Product Description
3 Axle for Heavy Machine Transportation Low Bed Semi Trailer
Product Description
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Series No |
Name | Unit | Q’ty | Notice |
| 1 | Frame Dimensions | 15250*3000*1780 (1250 the height of the loading area/ Platform ) (wheelbase = 1360) Length of platform is 10.5mmLoading capacity 70Tons |
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| 2 | Axle | piece | 3 | 14 tons BPW (Wheel track width 2360) strengthened model( wheelbase 1360 ) |
| 3 | Tire | Piece | 12 | Fengshen 10.00R-20-18 |
| 4 | Rim | Piece | 12 | Domestic Zhengxing 7.5-20 |
| 5 | Leaf-spring | piece | 6 | Domestic 10 pieces of leaf springs, Which are underslung. 16thickness 100width |
| 6 | Suspension | Set | 3 | CHHGC REINFORCED TYPE |
| 7 | Relay Valve | whole vehicle |
WABCO relay valve | |
| 8 | Landing gear | pair | 1 | JOST A400 (linkage) |
| 9 | Kingpin 2 | PCS | 1 | Adjustable (JOST) KZ1012 |
| 9 | Kingpin 3.5 | PCS | 1 | Adjustable (JOST) KZ1412 will be taken away, without the fifth wheel. |
| 11 | Tie-in | PCS | 4 | WABCO |
| 12 | Braking air chamber | 2 | Double chambers | |
| 13 | Floor | 6 mm checkered | ||
| 14 | Rotary support | Every side can be increased 250mm, so if the rotary supports were open the width will become 3500mm |
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| 15 | Ramp | Pair | 1 | Width 800mm, double springs pattern, which is strengthened. As for the length, it depends on its technical specifications. |
| 16 | Top Flange thickness and Bottom Flange thickness |
20mm, 30MM width =250mm | ||
| Through beam /cross members |
12# channel steel | |||
| Side beam | 294MMH Pattern STEEL | |||
| longitudinal beam height | 600mm and the web plate thickness is 14mm | |||
| 17 | Front overhang / kingpin distance |
500MM | ||
| 18 | Spare tire holder | Will be welded on the gooseneck, and will be hand waving type. | ||
| 19 | color | Orange red | ||
| 20 | Paint | Antiseawater, whole trailer will be waxed in order to get protection from Seawater. |
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| 21 | Marks | With CHHGC marque. | ||
| 26 | Packaging | Two units should be put as One unit | ||
| 27 | NOTICE:We send you one WABCO control valve, one single air chamber, one double air chamber as the service spare parts for free in the LOW BED SEMITRILER |
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| 28 Notice(1) |
No.2. The bearing height and front overhang/ suspension of the low-bed Semitrailer will be designed according to the 6X4 Delong Big Truck. |
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| -2 | This configuration excludes ABS | |||
Certificate
Workshop
Business Partners
FAQ:
Q1. How to ship the vehicles?
A: By container, bulk ship, RORO.
Q2. Do you have RHD(right hand driving) vehicles?
A: Yes, noramlly we supply all LHD vehicles, and we have some RHD model vehicles.
Q3. What is your payment term?
A: We usually accept T/T or L/C depends on the quantity.
T/T, deposit in advance, and balance paid before delivery from factory.
Q4. Which model vehicles do you supply?
A: We supply all kinds of vehicles such as SUV, MPV, Pickup,van,truck, bus etc,.
Q5. What is your terms of delivery?
A: FOB, CIF.
Q6. How about your delivery time?
A: Generally, it will take 30 to 60 days after receiving your advance payment. The specific delivery time depends on the items and the quantity of your order.
Q7. Do you test all your goods before delivery?
A: Yes, we have 100% test before delivery.
Q8: What can you guarantee to your business partner?
A: Best price with good quality. We guarantee quality and after sale service to satisfy our business partners.
How to Determine the Quality of a Worm Shaft
There are many advantages of a worm shaft. It is easier to manufacture, as it does not require manual straightening. Among these benefits are ease of maintenance, reduced cost, and ease of installation. In addition, this type of shaft is much less prone to damage due to manual straightening. This article will discuss the different factors that determine the quality of a worm shaft. It also discusses the Dedendum, Root diameter, and Wear load capacity.
Root diameter
There are various options when choosing worm gearing. The selection depends on the transmission used and production possibilities. The basic profile parameters of worm gearing are described in the professional and firm literature and are used in geometry calculations. The selected variant is then transferred to the main calculation. However, you must take into account the strength parameters and the gear ratios for the calculation to be accurate. Here are some tips to choose the right worm gearing.
The root diameter of a worm gear is measured from the center of its pitch. Its pitch diameter is a standardized value that is determined from its pressure angle at the point of zero gearing correction. The worm gear pitch diameter is calculated by adding the worm’s dimension to the nominal center distance. When defining the worm gear pitch, you have to keep in mind that the root diameter of the worm shaft must be smaller than the pitch diameter.
Worm gearing requires teeth to evenly distribute the wear. For this, the tooth side of the worm must be convex in the normal and centre-line sections. The shape of the teeth, referred to as the evolvent profile, resembles a helical gear. Usually, the root diameter of a worm gear is more than a quarter inch. However, a half-inch difference is acceptable.
Another way to calculate the gearing efficiency of a worm shaft is by looking at the worm’s sacrificial wheel. A sacrificial wheel is softer than the worm, so most wear and tear will occur on the wheel. Oil analysis reports of worm gearing units almost always show a high copper and iron ratio, suggesting that the worm’s gearing is ineffective.
Dedendum
The dedendum of a worm shaft refers to the radial length of its tooth. The pitch diameter and the minor diameter determine the dedendum. In an imperial system, the pitch diameter is referred to as the diametral pitch. Other parameters include the face width and fillet radius. Face width describes the width of the gear wheel without hub projections. Fillet radius measures the radius on the tip of the cutter and forms a trochoidal curve.
The diameter of a hub is measured at its outer diameter, and its projection is the distance the hub extends beyond the gear face. There are 2 types of addendum teeth, 1 with short-addendum teeth and the other with long-addendum teeth. The gears themselves have a keyway (a groove machined into the shaft and bore). A key is fitted into the keyway, which fits into the shaft.
Worm gears transmit motion from 2 shafts that are not parallel, and have a line-toothed design. The pitch circle has 2 or more arcs, and the worm and sprocket are supported by anti-friction roller bearings. Worm gears have high friction and wear on the tooth teeth and restraining surfaces. If you’d like to know more about worm gears, take a look at the definitions below.
CZPT’s whirling process
Whirling process is a modern manufacturing method that is replacing thread milling and hobbing processes. It has been able to reduce manufacturing costs and lead times while producing precision gear worms. In addition, it has reduced the need for thread grinding and surface roughness. It also reduces thread rolling. Here’s more on how CZPT whirling process works.
The whirling process on the worm shaft can be used for producing a variety of screw types and worms. They can produce screw shafts with outer diameters of up to 2.5 inches. Unlike other whirling processes, the worm shaft is sacrificial, and the process does not require machining. A vortex tube is used to deliver chilled compressed air to the cutting point. If needed, oil is also added to the mix.
Another method for hardening a worm shaft is called induction hardening. The process is a high-frequency electrical process that induces eddy currents in metallic objects. The higher the frequency, the more surface heat it generates. With induction heating, you can program the heating process to harden only specific areas of the worm shaft. The length of the worm shaft is usually shortened.
Worm gears offer numerous advantages over standard gear sets. If used correctly, they are reliable and highly efficient. By following proper setup guidelines and lubrication guidelines, worm gears can deliver the same reliable service as any other type of gear set. The article by Ray Thibault, a mechanical engineer at the University of Virginia, is an excellent guide to lubrication on worm gears.
Wear load capacity
The wear load capacity of a worm shaft is a key parameter when determining the efficiency of a gearbox. Worms can be made with different gear ratios, and the design of the worm shaft should reflect this. To determine the wear load capacity of a worm, you can check its geometry. Worms are usually made with teeth ranging from 1 to 4 and up to twelve. Choosing the right number of teeth depends on several factors, including the optimisation requirements, such as efficiency, weight, and centre-line distance.
Worm gear tooth forces increase with increased power density, causing the worm shaft to deflect more. This reduces its wear load capacity, lowers efficiency, and increases NVH behavior. Advances in lubricants and bronze materials, combined with better manufacturing quality, have enabled the continuous increase in power density. Those 3 factors combined will determine the wear load capacity of your worm gear. It is critical to consider all 3 factors before choosing the right gear tooth profile.
The minimum number of gear teeth in a gear depends on the pressure angle at zero gearing correction. The worm diameter d1 is arbitrary and depends on a known module value, mx or mn. Worms and gears with different ratios can be interchanged. An involute helicoid ensures proper contact and shape, and provides higher accuracy and life. The involute helicoid worm is also a key component of a gear.
Worm gears are a form of ancient gear. A cylindrical worm engages with a toothed wheel to reduce rotational speed. Worm gears are also used as prime movers. If you’re looking for a gearbox, it may be a good option. If you’re considering a worm gear, be sure to check its load capacity and lubrication requirements.
NVH behavior
The NVH behavior of a worm shaft is determined using the finite element method. The simulation parameters are defined using the finite element method and experimental worm shafts are compared to the simulation results. The results show that a large deviation exists between the simulated and experimental values. In addition, the bending stiffness of the worm shaft is highly dependent on the geometry of the worm gear toothings. Hence, an adequate design for a worm gear toothing can help reduce the NVH (noise-vibration) behavior of the worm shaft.
To calculate the worm shaft’s NVH behavior, the main axes of moment of inertia are the diameter of the worm and the number of threads. This will influence the angle between the worm teeth and the effective distance of each tooth. The distance between the main axes of the worm shaft and the worm gear is the analytical equivalent bending diameter. The diameter of the worm gear is referred to as its effective diameter.
The increased power density of a worm gear results in increased forces acting on the corresponding worm gear tooth. This leads to a corresponding increase in deflection of the worm gear, which negatively affects its efficiency and wear load capacity. In addition, the increasing power density requires improved manufacturing quality. The continuous advancement in bronze materials and lubricants has also facilitated the continued increase in power density.
The toothing of the worm gears determines the worm shaft deflection. The bending stiffness of the worm gear toothing is also calculated by using a tooth-dependent bending stiffness. The deflection is then converted into a stiffness value by using the stiffness of the individual sections of the worm shaft. As shown in figure 5, a transverse section of a two-threaded worm is shown in the figure.
