Product Description
dozer transmission& elements
match device
KO MATSU: D31, D50, D60, D65, D85-eighteen, D85-21, D155, D275, D355-3
SHXIHU (WEST LAKE) DIS.I: SD08, SD11, SD13, SD16, SD22, SD23, SD32, SD42 ,
TY130 TY160 TY220 TY230 TY320 SP1
57110-82255
01580-12218
01643-32260
1601N-90 Корзина сцепления
1601N-130 clutch plate
20J-eleven-00011 clutch shaft
GB/T307.1-91 release bearing
18J-twelve-00002 upper cardan
20J-twelve-00002 lower cardan
16Z-06-00006 bearing
16Z-06-00005 bearing
18J-16-20000 cylinder
18J-fifteen-12000 hydromotor of vibrator
20J-fifteen-00007 hydromotor of vibrator
20J-fifteen-00007s steering control pump
gear box pump
20S-fourteen-57100 cylinder
12Р-sixty one-08000 pump ()
12Р-71-14000 pump ()
13Р-twelve-57100 cardan ( transmission shaft)
D02А-109-30а gasket (for cylinder block head)
D05-101-30 piston
D02A-104-30a liner
D02А-111-01а bearing
D02А-a hundred and ten-01а bearing
D02А-112-01 bearing
D05-107-01 piston ring
D05-108-01 piston ring
D05-002-01 piston ring
D05-113-30 bearing
157-thirty-0571 “loafer, remaining”
“loafer, appropriate”
a hundred seventy five-30-33214 “idler hitch (internal, outer)”
176-thirty-43111 “loafer hitch (inner, outer)”
175-thirty-33282 “idler hitch (interior, outer)”
176-thirty-43121 “loafer hitch (internal, outer)”
0571 3-71103 feed pump
one hundred seventy five-seventy one-11454 bolt
a hundred seventy five-71-11530 nut
a hundred and fifty five-thirty-13230 rubber dump with spring for idler
157-27-31114 hub assy left
157-27-31124 hub assy right
a hundred seventy five-15-05716 transmission gearbox
a hundred seventy five-thirty-0571 ROLLER TOP
154-71-41270 bolt
154-70-22270 nut
154-27-15181 “Hub, sprocket”
175-27-31132 GASKET
175-27-31463 FLANGE
57110-31850 BOLT
01602-01854 WASHER
a hundred seventy five-27-31495 PINION
a hundred and seventy-09-13210 BEARING
one hundred seventy five-27-31161 CAGE
07000- 0571 5 O-RING
0571 3-10120 SEAL
57110-31640 BOLT
01602-01648 WASHER
a hundred and seventy-27-11232 SPACER
one hundred seventy-27-11246 WASHER
one hundred seventy-21-12141 NUT
57110-31225 BOLT
175-27-31170 COVER
07000-5710 O-RING
a hundred seventy five-27-00051 SHIM ASS’Y
170-09-13220 BEARING
a hundred seventy five-27-31233 PINION
one hundred seventy five-27-31255 GEAR
one hundred seventy five-27-31260 KEY
a hundred seventy five-27-31270 SPACER
a hundred seventy five-27-31282 HOLDER
175-27-32470 WASHER
57110-31230 BOLT
a hundred and seventy-09-13230 BEARING
170-09-13240 BEARING
a hundred seventy five-27-31291 COVER
a hundred seventy five-27-00061 SHIM ASS’Y
07000-05260 O-RING
57110-32050 BOLT
01602-57160 WASHER
5711-01842 PIN
57110-32035 BOLT
01602-57160 WASHER
07040-11812 PLUG
07000-57114 O-RING
07044-03620 PLUG
07000-03032 O-RING
57110-32050 BOLT
01602-57160 WASHER
57110-31640 BOLT
01602-01648 WASHER
175-27-31452 GUARD
57110-32455 BOLT
01602-57172 WASHER
07041-13612 PLUG
07000-03032 O-RING
208-926-5410 1.4
6732-eleven-8181
6738-11-3100
6732-41-4541
6732-11-1610
6732-eleven-1620
6735-eleven-1821
6731-81-8710
6732-21-3811
6736-21-3450
6735-21-6261
6735-21-4191
6735-K2-3001
6732-21-4171
6732-31-2420
6738-31-2031
6736-29-2110
6151-12-1810
6151-22-2220
6151-35-1571
6152-32-2510
6152-twelve-3110
6150-21-8571
6150-21-8050
6150-32-2030
6151-31-2410
6150-31-3130
6151-31-3040
11G-32-57102
11G-32-57143
113-27-31320
21W-thirty-00050
154-27-15181 “Hub, sprocket”
“Keep track of shoe ass’y (460mm, forty five link)”
10Y-forty-03000 Idler ass’y
10Y-forty-10000C “Monitor roller ass’y, S.F.”
10Y-40-11000C “Keep track of roller ass’y, D.F.”
10Y-40-07000 Carrier roller ass’y
10Y-eighteen-00011 Segment block (3)
10Y-eighteen-00012 Segment block (2)
09203-21860 “Bolt, segment”
01803-01824 “Nut, segment”
154-27-11257 Gear
one hundred seventy-09-13160 Bearing
a hundred and fifty-09-13260 Bearing
154-27-11313 Gear
Type: | Transmission Core |
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Application: | Bulldozer |
Certification: | ISO9001: 2000 |
Condition: | New |
HS: | 84314999 |
Fit Machine: | SD7 SD7K SD7LGP SD7n Dozer |
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Customization: |
Available
|
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Type: | Transmission Core |
---|---|
Application: | Bulldozer |
Certification: | ISO9001: 2000 |
Condition: | New |
HS: | 84314999 |
Fit Machine: | SD7 SD7K SD7LGP SD7n Dozer |
###
Customization: |
Available
|
---|
Types of Bevel Gears
Bevel Gears are used in a number of industries. They are used in wheeled excavators, dredges, conveyor belts, mill actuators, and rail transmissions. A bevel gear’s spiral or angled bevel can make it suitable for confined spaces. It is also used in robotics and vertical supports of rolling mills. You can use bevel gears in food processing processes. For more information on bevel gears, read on.
Spiral bevel gear
Spiral bevel gears are used to transmit power between two shafts in a 90-degree orientation. They have curved or oblique teeth and can be fabricated from various metals. Bestagear is one manufacturer specializing in medium to large spiral bevel gears. They are used in the mining, metallurgical, marine, and oil fields. Spiral bevel gears are usually made from steel, aluminum, or phenolic materials.
Spiral bevel gears have many advantages. Their mesh teeth create a less abrupt force transfer. They are incredibly durable and are designed to last a long time. They are also less expensive than other right-angle gears. They also tend to last longer, because they are manufactured in pairs. The spiral bevel gear also reduces noise and vibration from its counterparts. Therefore, if you are in need of a new gear set, spiral bevel gears are the right choice.
The contact between spiral bevel gear teeth occurs along the surface of the gear tooth. The contact follows the Hertz theory of elastic contact. This principle holds for small significant dimensions of the contact area and small relative radii of curvature of the surfaces. In this case, strains and friction are negligible. A spiral bevel gear is a common example of an inverted helical gear. This gear is commonly used in mining equipment.
Spiral bevel gears also have a backlash-absorbing feature. This feature helps secure the thickness of the oil film on the gear surface. The shaft axis, mounting distance, and angle errors all affect the tooth contact on a spiral bevel gear. Adjusting backlash helps to correct these problems. The tolerances shown above are common for bevel gears. In some cases, manufacturers make slight design changes late in the production process, which minimizes the risk to OEMs.
Straight bevel gear
Straight bevel gears are among the easiest types of gears to manufacture. The earliest method used to manufacture straight bevel gears was to use a planer equipped with an indexing head. However, improvements have been made in manufacturing methods after the introduction of the Revacycle system and the Coniflex. The latest technology allows for even more precise manufacturing. Both of these manufacturing methods are used by CZPT. Here are some examples of straight bevel gear manufacturing.
A straight bevel gear is manufactured using two kinds of bevel surfaces, namely, the Gleason method and the Klingelnberg method. Among the two, the Gleason method is the most common. Unlike other types of gear, the CZPT method is not a universal standard. The Gleason system has higher quality gears, since its adoption of tooth crowning is the most effective way to make gears that tolerate even small assembly errors. It also eliminates the stress concentration in the bevelled edges of the teeth.
The gear’s composition depends on the application. When durability is required, a gear is made of cast iron. The pinion is usually three times harder than the gear, which helps balance wear. Other materials, such as carbon steel, are cheaper, but are less resistant to corrosion. Inertia is another critical factor to consider, since heavier gears are more difficult to reverse and stop. Precision requirements may include the gear pitch and diameter, as well as the pressure angle.
Involute geometry of a straight bevel gear is often computed by varying the surface’s normal to the surface. Involute geometry is computed by incorporating the surface coordinates and the theoretical tooth thickness. Using the CMM, the spherical involute surface can be used to determine tooth contact patterns. This method is useful when a roll tester tooling is unavailable, because it can predict the teeth’ contact pattern.
Hypoid bevel gear
Hypoid bevel gears are an efficient and versatile speed reduction solution. Their compact size, high efficiency, low noise and heat generation, and long life make them a popular choice in the power transmission and motion control industries. The following are some of the benefits of hypoid gearing and why you should use it. Listed below are some of the key misperceptions and false assumptions of this gear type. These assumptions may seem counterintuitive at first, but will help you understand what this gear is all about.
The basic concept of hypoid gears is that they use two non-intersecting shafts. The smaller gear shaft is offset from the larger gear shaft, allowing them to mesh without interference and support each other securely. The resulting torque transfer is improved when compared to conventional gear sets. A hypoid bevel gear is used to drive the rear axle of an automobile. It increases the flexibility of machine design and allows the axes to be freely adjusted.
In the first case, the mesh of the two bodies is obtained by fitting the hyperboloidal cutter to the desired gear. Its geometric properties, orientation, and position determine the desired gear. The latter is used if the desired gear is noise-free or is required to reduce vibrations. A hyperboloidal cutter, on the other hand, meshes with two toothed bodies. It is the most efficient option for modeling hypoid gears with noise concerns.
The main difference between hypoid and spiral bevel gears is that the hypoid bevel gear has a larger diameter than its counterparts. They are usually found in 1:1 and 2:1 applications, but some manufacturers also provide higher ratios. A hypoid gearbox can achieve speeds of three thousand rpm. This makes it the preferred choice in a variety of applications. So, if you’re looking for a gearbox with a high efficiency, this is the gear for you.
Addendum and dedendum angles
The addendum and dedendum angles of a bevel gear are used to describe the shape and depth of the teeth of the gear. Each tooth of the gear has a slightly tapered surface that changes in depth. These angles are defined by their addendum and dedendum distances. Addendum angle is the distance between the top land and the bottom surface of the teeth, while dedendum angle is the distance between the pitch surface and the bottom surface of the teeth.
The pitch angle is the angle formed by the apex point of the gear’s pitch cone with the pitch line of the gear shaft. The dedendum angle, on the other hand, is the depth of the tooth space below the pitch line. Both angles are used to measure the shape of a bevel gear. The addendum and dedendum angles are important for gear design.
The dedendum and addendum angles of a bevel gear are determined by the base contact ratio (Mc) of the two gears. The involute curve is not allowed to extend within the base diameter of the bevel gear. The base diameter is also a critical measurement for the design of a gear. It is possible to reduce the involute curve to match the involute curve, but it must be tangential to the involute curve.
The most common application of a bevel gear is the automotive differential. They are used in many types of vehicles, including cars, trucks, and even construction equipment. They are also used in the marine industry and aviation. Aside from these two common uses, there are many other uses for bevel gears. And they are still growing in popularity. But they’re a valuable part of automotive and industrial gearing systems.
Applications of bevel gears
Bevel gears are used in a variety of applications. They are made of various materials depending on their weight, load, and application. For high-load applications, ferrous metals such as grey cast iron are used. These materials have excellent wear resistance and are inexpensive. For lower-weight applications, steel or non-metals such as plastics are used. Some bevel gear materials are considered noiseless. Here are some of their most common uses.
Straight bevel gears are the easiest to manufacture. The earliest method of manufacturing them was with a planer with an indexing head. Modern manufacturing methods introduced the Revacycle and Coniflex systems. For industrial gear manufacturing, the CZPT uses the Revacycle system. However, there are many types of bevel gears. This guide will help you choose the right material for your next project. These materials can withstand high rotational speeds and are very strong.
Bevel gears are most common in automotive and industrial machinery. They connect the driveshaft to the wheels. Some even have a 45-degree bevel. These gears can be placed on a bevel surface and be tested for their transmission capabilities. They are also used in testing applications to ensure proper motion transmission. They can reduce the speed of straight shafts. Bevel gears can be used in many industries, from marine to aviation.
The simplest type of bevel gear is the miter gear, which has a 1:1 ratio. It is used to change the axis of rotation. The shafts of angular miter bevel gears can intersect at any angle, from 45 degrees to 120 degrees. The teeth on the bevel gear can be straight, spiral, or Zerol. And as with the rack and pinion gears, there are different types of bevel gears.
editor by czh 2023-01-20