Product Description
Rotary Drilling Rig Gear Box 132777-26 Planetary For Sany, Zoomlion, Sunward, Bauer,77WH102/12 Soilmec And IMT
Hydraulic piston pump A11VLO40, A11VLO60, A11VLO75, A11VLO95, A11VLO130, A11VLO145, A11VLO190, A11VLO260
| Description |
Open circuit
Nominal pressure 5100 CZPT (350 bars)
Maximum pressure 5800 CZPT (400 bars)
The A11VLO variable axial piston pump of swash plate design for hydrostatic drives in open circuit hydraulic system
– Designed primarily for use in mobile applications.
– The pump operates under self-priming conditions, with tank pressurization, or with an optional built-in charge pump (impeller).
– A comprehensive range of control options is available matching any application requirement.
– Power control option is externally adjustable, even when the pump is running.
– The through drive is suitable for adding gear pumps and axial piston pumps up to the same size, i.e. 100% through drive.
– The output flow is proportional to the drive speed and infinitely variable between qV max and qV min = 0.
– Control devices: LR, LR.C, LR3, LG1, LG2, DR, DRS, DRL, DH1, DH2, DH.D, DH.G, EP1, EP2, DE.D, EP.G, etc.
(SAUER 90)MPT044/M44 MAIN PUMP PARTS
1,piston shoe,9pcs.
2,cylinder block,1pc.
3,retainer plate,1pc.
4,valve plate RH,1pc.
5,ball guide, 1pc.
If you are interested in other parts, please contact us!Thanks!
| Our company now supply a large number of piston pumps, motors, reducers and related spare parts. The main manufacturers are: Rexroth, Hitachi, Komatsu, Kawasaki, Caterpillar, NACHI, Toshiba, CZPT / Kato etc. |
| The specific models are: |
| Hitachi series: |
| HPV050; HPV080; ZX120-6 main pump (HPK055); HPV091 (EX200-2/3, EX120-2 single pump); HPV102 (EX200-5/6); HPV116 (EX200-1); HPV118 (ZX200-3, ZX270 main pump)etc. |
| Komatsu excavator main pump series: |
| HPV35 (PC60); HPV55 (PC120); HPV90 (PC200-3); HPV90 (PC200-5); PHV95 (PC200-6, PC120-6 except the pump shaft); HPV132 (PC300-7, PC400-6); HPV160 (PC300/400-3/5); HPV135; PC30UU; PC40-8 main pump; PC50; PC60, etc. |
| Caterpillar series: |
| VRD63 (CAT120) double pump; SBS80 (CAT312C) main pump; E200B (new) double pump; AP-12 double pump; AP-14 (CAT325C); CAT320C double pump; SPK10/10 (E200B) double pump; SPV10/10 (MS180) double pump; CAT12G; CAT14G/16G; CAT215; CAT245; CAT330B travel motor; PSV450 (AP-12) walking; CAT992; CAT330C walking; CAT385H. |
| Kayab (KYB, kayaba) series: |
| PSVD2-16E (Shanhe Intelligent 1.6-2 tons); PSVD2-21C (KYB); PSVD2-21E (KYB) 4T/SVD22 small CZPT main pump; PSVD2-26E/27E (KYB); KYB-25CC (Ishikawashima 45, CZPT K040/K045); Ishikawajima 60; PSVL-54 (KYB CZPT 6 ton 155 excavator). |
| The CZPT series: |
| PVD-2B-32L; PVD-2B-34 walking; PVD-2B-34L (small CZPT main pump); PVD-2B-36L/38/40; PVD-2B-42; PVD-2B-63; PVD45; 130; PVK-2B-505 (ZAX55 main pump); YC35-6 CZPT small CZPT rotary motor; YC35-6 CZPT small CZPT travel motor; PCL-200-18B (Yuchai 55 revolution); Bobcat 331 excavator ( Turn); Bobcat 337 (walking motor). |
| Toshiba series: |
| SG02; SG571 (MFB40); SG04 (MFB80); SG08 (MFB160); SG12; SG20 (MFB250); PVB92 (PVC90RC08/PVC70R) (Toshiba 8 tons, CZPT 8.5 tons excavator); PV090; PV092 (PV080 universal) ;PSVS-90. |
| JEIL series: |
| JMV-44/22; JMV-53/34 (6-8 ton small excavator travel motor); JMF-64; JMV 147/95; JMF-151-VBR (22SM1510117); JMF-155. |
| LPVD45; LPVD64; LPVD75; LPVD90; LPVD100; LPVD100 new (914); LPVD125; LPVD125 new; LPVD140; LPVD250; LPVD260. |
| Kobelco / Kato Series: |
| SK250-8 main pump; SK200-1/3 travel motor; SK220-3 (MA340 travel motor); SK200-6 travel motor; SK200-6 walking new; SK320 travel motor; M3V150 (SK220-2) travel motor; SK430 walking Motor; CZPT 400 excavator motor; HD450V-2 (Kato); HD3000; DH55 (Daewoo 55 excavator slewing motor); T3X128/Daewoo 300-7 slewing; CZPT 225-7 walking; CZPT DH370 slewing; CZPT 60-7 slewing Motor; modern 480 swing motor. |
| Kawasaki series: |
| K3SP36C (SDV36) 8 ton medium excavator main pump; K3V63DT (K3V63BDT); K3V112DT; K3V140DT; K3V180DT; K3V280; K3VG280; K3VG180; K3VL45; K5V80; K5V140 (Doosan 300-7); K5V160 (modern 300-6 main pump) ; M2X63; M2X96 (EX200-2); M2X120; M2X146 (EX200-5); M2X150/170 (EX400); M2X210 (EX270/280/300); M5X130 |
| Nabtesco series: |
| GM05VL; GM05VA; GM06VL (60 CZPT walking); GM07VA (Daewoo DH55, CZPT walking 60-7); GM08 (Komatsu 60-3 / 5 walking); GM09 (MSPG06-571 / PC60-7 travel motor); GM10; GM17 (PC120-3 / 5 walking); GM18; GM23; GM30H; GM35VA; GM35VL (travel motors); GM38VB (SK200-8, CZPT travel motor 1571-3); DNB08. |
| Rexroth Series: |
| A4V40; A4V56; A4V71; A4V125; A4V250; A4VFO28; A4VSO40; A4VSO71; A4VSO125; A4VSO180; A4VSO250; A4VSO355; A4VSO500; A4VF500 / A4F500; A4VG28 (A4F571); A4VG50;; A4VG40; A4VG45 A4VG56; A4VG71; A4VTG71; A4VG90 (A4VT90HW / 32R); A4VHW90; A4VTG90 charge pump (Laid thick); A4VG125; A4VG125 Charge pump; A4VG125 charge pump (general use type); A4VG125 charge pump (A10VO28 string type); A4VG12 charge pump (large). |
| Rexroth bent axis pump series: |
| A2F5;A2F12;A2F23;A2VK28;2VK28;A2F28;A2F55;A2F80;A2F107;A2F160;A2F200; A2V225;A2F250;A2V500;A2V915;A2F355;A2F500;A2F1000;A2FO10;A2FO12;A2FO16;A2FO23;A2FO28;A2FO32;A2FO45; A2FO56; A2FO63; A2FO80; A2FO90 / A2FE90; A2FO107; A2FO125 (A2FM125); A2FO200;; A2FO160; A2FO180 A2FO250; A2FO500; A6V28; A7V55 / A8V55; A7V58; A7V80 / A8V80; A7V107 / A8V107; A7V160 / A8V160; A7V200; A7V225 ; A7V250; A7V355; A7V500; A6VM / A7V1000; A6VM / A7VO12; A7VO28; A7VO55; A7VO80; A7VO107; A7VO160; A6VM160; A6VE160; A6VM200; A6VM500; A7VO172; A7VO200; A7VO250; A7VO355; A7VO500. |
| Sauer Series: |
| PV20; PV21 (PVD21); PV22; PVD22 dual pump; PV23 (PVD23); PV24; SPV6 / 119; PV25; PV26; PV112; OPV27; MF16A; MFO35; MF500; MPVO46 / M46; MPR63; MPV45. |
| Eaton Series: |
| 3321/3331 (Eaton 006); CZPT 3322 (EATON3322); 4621/4621-007; 5421/5431 (Eaton 23); Case 1460 (CASE1460); Case CS05A; CZPT 3932-243; CZPT 6423; 7621 (Eaton 24-7620); Road roller (Eaton 78462). |
| Vickers series: |
| PVE19;TA19;PVE21;PVH45;PVH57;PVH74;PVH81;PVH98;PVH106(HPN-1398);PVH131;PVH141;PVB5;PVB6;PVB10;PVB15(PVQ32 some common);PVB20;PVB29;PVBQA29-SR;PVQ40 /50; PVB110; TB35; B45. |
| LINDE series |
| HPR55/75/105/135/165/210/280 ;MPV45-01 MPV63-01; HMR75/105/135/165;MPF55-01; MPR28/45/63/71; HPR75/90/100/130/160;BPV35/50/70/100/200;B2PV35/50/75/105/140;BMF35/55/75/105/140;BMV35/55/75/105/135; BPR55/75/105/140/186/260;HPV55T/75/105/135/165/210; HMF28/35/50/55/75/105/135/165/210;HPV130-01. |
| Parker series |
| PVP16/23/33/41/48/60/76/100/140;PVM16/23/28;PV016/571/571/571/032/040/046/063;F11-005/006/012/014/019/10/28/39/80/110/150/250;F12-030/040/060/080/110/125/150/250;V12-060/080 V14-110/160;P2/P3-060/075/105/145;PAVC 33/38/65/100 |
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
| Structure: | Axial Plunger Pump |
|---|---|
| Cylinder Number: | Single Cylinder |
| Drive Mode: | Hydraulic Driven Reciprocating Pump |
| Pump Shaft Position: | Horizontal |
| Type: | V Type |
| Power: | Hydraulic |
| Customization: |
Available
| Customized Request |
|---|
Planetary Gearbox
This article will explore the design and applications of a planetary gearbox. The reduction ratio of a planetary gearbox is dependent on the number of teeth in the gears. The ratios of planetary gearboxes are usually lower than those of conventional mechanical transmissions, which are mainly used to drive engines and generators. They are often the best choice for heavy-duty applications. The following are some of the advantages of planetary gearboxes.
planetary gearboxes
Planetary gearboxes work on a similar principle to solar systems. They rotate around a center gear called the sun gear, and two or more outer gears, called planet gears, are connected by a carrier. These gears then drive an output shaft. The arrangement of planet gears is similar to that of the Milky Way’s ring of planets. This arrangement produces the best torque density and stiffness for a gearbox.
As a compact alternative to normal pinion-and-gear reducers, planetary gearing offers many advantages. These characteristics make planetary gearing ideal for a variety of applications, including compactness and low weight. The efficiency of planetary gearing is enhanced by the fact that ninety percent of the input energy is transferred to the output. The gearboxes also have low noise and high torque density. Additionally, their design offers better load distribution, which contributes to a longer service life.
Planetary gears require lubrication. Because they have a smaller footprint than conventional gears, they dissipate heat well. In fact, lubrication can even lower vibration and noise. It’s also important to keep the gears properly lubricated to prevent the wear and tear that comes with use. The lubrication in planetary gears also helps keep them operating properly and reduces wear and tear on the gears.
A planetary gearbox uses multiple planetary parts to achieve the reduction goal. Each gear has an output shaft and a sun gear located in the center. The ring gear is fixed to the machine, while the sun gear is attached to a clamping system. The outer gears are connected to the carrier, and each planetary gear is held together by rings. This arrangement allows the planetary gear to be symmetrical with respect to the input shaft.
The gear ratio of a planetary gearbox is defined by the sun gear’s number of teeth. As the sun gear gets smaller, the ratio of the gear will increase. The ratio range of planetary gears ranges from 3:1 to ten to one. Eventually, however, the sun gear becomes too small, and the torque will fall significantly. The higher the ratio, the less torque the gears can transmit. So, planetary gears are often referred to as “planetary” gears.
Their design
The basic design of a Planetary Gearbox is quite simple. It consists of three interconnecting links, each of which has its own torque. The ring gear is fixed to the frame 0 at O, and the other two are fixed to each other at A and B. The ring gear, meanwhile, is attached to the planet arm 3 at O. All three parts are connected by joints. A free-body diagram is shown in Figure 9.
During the development process, the design team will divide the power to each individual planet into its respective power paths. This distribution will be based on the meshing condition of all gears in the system. Then, the design team will proceed to determine the loads on individual gear meshes. Using this method, it is possible to determine the loads on individual gear meshes and the shape of ring gear housing.
Planetary Gearboxes are made of three gear types. The sun gear is the center, which is connected to the other two gears by an internal tooth ring gear. The planet pinions are arranged in a carrier assembly that sets their spacing. The carrier also incorporates an output shaft. The three components in a Planetary Gearbox mesh with each other, and they rotate together as one. Depending on the application, they may rotate at different speeds or at different times.
The planetary gearbox’s design is unique. In a planetary gearbox, the input gear rotates around the central gear, while the outer gears are arranged around the sun gear. In addition, the ring gear holds the structure together. A carrier connects the outer gears to the output shaft. Ultimately, this gear system transmits high torque. This type of gearbox is ideal for high-speed operations.
The basic design of a Planetary Gearbox consists of multiple contacts that must mesh with each other. A single planet has an integer number of teeth, while the ring has a non-integer number. The teeth of the planets must mesh with each other, as well as the sun. The tooth counts, as well as the planet spacing, play a role in the design. A planetary gearbox must have an integer number of teeth to function properly.
Applications
In addition to the above-mentioned applications, planetary gearing is also used in machine tools, plastic machinery, derrick and dock cranes, and material handling equipments. Further, its application is found in dredging equipment, road-making machinery, sugar crystallizers, and mill drives. While its versatility and efficiency makes it a desirable choice for many industries, its complicated structure and construction make it a complex component.
Among the many benefits of using a planetary gearbox, the ability to transmit greater torque into a controlled space makes it a popular choice for many industries. Moreover, adding additional planet gears increases the torque density. This makes planetary gears suitable for applications requiring high torque. They are also used in electric screwdrivers and turbine engines. However, they are not used in everything. Some of the more common applications are discussed below:
One of the most important features of planetary gearboxes is their compact footprint. They are able to transmit torque while at the same time reducing noise and vibration. In addition to this, they are able to achieve a high speed without sacrificing high-quality performance. The compact footprint of these gears also allows them to be used in high-speed applications. In some cases, a planetary gearbox has sliding sections. Some of these sections are lubricated with oil, while others may require a synthetic gel. Despite these unique features, planetary gears have become common in many industries.
Planetary gears are composed of three components. The sun gear is the input gear, whereas the planet gears are the output gears. They are connected by a carrier. The carrier connects the input shaft with the output shaft. A planetary gearbox can be designed for various requirements, and the type you use will depend on the needs of your application. Its design and performance must meet your application’s needs.
The ratios of planetary gears vary depending on the number of planets. The smaller the sun gear, the greater the ratio. When planetary stages are used alone, the ratio range is 3:1 to 10:1. Higher ratios can be obtained by connecting several planetary stages together in the same ring gear. This method is known as a multi-stage gearbox. However, it can only be used in large gearboxes.
Maintenance
The main component of a planetary gearbox is the planetary gear. It requires regular maintenance and cleaning to remain in top shape. Demand for a longer life span protects all other components of the gearbox. This article will discuss the maintenance and cleaning procedures for planetary gears. After reading this article, you should know how to maintain your planetary gearbox properly. Hopefully, you can enjoy a longer life with your gearbox.
Firstly, it is important to know how to properly lubricate a planetary gearbox. The lubricant is essential as gears that operate at high speeds are subject to high levels of heat and friction. The housing of the planetary gearbox should be constructed to allow the heat to dissipate. The recommended oil is synthetic, and it should be filled between 30 and 50 percent. The lubricant should be changed at least every six months or as needed.
While it may seem unnecessary to replace a planetary gearbox, regular servicing will help it last a long time. A regular inspection will identify a problem and the appropriate repairs are needed. Once the planetary gearbox is full, it will plug with gear oil. To avoid this problem, consider getting the unit repaired instead of replacing the gearbox. This can save you a lot of money over a new planetary gearbox.
Proper lubrication is essential for a long life of your planetary gearbox. Oil change frequency should be based on oil temperature and operating speed. Oil at higher temperatures should be changed more frequently because it loses its molecular structure and cannot form a protective film. After this, oil filter maintenance should be performed every few months. Lastly, the gearbox oil needs to be checked regularly and replaced when necessary.
editor by CX 2024-03-30