China high quality Crawler-Type Crane Spider Crane with 3 Ton Lifting Capacity

Product Description


KB3.0 micro crawler crane is widely used in the maintenance and installation of electrical equipment in substation, maintenance and installation of mechanical chemical workshop equipment, glass curtain wall, etc.

At present, has been the state grid and southern grid widely use, have been used for the ZheJiang world expo, general motors, HangZhou petrochemical, techsport petrochemical, HangZhou day ling and ZheJiang netcom building construction engineering, etc., products have been exported to USA, Australia, Canada, Britain, Brazil, Vietnam, united Arab emirates and other countries.

In crane rated load has a surplus, but can work for a long time. Crane durable, even in a harsh environment can easily finish the homework. Prevent wrong operation safety design, convenient for the operator easy to complete the lifting operations.


  • Compact, hydraulic walking.
  • Safe design prevents error handling.
  • Adapt to rugged outdoor Spaces.
  • Pentagon telescopic boom.
  • The remote control device is energy-saving and durable.
  • Torque limiter to prevent overload operation.



Model YC3.0 mini crawler crane
specifications 2.95T*1.3M
Maximum radius of homework 8.3M*0.14T
The largest ground lift 9.2M
The largest underground head ~
Winding device Hook up speed: 6.5 m/min (4)
Steel wire rope Diameter of 7.7 mm * 45 m
Telescopic device Crane jib form Five blocks of fully automatic
Crane arm length 2.56m-8.92m
Telescopic crane boom length/time 6.36m / 26sec
Rolling device Boom Angle/time 0°-75°/ 14sec0°-75°/ 14sec
Rotary device Turning Angle/time Continuous / 0 ° ~ 360 ° 40 SEC
Leg Leg action form The first paragraph automatically, high-centralized section of the manual regulation
Maximum out of range 3900mm*3750mm
Walking device Walk way Hydraulic motor drive, two speed
Walking speed 0-2.9Km / h
Climbing ability 20 degree
Crane earthing length * width * 2 1571mm*200mm*2
Ground pressure 51kpa
Diesel engine (optional) Model 2TNV70-PYU
displacement 570ml
The rated power output 77.5Kw
Start the way Electric start
Use fuel/volume 11L
The aerodynamic performance 5°C-40°C
Battery capacity 12V 45Ah
Gasoline engine Model GX390
displacement 389.2ml
The rated power output 6.6Kw
Start the way Manual recoil start/electric start
Use fuel/volume Gasoline / 6 l
The aerodynamic performance -5°C-40°C
Battery capacity 12V 36Ah
The motor Voltage power supply The standard AC380V
power 4KW
The wireless remote control Model BOX1.1 (optional)
The effective distance M100M
Waterproof standard IP67IP67
Safety device Level, alarm device, abrupt stop button, torque limiter (height limiter)
System voltage DC12V
The vehicle size Length * width * height 2900mm*800mm*1450mm
The weight of the The vehicle weight 2050Kg



The biggest location leg hoisting table
2.56/4.18 meters boom 5.8 meters boom 7.34 meters boom 5.5 meters boom
Radius of
Total rated
 lifting weight
Radius of
Total rated
 lifting weight
Radius o
f homework
Total rated
 lifting weight
Radius of 
Total rated
 lifting weight
(m) (t) (m) (t) (m) (t) (m) (t)
< 1.3 3 < 2.90 1.25 < 3.60 0.83 < 4.0 0.55
1.5 2.58 3 1.22 4 0.72 4.5 0.44
2 2.2 3.5 0.97 4.5 0.58 5 0.34
2.5 1.65 4 0.77 5 0.48 5.5 0.3
3 1.23 4.5 0.61 5.5 0.43 6 0.27
3.5 0.97 5 0.53 6 0.37 6.5 0.23
3.64 0.9 5.2 0.5 6.5 0.32 7 0.2
        6.75 0.29 7.5 0.18
            8 0.15
            8.3 0.14

More photos

  /* March 10, 2571 17:59:20 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1

Max. Lifting Height: 9.6 Meter
Rated Loading Capacity: 3.0 Ton
Certification: CE, RoHS
Condition: New
Warranty: 24 Month
Max Working Height: 9600mm


How does the injection molding process contribute to the production of high-precision parts?

The injection molding process is widely recognized for its ability to produce high-precision parts with consistent quality. Several factors contribute to the precision achieved through injection molding:

1. Tooling and Mold Design:

The design and construction of the injection mold play a crucial role in achieving high precision. The mold is typically made with precision machining techniques, ensuring accurate dimensions and tight tolerances. The mold design considers factors such as part shrinkage, cooling channels, gate location, and ejection mechanisms, all of which contribute to dimensional accuracy and part stability during the molding process.

2. Material Control:

Injection molding allows for precise control over the material used in the process. The molten plastic material is carefully measured and controlled, ensuring consistent material properties and reducing variations in the molded parts. This control over material parameters, such as melt temperature, viscosity, and fill rate, contributes to the production of high-precision parts with consistent dimensions and mechanical properties.

3. Injection Process Control:

The injection molding process involves injecting molten plastic into the mold cavity under high pressure. Advanced injection molding machines are equipped with precise control systems that regulate the injection speed, pressure, and time. These control systems ensure accurate and repeatable filling of the mold, minimizing variations in part dimensions and surface finish. The ability to finely tune and control these parameters contributes to the production of high-precision parts.

4. Cooling and Solidification:

Proper cooling and solidification of the injected plastic material are critical for achieving high precision. The cooling process is carefully controlled to ensure uniform cooling throughout the part and to minimize warping or distortion. Efficient cooling systems in the mold, such as cooling channels or conformal cooling, help maintain consistent temperatures and solidification rates, resulting in precise part dimensions and reduced internal stresses.

5. Automation and Robotics:

The use of automation and robotics in injection molding enhances precision and repeatability. Automated systems ensure consistent and precise handling of molds, inserts, and finished parts, reducing human errors and variations. Robots can perform tasks such as part removal, inspection, and assembly with high accuracy, contributing to the overall precision of the production process.

6. Process Monitoring and Quality Control:

Injection molding processes often incorporate advanced monitoring and quality control systems. These systems continuously monitor and analyze key process parameters, such as temperature, pressure, and cycle time, to detect any variations or deviations. Real-time feedback from these systems allows for adjustments and corrective actions, ensuring that the production remains within the desired tolerances and quality standards.

7. Post-Processing and Finishing:

After the injection molding process, post-processing and finishing techniques, such as trimming, deburring, and surface treatments, can further enhance the precision and aesthetics of the parts. These processes help remove any imperfections or excess material, ensuring that the final parts meet the specified dimensional and cosmetic requirements.

Collectively, the combination of precise tooling and mold design, material control, injection process control, cooling and solidification techniques, automation and robotics, process monitoring, and post-processing contribute to the production of high-precision parts through the injection molding process. The ability to consistently achieve tight tolerances, accurate dimensions, and excellent surface finish makes injection molding a preferred choice for applications that demand high precision.

Can you provide guidance on the selection of injection molded materials based on application requirements?

Yes, I can provide guidance on the selection of injection molded materials based on application requirements. The choice of material for injection molding plays a critical role in determining the performance, durability, and functionality of the molded parts. Here’s a detailed explanation of the factors to consider and the guidance for selecting the appropriate material:

1. Mechanical Properties:

Consider the mechanical properties required for the application, such as strength, stiffness, impact resistance, and wear resistance. Different materials have varying mechanical characteristics, and selecting a material with suitable properties is crucial. For example, engineering thermoplastics like ABS, PC, or nylon offer high strength and impact resistance, while materials like PEEK or ULTEM provide exceptional mechanical performance at elevated temperatures.

2. Chemical Resistance:

If the part will be exposed to chemicals, consider the chemical resistance of the material. Some materials, like PVC or PTFE, exhibit excellent resistance to a wide range of chemicals, while others may be susceptible to degradation or swelling. Ensure that the selected material can withstand the specific chemicals it will encounter in the application environment.

3. Thermal Properties:

Evaluate the operating temperature range of the application and choose a material with suitable thermal properties. Materials like PPS, PEEK, or LCP offer excellent heat resistance, while others may have limited temperature capabilities. Consider factors such as the maximum temperature, thermal stability, coefficient of thermal expansion, and heat transfer requirements of the part.

4. Electrical Properties:

For electrical or electronic applications, consider the electrical properties of the material. Materials like PBT or PPS offer good electrical insulation properties, while others may have conductive or dissipative characteristics. Determine the required dielectric strength, electrical conductivity, surface resistivity, and other relevant electrical properties for the application.

5. Environmental Conditions:

Assess the environmental conditions the part will be exposed to, such as humidity, UV exposure, outdoor weathering, or extreme temperatures. Some materials, like ASA or HDPE, have excellent weatherability and UV resistance, while others may degrade or become brittle under harsh conditions. Choose a material that can withstand the specific environmental factors to ensure long-term performance and durability.

6. Regulatory Compliance:

Consider any regulatory requirements or industry standards that the material must meet. Certain applications, such as those in the medical or food industries, may require materials that are FDA-approved or comply with specific certifications. Ensure that the selected material meets the necessary regulatory and safety standards for the intended application.

7. Cost Considerations:

Evaluate the cost implications associated with the material selection. Different materials have varying costs, and the material choice should align with the project budget. Consider not only the material cost per unit but also factors like tooling expenses, production efficiency, and the overall lifecycle cost of the part.

8. Material Availability and Processing:

Check the availability of the material and consider its processability in injection molding. Ensure that the material is readily available from suppliers and suitable for the specific injection molding process parameters, such as melt flow rate, moldability, and compatibility with the chosen molding equipment.

9. Material Testing and Validation:

Perform material testing and validation to ensure that the selected material meets the required specifications and performance criteria. Conduct mechanical, thermal, chemical, and electrical tests to verify the material’s properties and behavior under application-specific conditions.

Consider consulting with material suppliers, engineers, or experts in injection molding to get further guidance and recommendations based on the specific application requirements. They can provide valuable insights into material selection based on their expertise and knowledge of industry standards and best practices.

By carefully considering these factors and guidance, you can select the most appropriate material for injection molding that meets the specific application requirements, ensuring optimal performance, durability, and functionality of the molded parts.

Can you explain the advantages of using injection molding for producing parts?

Injection molding offers several advantages as a manufacturing process for producing parts. It is a widely used technique for creating plastic components with high precision, efficiency, and scalability. Here’s a detailed explanation of the advantages of using injection molding:

1. High Precision and Complexity:

Injection molding allows for the production of parts with high precision and intricate details. The molds used in injection molding are capable of creating complex shapes, fine features, and precise dimensions. This level of precision enables the manufacturing of parts with tight tolerances, ensuring consistent quality and fit.

2. Cost-Effective Mass Production:

Injection molding is a highly efficient process suitable for large-scale production. Once the initial setup, including mold design and fabrication, is completed, the manufacturing process can be automated. Injection molding machines can produce parts rapidly and continuously, resulting in fast and cost-effective production of identical parts. The ability to produce parts in high volumes helps reduce per-unit costs, making injection molding economically advantageous for mass production.

3. Material Versatility:

Injection molding supports a wide range of thermoplastic materials, providing versatility in material selection based on the desired properties of the final part. Various types of plastics can be used in injection molding, including commodity plastics, engineering plastics, and high-performance plastics. Different materials can be chosen to achieve specific characteristics such as strength, flexibility, heat resistance, chemical resistance, or transparency.

4. Strength and Durability:

Injection molded parts can exhibit excellent strength and durability. During the injection molding process, the molten material is uniformly distributed within the mold, resulting in consistent mechanical properties throughout the part. This uniformity enhances the structural integrity of the part, making it suitable for applications that require strength and longevity.

5. Minimal Post-Processing:

Injection molded parts often require minimal post-processing. The high precision and quality achieved during the molding process reduce the need for extensive additional machining or finishing operations. The parts typically come out of the mold with the desired shape, surface finish, and dimensional accuracy, reducing time and costs associated with post-processing activities.

6. Design Flexibility:

Injection molding offers significant design flexibility. The process can accommodate complex geometries, intricate details, undercuts, thin walls, and other design features that may be challenging or costly with other manufacturing methods. Designers have the freedom to create parts with unique shapes and functional requirements. Injection molding also allows for the integration of multiple components or features into a single part, reducing assembly requirements and potential points of failure.

7. Rapid Prototyping:

Injection molding is also used for rapid prototyping. By quickly producing functional prototypes using the same process and materials as the final production parts, designers and engineers can evaluate the part’s form, fit, and function early in the development cycle. Rapid prototyping with injection molding enables faster iterations, reduces development time, and helps identify and address design issues before committing to full-scale production.

8. Environmental Considerations:

Injection molding can have environmental advantages compared to other manufacturing processes. The process generates minimal waste as the excess material can be recycled and reused. Injection molded parts also tend to be lightweight, which can contribute to energy savings during transportation and reduce the overall environmental impact.

In summary, injection molding offers several advantages for producing parts. It provides high precision and complexity, cost-effective mass production, material versatility, strength and durability, minimal post-processing requirements, design flexibility, rapid prototyping capabilities, and environmental considerations. These advantages make injection molding a highly desirable manufacturing process for a wide range of industries, enabling the production of high-quality plastic parts efficiently and economically.

China high quality Crawler-Type Crane Spider Crane with 3 Ton Lifting Capacity  China high quality Crawler-Type Crane Spider Crane with 3 Ton Lifting Capacity
editor by CX 2024-01-19


Recent Posts