제품 설명
Good Price K Series Helical Bevel Gearbox
제품 설명
설명: K 시리즈 헬리컬 베벨 기어박스
개요
(1) 입력 모드: 결합 모터, 벨트 모터, 입력 샤프트 또는 연결 플랜지.
(2) 직각 출력.
(3) 컴팩트한 구조.
(4) 단단한 치아면.
(5) 더 큰 토크를 전달하고 높은 적재 용량을 갖습니다.
(6) 고정밀 기어는 장치의 안정적인 작동과 원활한 전달을 보장합니다.
(7) 소음이 적고 수명이 길다.
(8) 큰 중첩 계수, 내마모성.
K 시리즈 기어 장치는 다음과 같은 설계로 제공됩니다.
KAZ..Y..중공축이 있는 짧은 플랜지 장착형 헬리컬-베벨 기어 장치
K…Y…CHINAMFG 샤프트가 있는 발 장착형 헬리컬 베벨 기어 장치
KAT…Y…토크 암 장착형 헬리컬-베벨 기어 유닛(중공축 포함)
KAB…Y…중공축이 있는 발 장착형 헬리컬-베벨 기어 장치
K(KF,KA,KAF,KAB,KAZ)S…축 입력 헬리컬-베벨 기어 유닛
KA…Y…중공축이 있는 헬리컬-베벨 기어 유닛
KA(K, KF, KAF, KAB, KAZ)R..Y..조합형 헬리컬-베벨 기어 유닛
KF…Y…CHINAMFG 샤프트가 장착된 플랜지형 헬리컬-베벨 기어 유닛
KA(K, KF, KAF, KAZ)S…R…축 입력 조합형 헬리컬-베벨 기어 유닛
KAF…Y…플랜지 장착형 중공축 헬리컬-베벨 기어 유닛
KA(K, KF, KAF, KAB, KAZ)…Y…사용자 모터 또는 특수 1을 장착할 경우 플랜지를 연결해야 합니다.
구조:
| 케이(-) |
케이(A) | K(F) | 입력 전력 범위 | 출력 속도 | 출력 토크 |
| 발에 장착하는 | 속이 빈 샤프트 산출 |
플랜지 장착형 | 0.18-200kW | 0.1-270r/min | 최대 50000Nm |
입력 전력 정격 및 최대 토크:
| 크기 |
38 | 48 | 58 | 68 | 78 | 88 | 98 | 108 | 128 | 158 | 168 | 188 |
| 구조 |
K KA KF KAF KAZ KAT KAB | |||||||||||
| 입력 전력 정격(kw) |
0.18~ 3.0 |
0.18~ 3.0 |
0.18~ 5.5 |
0.18~ 5.5 |
0.37~ 11 |
0.75~ 22 |
1.3~ 30 |
3~ 45 |
7.5~ 90 |
11~ 160 |
11~ 200 |
18.5~ 200 |
| 비율 | 5.36~ 106.38 |
5.81~ 131.87 |
6.57~ 145.15 |
7.14~ 44.79 |
7.22~ 192.18 |
7.19~ 197.27 |
8.95~ 175.47 |
8.74~ 141.93 |
8.68~ 146.07 |
12.66~ 150.03 |
17.35~1 64.44 |
17.97~ 178.37 |
| 최고 토크(Nm) |
200 | 400 | 600 | 820 | 1550 | 2770 | 4300 | 8000 | 13000 | 18000 | 32000 | 50000 |
기어 장치 무게:
| 크기 |
38 | 48 | 58 | 68 | 78 | 88 | 98 | 108 | 128 | 158 | 168 | 188 |
| 무게 |
11 | 20 | 27 | 33 | 57 | 85 | 130 | 250 | 380 | 610 | 1015 | 1700 |
가중치는 평균값이며 참고용으로만 제공됩니다.
최대 토크란 지정된 크기에 대해 서로 다른 비율과 관련된 최대 토크 중 가장 큰 값을 의미합니다.
정격 출력: 0.18KW~200KW
정격 토크: 최대 50000N·m
기어 배열: 베벨 및 헬리컬, 경화 처리된 기어박스
입력 속도: 4극, 6극 및 8극 모터의 50Hz 또는 60Hz
비율: 5.36~192.18
Product Pictures:
Our company :
Customer visiting:
FAQ:
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| Application: | Motor, Machinery, Industry |
|---|---|
| Function: | Change Drive Torque, Speed Changing, Speed Reduction |
| Layout: | Right Angle |
| Hardness: | Hardened Tooth Surface |
| Installation: | Horizontal Type |
| Step: | Three-Step |
| Customization: |
Available
| Customized Request |
|---|
Minimizing Backlash and Ensuring Efficient Power Transfer in Bevel Gearboxes
Bevel gearboxes are meticulously designed to minimize backlash and optimize power transfer efficiency, ensuring smooth and precise motion in mechanical systems.
Several design considerations contribute to minimizing backlash and enhancing power transfer:
- Tooth Profile and Quality: High-precision tooth profiles with minimal clearance between mating gears reduce backlash. The use of advanced manufacturing techniques ensures consistent gear quality and accurate tooth engagement.
- Preload and Contact Pattern: Properly applied preload and optimized contact patterns between the bevel gear teeth enhance meshing accuracy, reducing the potential for backlash and improving load distribution.
- Gearbox Rigidity: Stiff and rigid gearbox housing and components help maintain precise gear alignment, reducing the effects of deflection and misalignment that can lead to backlash.
- Bearing Selection: High-quality bearings with minimal play contribute to reduced backlash and smoother motion by minimizing axial and radial movement of the gears.
- 매끄럽게 하기: Adequate lubrication reduces friction, wear, and vibration, promoting efficient power transfer and minimizing backlash-related issues.
- Tolerances and Manufacturing Precision: Tight manufacturing tolerances and precision machining processes ensure consistent gear geometry, alignment, and positioning, minimizing any potential sources of backlash.
By incorporating these design principles and practices, bevel gearboxes are engineered to achieve tight backlash control and efficient power transmission. This makes them suitable for applications where precise motion control, accuracy, and reliability are crucial, such as robotics, aerospace, automotive, and industrial machinery.
Maintenance Procedures to Extend the Lifespan of Bevel Gearboxes
Proper maintenance is essential for extending the lifespan of bevel gearboxes. Here are specific procedures to ensure their longevity:
- Regular Inspection: Conduct routine visual inspections to identify signs of wear, damage, or misalignment. Check for unusual noise, vibration, or leaks.
- 매끄럽게 하기: Follow the recommended lubrication schedule and guidelines for the specific gearbox. Ensure the correct type and quantity of lubricant are used.
- Cleanliness: Keep the gearbox and its surrounding area clean to prevent dirt, debris, and contaminants from entering and causing damage.
- Tightening and Fasteners: Periodically check and tighten fasteners, bolts, and mounting components. Loose fasteners can lead to misalignment and excessive wear.
- 조정: Ensure proper alignment of the gearbox with connected components. Misalignment can cause increased friction, heat, and wear.
- Temperature Monitoring: Monitor the operating temperature of the gearbox to identify any overheating issues. Excessive heat can degrade lubricant and components.
- Seals and Gaskets: Inspect and replace seals and gaskets as needed to prevent leaks and contamination.
- Gear Tooth Inspection: Periodically check gear teeth for signs of pitting, chipping, or wear. Address any issues promptly to prevent further damage.
- Vibration Analysis: Implement vibration analysis to detect irregularities in the gearbox’s operation. Unusual vibrations may indicate misalignment or other mechanical issues.
- Replace Worn Parts: Replace worn or damaged components, such as bearings, gears, and seals, with genuine parts from the manufacturer.
- Professional Maintenance: Engage qualified technicians for more in-depth inspections and maintenance tasks, especially for complex gearboxes.
- Operating Conditions: Operate the gearbox within its specified load, speed, and temperature limits to prevent excessive stress and wear.
- Training: Ensure personnel are trained to operate, maintain, and troubleshoot the gearbox properly.
- Record Keeping: Maintain detailed records of maintenance activities, inspections, and repairs for reference and future planning.
By following these maintenance procedures, bevel gearboxes can maintain optimal performance, minimize downtime, and have an extended operational lifespan.
Significance of the Angle Between Bevel Gears in a Bevel Gearbox
The angle between bevel gears in a bevel gearbox plays a crucial role in determining how the rotational motion is transmitted between the intersecting shafts. This angle, often referred to as the “shaft angle” or “pitch angle,” has significant implications for the performance, efficiency, and load-bearing capacity of the gearbox.
The angle between bevel gears affects several key aspects:
- Mechanical Advantage: The angle determines the mechanical advantage or gear ratio of the bevel gearbox. A smaller angle results in a lower gear ratio, providing higher torque and slower rotational speed, while a larger angle yields a higher gear ratio, resulting in higher rotational speed and lower torque output.
- Efficiency: The angle affects the efficiency of power transmission. A smaller angle generally leads to higher efficiency due to improved load distribution and reduced friction losses.
- Load Distribution: Properly chosen angles contribute to even load distribution across the teeth of the bevel gears. Improper angles can cause uneven wear and premature failure.
- 공간 제약 조건: The angle impacts the overall dimensions of the bevel gearbox, which can be critical when space is limited in certain applications.
The angle between bevel gears is typically selected based on the specific requirements of the mechanical system and the intended application. It is a critical design consideration that engineers carefully analyze to ensure optimal performance and reliability of the bevel gearbox.
editor by CX 2024-04-15
