GReddy Turbocharger
You can pick up the best turbo whatever your situation want to be. There has more than 40 of suitable turbo as well known as T series which you can find the best
| ターボチャージャー | |||||||
|---|---|---|---|---|---|---|---|
| タイプ | コンプレッサー ホイール | EXハウジング(㎠) | アクチュエーター | CODE | 本体価格(税抜) | 本体価格(税込) | 備考 |
| TD-04H | 15G | 8.5 | P380 | 11500036 | ¥110,000 | ¥121,000 | アクチュエーター取付加工前提商品 |
| TD-06S L2 | 20G | 8.0 | 無 | 11500205 | ¥203,000 | ¥223,300 | |
| TD-06S L2 | 20G | 10.0 | 無 | 11500206 | ¥203,000 | ¥223,300 | |
| TD-06SH | 20G | 8.0 | 無 | 11500185 | ¥195,000 | ¥214,500 | |
| TD-06SH | 20G | 10.0 | 無 | 11500186 | ¥195,000 | ¥214,500 | |
| TD-06SH | 20G | 16.0 | 無 | 11500195 | ¥195,000 | ¥214,500 | |
| TD-06SH | 25G | 8.0 | 無 | 11500170 | ¥235,000 | ¥258,500 | |
| TD-06SH | 25G | 10.0 | 無 | 11500175 | ¥235,000 | ¥258,500 | |
| TD-06SH | 25G | 16.0 | 無 | 11500180 | ¥235,000 | ¥258,500 | |
| TD07S | 25G | 14.0 | 無 | 11500245 | ¥260,000 | ¥286,000 | |
| TD07S | 25G | 17.0 | 無 | 11500250 | ¥260,000 | ¥286,000 | |
| TD07S | 25G | 21.0 | 無 | 11500255 | ※販売終了 | ||
| T67 | 25G | 8.0 | 無 | 11500210 | ※販売終了 | ||
| T67 | 25G | 10.0 | 無 | 11500215 | ※販売終了 | ||
| T78 | 29D | 14.0 | 無 | 11500330 | ¥267,000 | ¥293,700 | 排気出口アダプター 80φ四角フランジタイプ ※1 |
| T78 | 29D | 14.0 | 無 | 11500331 | ¥267,000 | ¥293,700 | 排気出口アダプター 94φカップリングタイプ ※1 |
| T78 | 29D | 17.0 | 無 | 11500332 | ¥267,000 | ¥293,700 | 排気出口アダプター 80φ四角フランジタイプ ※1 |
| T78 | 29D | 17.0 | 無 | 11500333 | ¥267,000 | ¥293,700 | 排気出口アダプター 94φカップリングタイプ ※1 |
| T78 | 33D | 14.0 | 無 | 11500267 | ¥267,000 | ¥293,700 | 排気出口アダプター 80φ四角フランジタイプ |
| T78 | 33D | 14.0 | 無 | 11500268 | ¥267,000 | ¥293,700 | 排気出口アダプター 94φカップリングタイプ |
| T78 | 33D | 17.0 | 無 | 11500260 | ¥267,000 | ¥293,700 | 排気出口アダプター 80φ四角フランジタイプ ※1 |
| T78 | 33D | 17.0 | 無 | 11500261 | ¥267,000 | ¥293,700 | 排気出口アダプター 94φカップリングタイプ ※1 |
| T88 | 34D | 15.0 | 無 | 11500314 | ¥278,000 | ¥305,800 | 排気出口アダプター 80φ四角フランジタイプ |
| T88 | 34D | 15.0 | 無 | 11500319 | ¥278,000 | ¥305,800 | 排気出口アダプター 94φカップリングタイプ |
| T88 | 34D | 18.0 | 無 | 11500315 | ¥278,000 | ¥305,800 | 排気出口アダプター 80φ四角フランジタイプ |
| T88 | 34D | 18.0 | 無 | 11500321 | ¥278,000 | ¥305,800 | 排気出口アダプター 94φカップリングタイプ |
| T88 | 34D | 22.0 | 無 | 11500316 | ¥278,000 | ¥305,800 | 排気出口アダプター 80φカップリングタイプ ※1 |
| T88 | 34D | 22.0 | 無 | 11500322 | ¥278,000 | ¥305,800 | 排気出口アダプター 94φカップリングタイプ ※1 |
| T88H | 34D | 18.0 | 無 | 11500317 | ※販売終了 | ||
| T88H | 34D | 22.0 | 無 | 11500323 | ※販売終了 | ||
| T88H | 38GK | 18.0 | 無 | 11500324 | ¥320,000 | ¥353,000 | 排気出口アダプター 94φカップリングタイプ |
| T88H | 38GK | 22.0 | 無 | 11500325 | ¥320,000 | ¥353,000 | 排気出口アダプター 94φカップリングタイプ |
| ※1=EXハウジングに溶接取り付けが必要。 | |||||||
| 【付属品】 ※フランジ、取付けボルト、オイルインレットユニオンは付属していません。 ●TD06SH-25G/T67は専用オイルインレットフランジ付属。(ボルト/銅ワッシャー含む) ●TD07S/T78/T88は排気出口アダプター付属。(EXハウジングに溶接取り付け必要) ●T88HはEXハウジングに排気出口アダプター溶接済み。 |
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GReddy TZ Turbo Charger
T517Z_10cm_se20
T620Z
This is a repair replacement turbo unit for the TZ turbocharger ‘OEM replacement type’ that can be directly installed on the original exhaust manifold and original intake pipe.
- Compressor and turbine has been developed for each cars. As far as combined with wheel design, each product has developed for any character of engine type.
- In addition to well responding engine at low revs. As hight revs you go,you can feel the proper racing engine feeling on any type of road conditions,like normal street and circuit.
- Please sense high cost performance by only exchanged from a Genuine turbocharger
|
Type |
EX.Housing |
Actuator |
CODE |
Price (Tax Included) |
Price without tax |
Remarks |
|
T517Z |
8.0 cm² |
P765 |
11500123 |
¥216,700 |
¥197,000 |
For SILVIA Turbine Kit T517Z 8.0cm2 |
|
10.0 cm² |
P765 |
11500124 |
¥216,700 |
¥197,000 |
For SILVIA Turbine Kit T517Z 10.0cm2 |
|
|
8.0 cm² |
P750 |
11500121 |
¥216,700 |
¥197,000 |
For SKYLINE GT-R Turbine Kit T517Z 8.0cm2 |
|
|
10.0 cm² |
P750 |
11500122 |
¥216,700 |
¥197,000 |
For SKYLINE GT-R Turbine Kit T517Z 10.0cm2 |
|
|
T518Z |
8.0 cm² |
P765 |
11500125 |
¥228,800 |
¥208,000 |
For SILVIA Turbine Kit T518Z 8.0cm2 |
|
10.0 cm² |
P765 |
11500126 |
¥228,800 |
¥208,000 |
For SILVIA Turbine Kit T518Z 10.0cm2 |
|
|
T620Z |
10.0 cm² |
P850 |
11500220 |
¥228,800 |
¥208,000 |
For JZX100 Turbine Kit T620Z 10.0cm2 |
■ GReddy Turbocharger Specification Chart
|
LINE UP |
Compressor |
Power range |
Compressor
|
Compressor
|
Turbine
|
Maximum
|
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|
2.2kg/kwh KW(PS) |
IN DIA mm | OUT DIA mm | IN DIA mm | OUT DIA mm | OUT DIA mm | EX DIA mm | Exhaust Temperture ℃ | Boost kpa | ||
|
TD04H
|
15G |
147-221 |
43.5 |
56 |
60
|
50
|
45.6
|
52
|
950
|
200
|
|
19T |
184-235 |
46 |
58 |
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|
TD05 |
14B |
184-257 |
43 |
58 |
50 |
45 |
47.6 |
56 |
||
|
16G |
184-257 |
46.5 |
60 |
190
|
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|
TD05H |
16G |
191-265 |
49.1 |
56 |
||||||
|
TD05SH |
18G |
211-294 |
50.5 |
68 |
80 |
50 |
||||
|
TD06S |
20G |
211-316 |
52.6 |
68 |
80 |
50 |
55.3 |
65 |
190
|
|
|
TD06SL2 |
20G |
54.1 |
61 |
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|
TD06SH |
20G |
257-331 |
58.8 |
67 |
||||||
|
T67 |
25G |
294-405 |
60.5 |
78 |
100 |
65 |
54.1 |
61 |
||
|
TD06SH |
25G |
368-441 |
58.8 |
67 |
||||||
|
TD07S |
25G |
405-463 |
65 |
74 |
900 |
|||||
|
T78 |
29D |
441-493 |
64 |
90 |
100 |
70 |
65 |
74 |
||
|
33D |
441-530 |
65.8 |
90 |
|||||||
|
T88 |
33D |
478-552 |
72.3 |
85 |
||||||
|
34D |
515-625 |
70 |
95 |
220 |
||||||
|
T88H |
34D |
588-662 |
79 |
90 |
||||||
|
38GK |
662-772 |
75.9 |
98 |
250 |
||||||
|
T517Z |
0616G |
211-279 |
48.1 |
68 |
Each has its own dedicated shape |
49.1 |
56 |
950 |
190 |
|
|
T518Z |
18G |
211-294 |
50.5 |
68 |
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|
T618Z |
18G |
55.3 |
65 |
|||||||
|
T620Z |
20G |
211-316 |
52.6 |
68 |
58.8 |
67 |
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*The dimension of Inlet/ outlet of compressor cover is out side diameter *20℃, 1013hpa
GReddy Turbocharger feature
Mechanism and Features of Turbocharger Supercharging
High-efficiency Compressor Turbine Housing Wheel
Turbo is working as using the pressure of exhaust came out from the engine. Then exhaust pressure is spinning the compressor wheel on the same axis to increase the pressure.Thus if you put smaller turbine wheel you can get more low torque engine but hard to spinning on higher revs. This is simply related to”shape and size of turbine wheel” and “relation between exhaust and compression”are effecting to most of engine characteristic .Also if you start to understanding the principle of turbo, you might to start to thinking about “why don’t you put small turbine wheel with big compressor wheel to get efficient turbo pressure out from smaller engine?” Yes!! this is the one of our specialty technology ,”Hybrid turbine”. considering the balance of spinning compressor wheel, we made high efficient size of wheel and number of wing selection.Further we pick up the best housing selection for each engine characters.These are “GReddy turbo charger”
Superiority of Floating metal
GReddy turbochargers are committed to floating metal bearings. This is because it’s the bearing system with the least resistance ‘during actual use’. When disassembling a floating metal bearing, it may appear to have high frictional resistance as metal surfaces seem to be in contact. Also, when manually rotating the compressor wheel while the turbocharger is cold, it may feel heavier than a ball bearing system. So why are floating metal bearings superior? The answer lies in the presence of ‘engine oil’. When the engine starts and oil pressure builds up, with the engine oil warmed up, the shaft floats in the center of the bearing, surrounded by oil. This is the ‘fluid bearing system’ where the shaft is supported solely by oil. Hence the name ‘floating’ metal. In other words, when disassembling the bearing, we’re working without the most crucial component – ‘engine oil’ – so we’re essentially overlooking the most important device. During actual use, the space between the bearing and shaft is filled with oil, and the metal surfaces never touch. To put it simply, comparing the rotation resistance of the compressor wheel when the turbocharger is cold doesn’t reflect the true performance of floating metal bearings. What matters for a turbocharger is its performance during actual use, not when the engine is stopped. When the turbocharger reaches its operating temperature, which do you think has less resistance: a bearing system where metal surfaces are in contact (even if at points), or a fluid bearing where metal never touches? Moreover, the fact that fluid bearings don’t require coolant circulation like ball bearings indicates that there’s no frictional heat generated around the bearing. When pursuing performance and convenience at the actual operating temperatures of turbochargers, we inevitably arrive at the fluid bearing system of floating metal bearings.