JP2012050987A - Heat dissipation base board having electric insulation - Google Patents
Heat dissipation base board having electric insulation Download PDFInfo
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Abstract
Description
本発明は高温になると短寿命になったり、故障したりするLEDパッケージ、高負荷半導体、高負荷コンデンサー、レンズ集光型太陽光発電素子の基板に好適なセラミックス焼結板と黒鉛および金属又は合金(以下金属)の組合せからなる放熱基板に関する。 The present invention is a ceramic sintered plate and graphite and metal or alloy suitable for substrates of LED packages, high-load semiconductors, high-load capacitors, and lens concentrating solar power generation devices that have a short life or fail at high temperatures. The present invention relates to a heat dissipation board made of a combination of (hereinafter referred to as metals).
黒鉛材料を含む黒鉛−金属複合体には、金属マトリックスと黒鉛粒子、又は黒鉛繊維を材料として、分散させた金属基複合材料や、押出成形体や冷間等方圧力成形体、金型にて一方向圧力による成形体より焼成してなる黒鉛成形体に金属を分散する黒鉛基金属複合材料が知られている。(特願平11−321828、特願2001−135551) For graphite-metal composites containing graphite materials, metal matrix composites, graphite particles, or graphite fibers are used as materials, dispersed metal matrix composites, extruded moldings, cold isostatic pressings, and molds. There is known a graphite-based metal composite material in which a metal is dispersed in a graphite molded body fired from a molded body by unidirectional pressure. (Japanese Patent Application No. 11-321828, Japanese Patent Application No. 2001-135551)
一方で黒鉛を含む複合体は熱拡散率が1.5〜3cm2/secと大きく、アルミニウムや銅、窒化アルミニウムなどといった伝熱媒体として通常多用されている材料の熱拡散率が0.7〜1.0cm2/secと比較すると、その熱拡散性能が卓越していることが知られている。 On the other hand, the composite containing graphite has a large thermal diffusivity of 1.5 to 3 cm 2 / sec, and the thermal diffusivity of a material usually used as a heat transfer medium such as aluminum, copper, and aluminum nitride is 0.7 to Compared to 1.0 cm 2 / sec, it is known that its thermal diffusion performance is superior.
他方で、黒鉛を含む複合体は、優れた導電性を有するので、複合体の一方の表面に回路基板を形成する時、何らかの絶縁層を付加せねばならない。 On the other hand, a composite containing graphite has excellent conductivity, and therefore, when a circuit board is formed on one surface of the composite, some kind of insulating layer must be added.
黒鉛−金属複合体の一方の表面に絶縁性を付与する時、一旦は、黒鉛−金属複合体を所定形状に加工した後に、その表にメッキ処理などを施して、有機フィルムや、セラミック焼結体を接着剤やハンダ等により、接合して、絶縁層を形成する方法が、多く用いられている。これは、工程が多岐に亘るので、高価になってしまう。又、接着剤やハンダの使用は、熱伝導度を下げることになる。 When imparting insulation to one surface of a graphite-metal composite, once the graphite-metal composite is processed into a predetermined shape, the surface is subjected to plating treatment, etc., and an organic film or ceramic sintered A method of joining the bodies with an adhesive or solder to form an insulating layer is often used. This is expensive because the process is diverse. In addition, the use of an adhesive or solder lowers the thermal conductivity.
本発明の目的は上記問題に鑑み、黒鉛−金属複合体の良好な熱拡散率を保持しつつ、セラミック焼結体を密接させて、1回の工程で電気絶縁被膜を具備した放熱基板を提供することにある。 In view of the above problems, an object of the present invention is to provide a heat dissipation substrate provided with an electrical insulating coating in one step by bringing a ceramic sintered body into close contact while maintaining a good thermal diffusivity of a graphite-metal composite. There is to do.
本発明者は、用いる材料の組合せを考案することにより、上記の目的を良好に達成しうる以下の要旨を有する本発明に到達した。 The present inventor has arrived at the present invention having the following gist that can achieve the above-mentioned object satisfactorily by devising a combination of materials to be used.
セラミック焼結板の種類としては、アルミナ、ムライト、ジルコニア、ベリリア、マグネシア、マグネシア−アルミナスピネル、トリアなどの酸化物の他に、窒化ホウ素、窒化アルミニウム、窒化ケイ素などの窒化物で電気比抵抗値が1×106オーム・cm以上のものである。
セラミック焼結板の大きさは、適宣、用途に応じて変わるが、厚さは薄い程良好で、0.01mm〜1mmのものが、工程中のハンドリングや、出来上がった放熱基板の電気絶縁性、熱拡散率の低下を防ぐために好ましい。
As for the types of sintered ceramics, in addition to oxides such as alumina, mullite, zirconia, beryllia, magnesia, magnesia-alumina spinel, and tria, nitrides such as boron nitride, aluminum nitride, and silicon nitride are used for electrical resistivity. Is 1 × 10 6 ohm · cm or more.
The size of the sintered ceramic plate will vary depending on the application, but the thinner the better, the better the thickness is from 0.01 mm to 1 mm. Handling in the process and electrical insulation of the finished heat dissipation substrate It is preferable for preventing a decrease in thermal diffusivity.
黒鉛の成形体としては、黒鉛電極のブロックから板状に切り出したもの、人工黒鉛の粉末、天然黒鉛の粉末、黒鉛繊維のチョップド化したものなど一種以上のものを混合して、板状にプレスしたものなどが好適で、冷間等方圧力成形体なども、用いることができる。これらの黒鉛は、その大きさは、適宣、用途に応じて変わるが、厚さは0.5mm〜10mmものもが、出来上がった放熱基板の熱拡散率の低下を防ぐために好ましい。 As the graphite compact, one or more kinds of graphite electrode blocks, artificial graphite powder, natural graphite powder, chopped graphite fiber, etc. are mixed and pressed into a plate shape. It is preferable to use a cold isostatic pressing or the like. The size of these graphites may vary depending on the application, but a thickness of 0.5 mm to 10 mm is preferable in order to prevent a reduction in the thermal diffusivity of the completed heat dissipation substrate.
この発明に供される黒鉛は体積率が60%以上のものが好ましく、良好な熱拡散率が期待できる。 The graphite used in the present invention preferably has a volume ratio of 60% or more, and a good thermal diffusivity can be expected.
セラミック板と接合し、黒鉛板とは複合される金属としてアルミニウム、アルミニウム合金、銅、銅合金、マグネシウム、マグネシウム合金、銀、銀合金、亜鉛、亜鉛合金、錫、錫合金、金、金合金などの融点が1100℃以下のものが利用できる。 Aluminum, aluminum alloy, copper, copper alloy, magnesium, magnesium alloy, silver, silver alloy, zinc, zinc alloy, tin, tin alloy, gold, gold alloy, etc. Those having a melting point of 1100 ° C. or lower can be used.
セラミック焼結板(4)と黒鉛板(3)とを、例えば鉄製の治具(6)によって密接させて、金型(1)内に配置し、金属溶湯(5)を注ぎ、加圧パンチ(2)によって、密接させて、金型(1)内に配置し、金属溶湯(5)を注ぎ、加圧パンチ(2)によって、溶湯を加圧し、金属凝固後、セラミック焼結板と黒鉛に金属含浸された複合体の接合された部分を切出して得る。 The ceramic sintered plate (4) and the graphite plate (3) are brought into close contact with, for example, an iron jig (6) and placed in the mold (1), and the molten metal (5) is poured into the pressure punch. (2) Closely placed and placed in the mold (1), poured into the molten metal (5), pressurized with the pressure punch (2), solidified the metal, then sintered ceramic plate and graphite A bonded portion of the composite impregnated with metal is cut out.
本発明によれば、電気絶縁性セラミックス板と、黒鉛−金属複合体の一体成形物は、優れた熱拡散性を有し、工程も非常に簡素で、経済性も高い。このものは、産業上では、LEDパッケージ、高負荷半導体、高負荷コンデンサー、レンズ集光型発電素子などに有用な基板を提供することができる。 According to the present invention, the integrally formed product of the electrically insulating ceramic plate and the graphite-metal composite has excellent thermal diffusibility, the process is very simple, and the economy is high. Industrially, this can provide a substrate useful for an LED package, a high load semiconductor, a high load capacitor, a lens condensing power generation element, and the like.
セラミック焼結板と黒鉛板が密接させた状態で、金属溶湯に10Mpa以上の圧力を加えて、凝固させて、電気絶縁性を有する放熱基板を得る。10Mpa以下の圧力では、セラミックの表面に金属が密着せず、目的を達し得ない。セラミックの表面に、金属を予め溶射しても良い。 In a state where the ceramic sintered plate and the graphite plate are brought into close contact with each other, a pressure of 10 Mpa or more is applied to the molten metal and solidified to obtain a heat dissipation substrate having electrical insulation. At a pressure of 10 MPa or less, the metal does not adhere to the surface of the ceramic and the purpose cannot be achieved. A metal may be sprayed on the ceramic surface in advance.
セラミック焼結板の表面に何ら前処理しない場合、50Mpa以上の加圧をすれば、密着性は良好となる。 In the case where no pretreatment is performed on the surface of the ceramic sintered plate, the adhesion is improved by applying a pressure of 50 Mpa or more.
本発明に用いられる黒鉛板は、板厚方向に良好な熱拡散率を有するものが、好適である。そのため、黒鉛板としては、黒鉛電極に用いられるような押出材が好適であり、熱拡散率が2cm2/sec以上のものがより好まれる。この黒鉛の成分の一部として、針状黒鉛、黒鉛のチョップド繊維、天然黒鉛などを含む場合、熱拡散率の高いものが得られる。 The graphite plate used in the present invention preferably has a good thermal diffusivity in the plate thickness direction. Therefore, as the graphite plate, an extruded material used for a graphite electrode is suitable, and a material having a thermal diffusivity of 2 cm 2 / sec or more is more preferred. When a part of the graphite component includes acicular graphite, graphite chopped fiber, natural graphite, or the like, one having a high thermal diffusivity is obtained.
本発明に用いられるセラミック焼結板は、その焼結板の熱拡散率の大きいものが、やはり好まれる。しかしながら、熱拡散率の低いセラミック焼結板でも、その厚さを小さくすれば、黒鉛−金属複合体の良好な熱拡散率を阻害する要因を小さくすることができる。逆に熱拡散率の低いセラミック焼結板の場合、黒鉛一金属複合体の部分の厚さを増すことにより、電気絶縁性を有する放熱基板の良好な性質を持つものを得ることができる。 The ceramic sintered plate used in the present invention is also preferred to have a large thermal diffusivity of the sintered plate. However, even if a ceramic sintered plate having a low thermal diffusivity is reduced in thickness, the factors that hinder the good thermal diffusivity of the graphite-metal composite can be reduced. On the other hand, in the case of a ceramic sintered plate having a low thermal diffusivity, by increasing the thickness of the graphite-metal composite portion, it is possible to obtain a heat radiating substrate having electrical insulating properties with good properties.
本発明に用いられるセラミック焼結板の種類として、酸化物系のものは概して、熱拡散率が低く、好ましくはないが、電気絶縁性は優れているので、板厚を薄くして使用すればよいが、0.01mm以下では、ハンドリングに困難をきたすので好ましくない。
窒化物系は、熱拡散率が酸化物系より高いので、1mm程度の板厚でも、放熱基板としての性能は優れたものが得られる。
As a kind of the sintered ceramic plate used in the present invention, an oxide-based one generally has a low thermal diffusivity, which is not preferable. However, since the electrical insulation is excellent, if it is used with a thin plate thickness, However, it is not preferable that the thickness is 0.01 mm or less because handling is difficult.
Since the nitride system has a higher thermal diffusivity than the oxide system, even if the plate thickness is about 1 mm, an excellent performance as a heat dissipation substrate can be obtained.
本発明に用いられる金属として、融点として、1100℃以下の金属ならば良いが、それは、金型が鉄性を用いることから由来する。又、経済性の面から、一般に安価で融点の低いものの方が、好まれる。鋳造時のハンドリングの良さなどから、アルミニウム、アルミニウム合金などが好適な金属である。 The metal used in the present invention may be a metal having a melting point of 1100 ° C. or lower, which is derived from the fact that the mold uses iron. Also, from the economical aspect, those having a low price and a low melting point are generally preferred. Aluminum, aluminum alloy, and the like are suitable metals because of good handling during casting.
以下、本発明を実施例により、具体的に説明する。 Hereinafter, the present invention will be specifically described by way of examples.
体積率85%の電極用黒鉛ブロックの押出材の押出方向に直角に2mmの厚さで切り出し、120mm×60mmのものを得た。このものの熱拡散率は、2.3cm2/secであった。一方で、セラミックス焼結体として、窒化アルミニウムを厚さ0.4mmで120mm×60mmのものを図−1のように鉄製補助治具で密接することにした。この時の窒化アルミニウムの熱拡散率は0.8cm2/sceであった。 Cut out at a thickness of 2 mm perpendicular to the extrusion direction of the extruded material of the graphite block for electrodes having a volume ratio of 85% to obtain a 120 mm × 60 mm one. The thermal diffusivity of this product was 2.3 cm 2 / sec. On the other hand, as a ceramic sintered body, aluminum nitride having a thickness of 0.4 mm and 120 mm × 60 mm was closely contacted with an iron auxiliary jig as shown in FIG. At this time, the thermal diffusivity of aluminum nitride was 0.8 cm 2 / sce.
このようにして、組立したものを図−1のように金型内に配置し、JIS−AC3A溶湯を700℃で注ぎ、加圧パンチにて、80Mpaで鋳造凝固後、セラミック焼結板と黒鉛板の部分を採り出した。黒鉛にはAC3Aのアルミニウム合金が、その空隙に浸漬しており、セラミック焼結板には密に接合していた。 As shown in FIG. 1, the assembled product is placed in a mold, poured into a JIS-AC3A molten metal at 700 ° C., cast and solidified with a pressure punch at 80 Mpa, and then sintered with a ceramic sintered plate and graphite. The board part was taken out. In graphite, an AC3A aluminum alloy was immersed in the voids, and was closely joined to the sintered ceramic plate.
以上のようにして得られた電気絶縁性を有する放熱基板の熱拡散率は、2.1cm2/secであった。又、セラミック焼結板と黒鉛一金属複合体の接合強度は、45Mpa以上であった。このものは55Wの出力を有する高負荷半導体の基板として、充分な絶縁特性と、放熱特性を有していた。 The thermal diffusivity of the heat insulating substrate having electrical insulation obtained as described above was 2.1 cm 2 / sec. Further, the bonding strength between the ceramic sintered plate and the graphite / metal composite was 45 Mpa or more. This material had sufficient insulation characteristics and heat dissipation characteristics as a high load semiconductor substrate having an output of 55 W.
ピッチ系炭素繊維の黒鉛化したものを長さ1mm(平均)に切断したものを体積で30%含む黒鉛の押出成形体を得た。このものを押出方向と直角に切り出して、100mm×100mm×3mm厚さのものを得た。このものの熱拡散率は2.6cm2/secであった。 A graphite extrudate containing 30% by volume of a pitch-based carbon fiber graphitized by cutting to 1 mm (average) length was obtained. This was cut out at right angles to the extrusion direction to obtain 100 mm × 100 mm × 3 mm thick. The thermal diffusivity of this product was 2.6 cm 2 / sec.
一方で窒化珪素焼結板を100mm×100mm×0.2mm厚さのもので、この熱拡散率は0.5cm2/secであり、これを実施例1と同様に、鋳造処理して、電気絶縁性を有する放熱基板を得た。このものの熱拡散率は、2.1cm2/secであった。 On the other hand, the silicon nitride sintered plate has a thickness of 100 mm × 100 mm × 0.2 mm, and its thermal diffusivity is 0.5 cm 2 / sec. An insulating heat dissipation substrate was obtained. The thermal diffusivity of this product was 2.1 cm 2 / sec.
実施例2と同様にして、アルミナ焼結板を厚さ0.05mmのもので行った。この時に利用したアルミナの熱拡散率は0.08cm2/secであった。得られた電気絶縁性を有する放熱基板の熱拡散率は、2.1cm2/secであった。 In the same manner as in Example 2, an alumina sintered plate having a thickness of 0.05 mm was used. The thermal diffusivity of alumina used at this time was 0.08 cm 2 / sec. The obtained heat radiating substrate having electrical insulation had a thermal diffusivity of 2.1 cm 2 / sec.
実施例2と実施例3で得られた放熱基板をレンズ集光型太陽光発電機のシリコンチップの基板として、用いたところ、シリコンチップの温度を80℃以下に保持できた。 When the heat dissipation substrate obtained in Example 2 and Example 3 was used as a silicon chip substrate of a lens concentrating solar power generator, the temperature of the silicon chip could be kept at 80 ° C. or lower.
実施例1の黒鉛一金属複合体部のみを採り出して、これにNiメッキを5μm施して、その後、銅−銀−亜鉛からなるハンダを片面のみ塗布し、それに、やはり実施例1と同じサイズの窒化アルミニウム板を接合した。このものの接合強度は、28Mpaで、熱拡散率は、1.4cm2/secであった。 Only the graphite-metal composite part of Example 1 is taken out, Ni plating is applied to this by 5 μm, and then only one side of the solder made of copper-silver-zinc is applied to the same size as in Example 1. The aluminum nitride plates were joined. The bonding strength of this was 28 Mpa, and the thermal diffusivity was 1.4 cm 2 / sec.
このようにして得られたものは、本発明の実施例1に比較すると、強度、熱拡散率の両面で劣り、かつ、工程がメッキ工程、ハンダ工程、接合工程が必要で、コスト的に大きな差異となって来て、経済的に不利であった。 The product thus obtained is inferior in both strength and thermal diffusivity compared to Example 1 of the present invention, and the process requires a plating process, a solder process, and a joining process, and is large in cost. It became a difference and was economically disadvantageous.
本発明の電気絶縁性セラミックス板と、黒鉛−金属複合体の一体成形物は、優れた熱拡散性を有し、工程も非常に簡素で、経済性も高い。このものは、産業上では、LEDパッケージ、高負荷半導体、高負荷コンデンサー、レンズ集光型発電素子などに有用な基板となり得る。 The integrally molded product of the electrically insulating ceramic plate and the graphite-metal composite of the present invention has excellent thermal diffusivity, a very simple process, and high economic efficiency. Industrially, this can be a useful substrate for LED packages, high-load semiconductors, high-load capacitors, lens condensing power generation elements, and the like.
1.
金型
2.
加圧パンチ
3.
電気絶縁性セラミック板
4.
黒鉛板
5.
金属溶湯
6.
補助治具
1.
2. Pressure punch
Electrically insulating ceramic plate4.
4. Graphite plate
Metal melt6.
Auxiliary jig
セラミック焼結板の種類としては、アルミナ、ムライト、ジルコニア、ベリリア、マグネシア、マグネシア−アルミナスピネル、トリアなどの酸化物の他に、窒化ホウ素、窒化アルミニウム、窒化ケイ素などの窒化物で電気比抵抗値が1×106Ω・cm以上のものである。
セラミック焼結板の大きさは、適宣、用途に応じて変わるが、厚さは薄い程良好で、0.01mm〜1mmのものが、工程中のハンドリングや、出来上がった放熱基板の電気絶縁性、熱拡散率の低下を防ぐために好ましい。
As for the types of sintered ceramics, in addition to oxides such as alumina, mullite, zirconia, beryllia, magnesia, magnesia-alumina spinel, and tria, nitrides such as boron nitride, aluminum nitride, and silicon nitride are used for electrical resistivity. Is 1 × 10 6 Ω · cm or more.
The size of the sintered ceramic plate will vary depending on the application, but the thinner the better, the better the thickness is from 0.01 mm to 1 mm. Handling in the process and electrical insulation of the finished heat dissipation substrate It is preferable for preventing a decrease in thermal diffusivity.
黒鉛の成形体としては、黒鉛電極のブロックから板状に切り出したもの、人工黒鉛の粉末、天然黒鉛の粉末、黒鉛繊維のチョップド化したものなど一種以上のものを混合して、板状にプレスしたものなどが好適で、冷間等方圧力成形体なども、用いることができる。これらの黒鉛は、その大きさは、適宣、用途に応じて変わるが、厚さは0.5mm〜10mmのものが、出来上がった放熱基板の熱拡散率の低下を防ぐために好ましい。 As the graphite compact, one or more kinds of graphite electrode blocks, artificial graphite powder, natural graphite powder, chopped graphite fiber, etc. are mixed and pressed into a plate shape. It is preferable to use a cold isostatic pressing or the like. The size of these graphites varies according to the intended use, but a thickness of 0.5 mm to 10 mm is preferable in order to prevent a decrease in the thermal diffusivity of the completed heat dissipation substrate.
セラミック焼結板(4)と黒鉛板(3)とを、例えば鉄製の治具(6)によって密接させて、金型(1)内に配置し、金属溶湯(5)を注ぎ、加圧パンチ(2)によって、溶湯を加圧し、金属凝固後、セラミック焼結板と黒鉛に金属含浸された複合体の接合された部分を切出して得る。 The ceramic sintered plate (4) and the graphite plate (3) are brought into close contact with, for example, an iron jig (6) and placed in the mold (1), and the molten metal (5) is poured into the pressure punch. According to (2), the molten metal is pressurized, and after solidifying the metal, it is obtained by cutting out the joined portion of the ceramic sintered plate and the composite impregnated with graphite in the metal.
セラミック焼結板と黒鉛板が密接させた状態で、金属溶湯に10MPa以上の圧力を加えて、凝固させて、電気絶縁性を有する放熱基板を得る。10MPa以下の圧力では、セラミックの表面に金属が密着せず、目的を達し得ない。セラミックの表面に、金属を予め溶射しても良い。 In a state where the ceramic sintered plate and the graphite plate are brought into close contact with each other, a pressure of 10 MPa or more is applied to the molten metal and solidified to obtain a heat dissipation substrate having electrical insulation. At a pressure of 10 MPa or less, the metal does not adhere to the ceramic surface, and the purpose cannot be achieved. A metal may be sprayed on the ceramic surface in advance.
セラミック焼結板の表面に何ら前処理しない場合、50MPa以上の加圧をすれば、密着性は良好となる。 In the case where no pretreatment is performed on the surface of the ceramic sintered plate, adhesion is improved by applying a pressure of 50 MPa or more.
本発明に用いられる金属として、融点として、1100℃以下の金属ならば良いが、それは、金型が鉄性を用いることに由来する。又、経済性の面から、一般に安価で融点の低いものの方が、好まれる。鋳造時のハンドリングの良さなどから、アルミニウム、アルミニウム合金などが好適な金属である。 The metal used in the present invention may be a metal having a melting point of 1100 ° C. or lower, which is derived from the fact that the mold uses iron. Also, from the economical aspect, those having a low price and a low melting point are generally preferred. Aluminum, aluminum alloy, and the like are suitable metals because of good handling during casting.
このようにして、組立したものを図−1のように金型内に配置し、JIS−AC3A溶湯を700℃で注ぎ、加圧パンチにて、80MPaで鋳造凝固後、セラミック焼結板と黒鉛板の部分を採り出した。黒鉛にはAC3Aのアルミニウム合金が、その空隙に浸漬しており、セラミック焼結板には密に接合していた。 The assembly thus assembled is placed in a mold as shown in FIG. 1, JIS-AC3A molten metal is poured at 700 ° C., cast and solidified at 80 MPa with a pressure punch, and then a ceramic sintered plate and graphite The board part was taken out. In graphite, an AC3A aluminum alloy was immersed in the voids, and was closely joined to the sintered ceramic plate.
以上のようにして得られた電気絶縁性を有する放熱基板の熱拡散率は、2.1cm2/secであった。又、セラミック焼結板と黒鉛一金属複合体の接合強度は、45MPa以上であった。このものは55Wの出力を有する高負荷半導体の基板として、充分な絶縁特性と、放熱特性を有していた。 The thermal diffusivity of the heat insulating substrate having electrical insulation obtained as described above was 2.1 cm 2 / sec. Further, the bonding strength between the ceramic sintered plate and the graphite / metal composite was 45 MPa or more. This material had sufficient insulation characteristics and heat dissipation characteristics as a high load semiconductor substrate having an output of 55 W.
実施例1の黒鉛一金属複合体部のみを採り出して、これにNiメッキを5μm施して、その後、銅−銀−亜鉛からなるハンダを片面のみ塗布し、それに、やはり実施例1と同じサイズの窒化アルミニウム板を接合した。このものの接合強度は、28MPaで、熱拡散率は、1.4cm2/secであった。 Only the graphite-metal composite part of Example 1 is taken out, Ni plating is applied to this by 5 μm, and then only one side of the solder made of copper-silver-zinc is applied to the same size as in Example 1. The aluminum nitride plates were joined. This had a bonding strength of 28 MPa and a thermal diffusivity of 1.4 cm 2 / sec.
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