synthetic resin member, a rubber member, or a metal leaf spring having conductivity and thermal conductivity and having elasticity. Therefore, the heat radiating piece that urges the pressing and has thermal conductivity is in contact with the heat radiating member and the shield case and reliably conducts heat generated by the digital circuit control unit to the shield case. It can dissipate heat. In addition, the shield piece that energizes the pressing and has electrical conductivity can securely connect the shield case and the shield plate, which are electrically coupled to the ground, so that radiation from the digital circuit control unit can be achieved. The electromagnetic wave noise is effectively shielded by the shield plate and the shield case, and can be released to the ground. Further, since the heat radiating member is made of metal, electromagnetic wave noise radiated from the digital circuit controller is effectively shielded by the shield case and the heat radiating member electrically coupled to the ground by the heat radiating piece. This heat dissipation piece is also effective in reducing electromagnetic noise.

  According to the invention of claim 7, the outer periphery of the shield plate is bent at the edge of the circuit board, so that no sharp edge is formed on the outer periphery of the shield plate, and electromagnetic noise is radiated from the sharp edge. Can be prevented. In addition, since the outer periphery of the shield plate is simply bent at the edge, a sufficient gap is secured between the shield plate and the circuit board, and heat generated from the digital circuit control unit is generated between the shield plate and the circuit board. Can be prevented.

  As described above, the present invention further improves the countermeasures against electromagnetic noise and heat dissipation, and can receive digital broadcasts with a shield structure that can easily cope with the necessity of design change in the circuit board. In the following description of the embodiments, the first embodiment shows an embodiment in which an AV board constituting an analog circuit and a digital board constituting a digital circuit are separately formed, and the embodiment is described. Reference numeral 2 shows an embodiment in which an AV circuit and a digital circuit are formed on a single circuit board. Details of these examples are described below.

  Hereinafter, an embodiment as the best mode for carrying out the present invention will be described below with reference to FIGS. Of course, it is needless to say that the present invention can be easily applied to other than those described in the embodiments without departing from the spirit of the invention.

  In this embodiment, FIG. 1 is a perspective view showing a digital TV in the first embodiment of the present invention, FIG. 2 is a plan view showing the digital TV in a state in which a part of a front cabinet and a back cabinet of the digital TV are cut out, 3 is a perspective view showing the upper lid of the shield case provided in the digital television, FIG. 4 is a cross-sectional view showing the upper lid of the shield case, FIG. 5 is a perspective view showing the lower lid of the shield case provided in the digital television, and FIG. FIG. 7 is an explanatory view showing a state in which a digital board on which a digital circuit control microcomputer and a card slot are mounted is arranged on the lower lid, and FIG. 7 is an explanatory view showing a state in which a shield plate and a shield piece are attached to the back surface of the digital board on which electronic components are mounted. 8 is a cross-sectional view of the heat radiating member portion, FIG. 9 is an exploded perspective view showing a shield case and a digital board composed of an upper lid, a lower lid, and FIG. 0 is a perspective view showing a shield case accommodating the digital board mounted with the digital circuit control microcomputer and the card slot.

  With reference to the perspective view shown in FIG. 1, a digital television as a digital broadcast receiving apparatus according to the first embodiment of the present invention will be described. As shown in FIG. 1, a digital television 1 is composed of a synthetic resin cabinet 2 having a substantially box-shaped outer shape by combining a front cabinet 2a and a back cabinet 2b at the front and rear, and an image is displayed at the front center of the front cabinet 2a. Is displayed.

  Next, an outline of the inside of the digital television 1 will be described with reference to FIG. Inside the cabinet 2, a power supply unit that supplies power to each unit of the digital television 1, a video / audio signal generation unit that generates a displayable video / audio signal, a horizontal / vertical deflection unit, and the like are formed and arranged. substrate. A predetermined video / audio signal is selected from an analog video / audio signal and a digital video / audio signal input from the jack portion 21 which is a connection terminal connected to another electronic device, and an input / output of these signals is controlled. A board is horizontally arranged, and this AV board and a digital tuner 22 as a connection terminal for selecting one of video / audio signals of a predetermined program from digital received video / audio signals received by an antenna (not shown), The digital circuit board 12 on which the above components are mounted is covered with a thin, box-shaped shield case 30 that is electrically coupled to the ground and blocks electromagnetic wave noise, and is horizontally disposed in two layers.

  As shown in FIGS. 3, 5, 9, and 10, the shield case 30 is formed so as to be divided into an upper lid 30a and a lower lid 30b, and a hole 33 formed in the upper lid 30a and the lower lid 30b. The screw is screwed onto and fixed. The shield case 30 is configured such that the digital circuit board 12 is placed on the board placing portion 36 formed on the lower lid 30b, and the digital circuit board 12 is covered with the upper lid 30a. A component insertion hole 38 is disposed in the side wall 32 of the lower lid 30b so that an electronic component disposed on the digital circuit board 12 can be inserted. The upper and lower lids 30a and 30b are formed with a plurality of small vent holes 31a for radiating heat generated from electronic components disposed on the digital circuit board 12.

  Also, as shown in FIGS. 3 and 8, the upper lid 30a is formed with a plurality of L-shaped projecting pieces 34 that cut and raise a part of the flat surface portion 31 of the upper lid 30a and extend to the side wall 32. The AV substrate 11 is placed on the projecting piece 34 and fixed to the mounting hole 35 by screwing. Inside the flat portion 31 of the upper lid 30a, a cooling fan 44 for cooling a card slot 23, which will be described later, is attached, and vent holes 31b for passing the cooling air are formed and arranged substantially radially. Further, a leaf spring 41 is attached to the inner side of the upper lid 30a shown in the cross-sectional view of FIG. 4 so as to abut on a heat radiating member 40 attached to the digital circuit control microcomputer 20 described later.

  Various electronic components arranged on the digital circuit board 12 will be described with reference to FIGS. The digital circuit board 12 is substantially the same size as the outer shape of the shield case 30 and constitutes a broadcast receiving circuit capable of receiving digital broadcasts. In addition to the digital broadcast receiving unit in which the digital tuner 22 is disposed, In addition, when a billing broadcast is received, a card slot 23 serving as a card mounting portion that can receive a digital broadcast by inserting a billing broadcast user card, and a digital circuit control unit serving as a digital circuit control unit for controlling a digital circuit When the microcomputer 20 and the like are arranged and the power of the digital television 1 is on, the digital circuit control microcomputer 20, the jack section 21, and the card slot 23 radiate high-frequency electromagnetic noise. Arranged adjacent to the circuit board 12 and disposed on the AV board 11 having a different signal frequency. In order to prevent them from being affected by electromagnetic noise in electronic components that are easily affected by electromagnetic noise and other electronic devices that are disposed adjacent to the digital television 1, etc. The digital circuit control microcomputer 20, the jack unit 21, and the card are housed in a thin, box-shaped shield case 30 that is electrically coupled to the ground and blocks radiation such as electromagnetic noise so as to be wrapped. Unnecessary radiation of electromagnetic noise from the slot 23 can be shielded and released to the ground.

  However, electromagnetic wave noise radiated from the digital circuit control microcomputer 20 affects other electronic components mounted on the digital circuit board 12 on which the microcomputer 20 is mounted. In order to prevent unnecessary radiation of electromagnetic noise from the microcomputer 20, the digital circuit control microcomputer 20 is mounted on the digital circuit board 12 on which the digital circuit control microcomputer 20 shown in FIG. A shield plate 43 that covers from the back side of the substrate 12 is provided. As shown in FIG. 7, the shield plate 43 has a bent portion 43b in which the outer peripheral end of the rectangular flat portion 43a is bent toward the digital circuit board 12 side, and is located on each side of the flat portion 43a. Four leg portions 43c and 43d that are integrally suspended from the bent portion 43b are provided. The two opposite leg portions 43c are brought into contact with the back surface of the digital circuit board 12, and the remaining two leg portions 43d are digitally connected. It penetrates from a through hole 12 c formed in the circuit board 12. The through hole 12c is formed in the ground pattern 12b of the digital circuit control microcomputer 20 as shown in FIG. 8, and the heat radiating member 40 is a fixed piece that is located between the fins 40a and is a conductive member. The fixed piece 40b and the leg portion 43d of the shield plate 43 are overlapped and penetrated through the through hole 12c and soldered to the ground pattern 12b. In this embodiment, the jack portion 21 and the digital tuner 22 which are connection terminals are mounted on the digital circuit board 12, and the component insertion hole 38 through which the jack portion 21 and the digital tuner 22 are inserted into the lower cover 30 b of the shield case 30. The digital circuit board 12 is assembled to the lower cover 30b while the jack portion 21 and the digital tuner 22 are inserted into the component insertion hole 38, and the jack portion 21 and the digital tuner 22 to the component insertion hole 38 are assembled. The insertion direction X1 and the direction of the fin 40a formed in the heat radiating member 40 coincide, and the direction of the through hole 12c into which the fixed piece 40b fixed between the fin 40a and the leg portion 43d of the shield plate 43 is inserted X2 is orthogonal to the insertion direction X1 of the jack portion 21 and the digital tuner 22. Then, before assembling the digital circuit board 12 to the lower cover 30b of the shield case 30, the leg portions 43d of the shield plate 43 and the fixing pieces 40b fixed to the heat dissipation member 40 are inserted into the through holes 12c formed in the digital circuit board 12 in advance. The leg 43d and the fixing piece 40b are soldered to the ground pattern 12b of the digital circuit control microcomputer 20 to fix the shield plate 43 and the heat radiating member 40 to the digital circuit board 12, and then the digital circuit board 12 is mounted. The digital circuit board 12 is covered with the shield case 30 by assembling to the lower lid 30b of the shield case 30 and further attaching the upper lid 30a to the lower lid 30b. As a result, the heat radiation member 40 and the shield plate 43 are attached to the digital circuit board 12 so as to cover the front and back of the digital circuit control microcomputer 20, and the electromagnetic wave noise radiated from the microcomputer 20 is reduced to the shield plate 43 and the heat radiation member 40. The shielded electromagnetic wave noise is released to the ground pattern 12b of the digital circuit control microcomputer 20 and is prevented from being radiated from the edge of the outer periphery of the shield plate 43. Further, a conductive cushion 42 as a shield piece having conductivity and heat conductivity is attached to the flat portion 43a of the shield plate 43, and the lower cover 30b of the shield case 30 and the shield plate 43 electrically coupled to the ground. Can be electrically coupled via the conductive cushion 42. As a result, the shield plate 43 is connected to the shield case 30 that is electrically coupled to the ground, whereby the shielding property of the electromagnetic wave noise can be improved by using the conductive cushion 42. In addition, the above-described shield piece having conductivity and heat conductivity and elasticity is made of rubber or metal having conductivity that can electrically connect the shield case 30 and the shield plate 43 in addition to the conductive cushion 42. May be a leaf spring or the like.

  The microcomputer 20 for controlling the digital circuit and the card slot 23 generate heat when the digital TV 1 is turned on, and are wrapped in a shield case 30 as shown in FIGS. In order to dissipate the heat, the microcomputer 20 has a plurality of heat dissipating fins 40a called heat sinks, because the heat generated from the heat generating parts 20 and 23 such as the card slot 23 goes into the shield case 30 and becomes high temperature. A metal heat dissipating member 40 is mounted to dissipate heat in the shield case 30, and heat is conducted to the shield case 30 by the metal leaf spring 41, which is a heat dissipating piece in contact with the heat dissipating member 40 and the shield case 30. The heat is dissipated from the surface of the case 30. In addition, the heat-radiating piece having conductivity and thermal conductivity and having elasticity described above is a conductive material having thermal conductivity capable of thermally connecting the shield case 30 and the heat-dissipating member 40 in addition to the metal leaf spring 41. It may be made of rubber, conductive cushion 42 or the like.

  Further, the card slot 23 is provided on the mounting surface side of the digital circuit control microcomputer 20 mounted on the digital circuit board 12, and the cooling fan 44 is provided in the shield case 30 in the vicinity of the card slot. The card slot 23 and the microcomputer 20 can be cooled by the cooling air from the fan 44.

  The heat radiating member 40 mounted on the digital circuit control microcomputer 20 is made of metal, and is mounted so as to cover the surface of the microcomputer 20, so that electromagnetic noise radiated from the microcomputer 20 is also generated by the heat radiating member 40. Can be shielded. Further, as described above, the heat radiating member 40 is electrically connected to the shield case 30 that is electrically coupled to the ground by the metal leaf spring 41, so that the electromagnetic noise radiated from the microcomputer 20 can be reduced. The shield case 30 can be effectively shielded. In addition, the heat-radiating piece having conductivity and thermal conductivity and having elasticity described above is a conductive material having thermal conductivity capable of thermally connecting the shield case 30 and the heat-dissipating member 40 in addition to the metal leaf spring 41. It may be made of rubber, conductive cushion 42 or the like.

  According to the first embodiment described above, the digital television 1 as a digital broadcast receiving device having this shield structure is formed on the digital circuit board 12 on which the digital circuit block is formed, and is disposed at least wrapped in the shield case 30. The electromagnetic wave noise radiated from the digital circuit control microcomputer 20, the card slot 23, and the digital tuner 22 is effectively shielded by the shield case 30 that is electrically coupled to the ground. By forming and arranging an analog substrate (not shown) such as a main substrate or an AV substrate 11, various electronic components mounted in the vicinity of the electronic components 20, 23, and 22 that are mounted on the digital circuit block and radiate electromagnetic noise, Prevent interference with the analog substrate 11 and the like. You can.

  Further, a leaf spring 41 as a heat radiating piece that contacts the heat radiating member 40 thermally coupled to the surface of the microcomputer 20 which is a digital circuit control unit mounted on the digital circuit block, and also contacts the inner side of the shield case 30, By providing between the heat radiating member 40 and the shield case 30, the heat generated by the microcomputer 20 is thermally coupled to the surface of the heat radiating member 40, and a leaf spring 41 that contacts the heat radiating member 40 and the shield case 30. Since the heat can be radiated from the shield case 30 to the outside through the shield case 30, the microcomputer 20 and other electronic components constituting the other digital circuit are heated by the heat inside the shield case 30. It is possible to prevent malfunction due to overheating or failure. Further, the leaf spring 41 is provided between the heat radiating member 40 and the shield case 30, and when the design of the position of the microcomputer 20 or the like arranged on the digital circuit board 12 needs to be changed. It is only necessary to change the attachment position of the leaf spring 41, and there is no need to remodel or remodel the press die forming the shield case 30.

  The digital circuit board 12 is provided with a shield plate 43 so as to cover the digital circuit control microcomputer 20 mounted on the board 12 from the back surface of the board 12, and is in contact with the shield board 43, and the shield case. By providing a conductive cushion 42 as a shield piece that also contacts the inside of the shield 30 between the shield plate 43 and the shield case 30, electromagnetic noise radiated from the microcomputer 20 is shielded by the conductive cushion 42. The shield plate 43 electrically coupled to the ground 30 can be effectively primary shielded, and can be secondarily shielded by the shield case 30 electrically coupled to the ground and escaped to the ground. Further, the leg 43d of the shield plate 43 and the fixed piece 40b fixed to the heat radiating member 40 are inserted into the through hole 12c formed in the ground pattern 12b of the digital circuit control microcomputer 20, and the leg 43d and the fixed piece 40b are inserted. Is soldered to the ground pattern 12b of the digital circuit control microcomputer 20, so that the electromagnetic noise radiated from the microcomputer 20 can be released to the ground pattern 12b. The shield plate 43 and the heat radiating member 40 can be shielded on the digital circuit board 12 by soldering the leg 43d of the shield plate 43 and the fixing piece 40b fixed to the heat radiating member 40 to the ground pattern 12b. Can be fixed at the same time. It can be of. Accordingly, the microcomputer 20 can effectively radiate and cool the heat from the front surface in the shield case 30 and can effectively shield the electromagnetic noise from the back surface. Further, the conductive cushion 42 is provided between the shield 43 plate and the shield case 30, and the design of the position of the microcomputer 20 or the like arranged on the digital circuit board 12 is also required. It is only necessary to change the mounting position of the conductive cushion 42, and there is no need to modify or remodel the press die forming the shield case 30.

  Further, the digital circuit board 12 is provided with a card slot 23 for mounting a card capable of receiving billing broadcast on the mounting surface side of the digital circuit control microcomputer 20 mounted on the board 12, and in the vicinity of the card slot 23. By providing the cooling fan 44 in the shield case 30, both the card slot 23 and the microcomputer 20 can be cooled by the cooling air generated by the cooling fan 44, so that the cooling efficiency of the microcomputer 20 is improved. It can be greatly improved.

  In addition, since the heat dissipating piece is a metal leaf spring 41, the leaf spring 41 that urges the pressing and has thermal conductivity is in contact with the heat radiating member 40 and the shield case 30 to form a digital circuit. Heat generated by the control microcomputer 20 can be reliably conducted to the shield case 30 and radiated from the surface of the shield case 30. Further, since the heat radiating member 40 is made of metal, electromagnetic wave noise radiated from the microcomputer 20 is effectively shielded by the shield case 30 and the heat radiating member 40 electrically coupled to the ground by the leaf spring 41. Therefore, the leaf spring 41 is effective in reducing electromagnetic noise.

  Since the shield piece is a conductive cushion 42 having conductivity and thermal conductivity and having elasticity, the conductive cushion 42 having a thermal conductivity and capable of urging the pressing force is electrically connected to the ground and the electricity. Since the shield case 30 and the shield plate 43 that are mechanically coupled can be electrically and reliably connected, the electromagnetic wave noise radiated from the microcomputer 20 can be effectively shielded by the shield plate 43 and the shield case 30. I can do it.

  The outer periphery of the shield plate 43 has its edge bent to the digital circuit board 12 side, so that no sharp edge is formed on the outer periphery of the shield plate 43 and electromagnetic wave noise is prevented from being radiated from the sharp edge. I can do it. Further, since the outer periphery of the shield plate 43 is merely bent at the edge thereof, a sufficient gap between the shield plate 43 and the digital circuit board 12 is ensured, and is emitted from the microcomputer 20 between the shield plate 43 and the digital circuit board 12. Heat can be prevented from burning.

  Then, Example 2 in this invention is demonstrated. The same parts as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof will be omitted. In the second embodiment, FIG. 11 shows that a digital circuit block and an AV circuit block are formed on the same circuit board disposed in the digital television 1, and the digital circuit block is covered with a shield case 30 as in the first embodiment. FIG.

  In FIG. 11, a horizontally long single circuit board 10 is formed with a digital circuit block 12a in a substantially right half of the length direction in FIG. 11, and a shield case 30 electrically coupled to the ground is provided as the digital circuit block 12a. It is covered so as to wrap up. Similar to the digital circuit board 12 in the first embodiment, the digital circuit block 12a is provided with a digital circuit control microcomputer 20, a card slot 23, and a digital tuner 22. Further, a heat radiating member (not shown) is mounted on the surface of the microcomputer 20, and a leaf spring 41 that contacts the heat radiating member and conducts heat generated from the microcomputer 20 to the shield case 30 is provided inside the shield case 30. ing. On the back side of the circuit board 10 on which the microcomputer 20 is mounted, a shield plate (not shown) is provided so as to cover the back side of the microcomputer 20, and a conductive cushion (not shown) that electrically connects the shield case 30 and the shield plate. Abbreviation) is provided.

  In the digital circuit block 12a, the card slot 23 is mounted on the mounting surface side of the digital circuit control microcomputer 20, and the cooling fan 44 is mounted on the upper cover 30a of the shield case 30 covering the card slot 23 from above. Is provided.

  In addition, an AV circuit block 11a is formed and arranged on the substantially left half of the circuit board 10, and a predetermined video is obtained from an analog video / audio signal and a digital video / audio signal input from a jack unit 21 connected to another electronic device. The AV circuit block 11a for selecting the audio signal and controlling the input / output of these signals is formed on the same circuit board 10 as the digital circuit block 12a, and therefore covers the digital circuit block 12a. The shield case 30 is formed so that the circuit board 10 can be placed by cutting out a part of the upper lid 30a.

  According to the second embodiment, the digital television 1 serving as a digital broadcast receiving device having this shield structure is formed on the circuit board 10 and electromagnetic wave noise radiated from at least the digital circuit block 12a enclosed in the shield case 30 is Since it is effectively shielded by the shield case 30 electrically coupled to the ground, the digital circuit block 12a and the analog circuit block 11a are formed and arranged on one circuit board 10, so that the digital circuit block 12a is mounted. The electronic circuit control microcomputer 20 that radiates electromagnetic noise, the card slot 23, the digital tuner 22 and other electronic components mounted in close proximity to each other and the analog circuit block 11a and the like. Can be prevented.

  Further, a plate spring 41 that is in contact with the heat dissipating member 40 that is thermally coupled to the surface of the microcomputer 20 mounted on the digital circuit block 12a and that also contacts the inside of the shield case 30 is provided with the heat dissipating member 40 and the shield. By providing it between the case 30, the heat generated by the microcomputer 20 is transferred to the shield case 30 via the heat dissipating member 40 thermally coupled to the surface of the microcomputer 20 and the leaf spring 41 contacting the heat dissipating member 40 and the shield case 30. Since it is conducted and heat can be radiated from the shield case 30 to the outside, the heat inside the shield case 30 causes the microcomputer 20 and other electronic components constituting the digital circuit to overheat or malfunction. This can be prevented in advance. Further, the leaf spring 41 is provided between the heat radiating member 40 and the shield case 30, and it is necessary to change the design of the position of the microcomputer 20 etc. arranged on the digital circuit block 12a. In this case, it is only necessary to change the attachment position of the leaf spring 41, and there is no need to modify or remodel the press die forming the shield case 30.

  12 to 14 show a third embodiment of the present invention. The same parts as those of the first embodiment are denoted by the same reference numerals, and detailed description thereof will be omitted. In the first embodiment, an example in which the shield plate 43 covering the back surface side of the microcomputer 20 mounted on the digital circuit board 12 is provided. However, in this embodiment, the shield plate 43 is omitted and the lower cover of the shield case 30 is provided. A pair of attachment pieces 50 are formed on 30 b, and the attachment pieces 50 are brought into contact with a fixed piece 40 b fixed to the heat radiating member 40. The mounting piece 50 is cut and raised so as to face the lower lid 30 b corresponding to the heat radiating member 40, and the through hole 51 of the mounting piece 50 is formed in the digital circuit board 12. The through hole 51 is formed in the ground pattern 12b of the digital circuit block 12a. The fixing piece 40b fixed to the heat radiating member 40 and the mounting piece 50 formed by cutting and raising the lower lid 30b are passed through the through hole 51. 40b and the mounting piece 50 are soldered to the ground pattern 12b. That is, in this embodiment, the mounting piece 50 cut and raised from the lower lid 30b is inserted into the through hole 51 formed in the digital circuit board 12 while the digital circuit board 12 is assembled to the lower lid 30b of the shield case 30. . When the digital circuit board 12 is assembled to the lower cover 30 b of the shield case 30, the component insertion hole 38 that forms the jack portion 21 and the digital tuner 22 as connection terminals mounted on the digital circuit board 12 in the lower cover 30 b of the shield case 30. Assemble the digital circuit board 12 to the lower lid 30b. Here, in the first embodiment, the insertion direction X1 of the jack portion 21 and the digital tuner 22 into the component insertion hole 38 and the direction X2 of the through hole 12c formed in the digital circuit board 12 are orthogonal to each other. In the example, the same as in the first embodiment, the jack portion 21, the digital tuner 22 insertion direction X 1 and the through hole 12 c formed in the digital circuit board 12 are orthogonal to the through hole 12 c, the jack portion 21, the digital A through hole 51 having an orientation X3 along the insertion direction X1 of the tuner 22 is formed. And the component formed in the lower cover 30b in the state which inserted the fixing piece 40b adhering to the heat radiating member 40 mounted in the digital circuit board 12 in the through-hole 51 along the insertion direction X1 of the jack part 21 and the digital tuner 22 The insertion piece 50 formed on the lower lid 30 b is inserted into the through hole 51 while being inserted into the jack portion 21 and the digital tuner 22 mounted on the digital circuit board 12 into the insertion hole 38. After that, the mounting piece 50 and the fixing piece 40b are soldered to the ground pattern 12b of the digital circuit control microcomputer 20, and the heat radiation member 40 of the digital circuit board 12 and the mounting piece 50 formed on the lower lid 30b are fixed to the fixing piece 40b. Contact indirectly through. As a result, the digital circuit board 12 is fixed to the lower cover 30b of the shield case 30, and after the lower cover 30b and the digital circuit board 12 are fixed in this way, the upper cover 30a is assembled to the lower cover 30b. The substrate 12 is covered with a shield case 30. Therefore, in this embodiment, since the lower lid 30a of the shield case 30 and the digital circuit board 12 are integrated, the conductive cushion 42 that connects the shield plate 43 and the shield case 30 as in the above embodiments. The leaf spring 41 that connects the heat radiating member 40 and the shield case 30 is also omitted.

  In the present embodiment configured as described above, the shield plate 43 is omitted, and the shield 50 is formed in a state in which the attachment piece 50 formed by cutting and raising the lower lid 30b is in indirect contact with the heat radiating member 40 via the fixed piece 40b. The digital circuit board 12 is fixed to the lower lid 30b of the case 30. Thus, the shield plate 43 and the conductive cushion 42 that connects the shield plate 43 and the shield case 30 can be omitted, and the leaf spring 41 that connects the heat radiation member 40 and the shield case 30 is also omitted. The score can be reduced. Thus, by reducing the number of parts, the manufacturing process and assembly work can be simplified, and the productivity is excellent. Further, since the direction X3 of the through hole 51 of the mounting piece 50 formed by cutting and raising the lower lid 30b is formed along the insertion direction X1 of the jack portion 21 and the digital tuner 22, the lower lid 30b of the shield case 30 is formed on the lower lid 30b. When assembling the digital circuit board 12, the jack 21 to be mounted on the digital circuit board 12 and the digital tuner 22 are inserted into the component insertion hole 38 formed in the lower lid 30b, and the mounting piece formed on the lower lid 30b in the through hole 51 50 can be inserted smoothly, and the assembly workability is excellent. Furthermore, since the digital circuit board 12 is also provided with a through hole 12c orthogonal to the insertion direction X1 of the jack portion 21 and the digital tuner 22, there is a case where the shield plate 43 is provided and a case where the shield plate 43 is omitted. Since the digital circuit board 12 can be shared, the versatility is excellent. Further, by covering the digital circuit control microcomputer 20 mounted on the digital circuit board 12 with a shield case 30, electromagnetic wave noise radiated from the microcomputer 20 is integrally formed from the shield case 30 to the ground pattern 12b. Further, by shielding with a shield case 30 electrically coupled to the ground, it is possible to escape to the ground, and an excellent shielding effect can be exhibited.

  Although the present embodiment has been described in detail, various modifications can be made within the scope of the present invention. For example, the digital television 1 that is a digital broadcast receiving device having a shield structure is not limited to the digital television 1 that only receives and displays a digital broadcast, and the digital television 1 includes a DVD device or an HDD device. An electronic component that radiates electromagnetic noise and emits heat is not limited to the digital circuit control microcomputer 20 and generally compresses and decompresses a moving image signal and an audio signal. Also, it may be a semiconductor or the like, and it is necessary to shield and dissipate electromagnetic waves, such as a DVD device or HDD device on which the circuit board 10 on which the digital circuit control microcomputer 20 or MPEG IC is mounted, and a complex machine of these devices. What is necessary is just to select suitably the electronic device etc. which are made. In the third embodiment, the attachment piece 50 formed on the shield case 30 and the heat radiating member 40 are indirectly contacted via the fixing piece 40b fixed to the heat radiating member 40. You may comprise so that the formed attachment piece 50 may be made to contact the heat radiating member 40 directly.

  The present invention relates to an electromagnetic wave shield of a circuit board on which an electronic component that radiates electromagnetic noise is mounted, and can be applied to an application in which it is essential to dissipate heat generated from an electronic component that radiates electromagnetic noise.

1 is a perspective view showing an overview of a digital television in a first embodiment of the present invention. It is a top view which shows the digital television of the state which notched a part of front cabinet and back cabinet same as the above. It is a perspective explanatory view showing the upper cover of the shield case provided in the digital television. It is a section explanatory view showing the upper lid of a shield case same as the above. It is a perspective explanatory view showing the lower lid of the shield case provided in the digital television. It is explanatory drawing which shows the state which has arrange | positioned the digital circuit board which mounted the microcomputer for digital circuit control and the card slot on the lower cover of a shield case same as the above. FIG. 4 is an explanatory diagram showing a state in which a shield plate and a shield piece are attached to the back surface of the digital circuit board on which the digital circuit control microcomputer is mounted. It is sectional drawing of a heat radiating member part same as the above. It is a disassembled perspective view which shows a shield case and digital circuit board which consist of an upper cover and a lower cover as above. FIG. 4 is a perspective explanatory view showing a shield case containing a digital circuit board on which a digital circuit control microcomputer and a card slot are mounted. It is explanatory drawing which shows the principal part of the state which removed the circuit board of the digital television in 2nd Example of this invention, and a part of shield case. It is a disassembled perspective view of the shield case in 3rd Example of this invention. It is explanatory drawing which shows the state which has arrange | positioned the digital circuit board which mounted the microcomputer for digital circuit control and the card slot on the lower cover of a shield case same as the above. It is sectional drawing of a heat radiating member part same as the above.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Digital television 10 Circuit board 12 Digital circuit board 12a Digital circuit block 12b Ground pattern 12c, 51 Through-hole 20 Digital circuit control part (digital circuit control microcomputer)
21 Jack (connection terminal)
22 Digital tuner (connection terminal)
23 Card slot 30 Shield case 40 Heat radiation member 40b Fixed piece (conductive member)
41 Heat dissipation piece (leaf spring)
42 Shield piece (conductive cushion)
43 Shield plate 44 Cooling fan X1 Connection terminal insertion direction X2, X3 Direction of through hole

Claims (7)

  A digital broadcast receiving apparatus including a shield case that encloses at least a digital circuit block formed on a circuit board and is electrically coupled to a ground, and is thermally applied to a surface of a digital circuit control unit mounted on the digital circuit block. A digital broadcast having a shield structure, characterized in that a heat dissipating piece that abuts on the combined metal heat dissipating member and also contacts the inside of the shield case is provided between the heat dissipating member and the shield case. Receiver device.   A shield plate that covers the digital circuit control unit mounted on the circuit board is disposed on the back surface of the circuit board, and this shield plate is connected to a ground pattern formed on the circuit board, and is also applied to the inside of the shield case. 2. The digital broadcast receiving apparatus having a shield structure according to claim 1, wherein a shield piece in contact with the shield piece is provided between the shield plate and the shield case.   An attachment piece is formed on the inner surface side of the shield case, the attachment piece is electrically connected to the ground pattern of the circuit board, and the attachment piece and the heat dissipation member are directly or indirectly via a conductive member. The digital broadcast receiving apparatus according to claim 1, wherein the digital broadcast receiving apparatus is in contact with the digital broadcast receiving apparatus.   A connection terminal for connecting to an external device is mounted on the circuit board, a component insertion hole for leading the connection terminal to the outside is provided in the shield case, and a through hole of the mounting piece is provided in the ground pattern of the circuit board. 4. The digital broadcast receiving apparatus according to claim 3, wherein the direction of the through hole is made to coincide with the insertion direction of the connection terminal with respect to the component insertion hole.   The circuit board is provided with a card mounting part for mounting a card capable of receiving billing broadcast on the mounting surface side of the digital circuit control part mounted on the circuit board, and a cooling case is provided in a shield case in the vicinity of the card mounting part. A digital broadcast receiving apparatus comprising the shield structure according to any one of 1 to 3, wherein a fan is provided.   4. The heat radiating piece and the shield piece are a synthetic resin member, a rubber member, or a metal leaf spring having conductivity and thermal conductivity and having elasticity. A digital broadcast receiver comprising the shield structure according to any one of the above. The digital broadcast receiving apparatus having a shield structure according to any one of claims 2 to 6, wherein the outer periphery of the shield plate has its edge bent toward the circuit board.

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