Product Description

Product Description

Products

Gear rack

Precision grade

DIN5, DIN6, DIN7, DIN8, DIN10

Material

C45 steel, 304SS, 316SS, 40CrMo, nylon, POM

Heat treatment

High frequency,Quenching/Carburization, Teeth hardened

Surface treatment

Zinc-plated,Nickle-plated,Chrome-plated,Black oxide or as you need

Application Machine

Precision cutting machines.

Lathes machine 

Milling machines

Grinders machine

Automated mechanical systems

Automated warehousing systems.

Produce Machine

CNC engine lathe

CNC milling machine

CNC drilling machine

CNC grinding machine

CNC cutting machines

Machining center

Workstyle

Execution is more preferred than empty talk.

Stock Gear Rack Type

Specification

Color

Helical gear rack

M1 15*15*1000mm

White

M1.5 19*19*1000mm

White

M2 24*24*1000mm

White

M3 29*29*1000mm

White

M4 39x39x1000mm

White

Spur gear rak

M1 15*15*1000mm

Black

Rack Assembly

To assemble connected racks more smoothly, 2 ends of a standard rack would add half tooth which is convenient for next half tooth of next rack to be connected to a complete tooth. The following drawing shows how 2 racks connect and tooth gauge can control pitch position accurately.

With regards to connection of helical racks, it can be connected accurately by opposite tooth gauge.

1. When connecting racks, we recommend lock bores on the sides of rack first, and lock bores by the sequence of the foundation. With assembling the tooth gauge, pitch position of racks can be assembled accurately and completely.

2. Last, lock the position pins on 2 sides of rack; the assembly is completed.
 

Test

Use Coordinate Measuring Machine to test the precision and hardness of gear rack and pinion

 

Packaging & Shipping

Small quantity: We will use carton box.

Big quantity: We will use wooden cases.

 

Company Profile

ZheJiang Haorongshengye Electrical Equipment Co., Ltd.

1. Was founded in 2008
2. Our Principle:

“Credibility Supremacy, and Customer First”
3. Our Promise:

“High quality products, and Excellent Service”
4. Our Value:

“Being Honesty, Doing the Best, and Long-lasting Development”
5. Our Aim:

“Develop to be a leader in the power transmission parts industry in the world”
 

6.Our services:

1).Competitive price

2).High quality products

3).OEM service or can customized according to your drawings

4).Reply your inquiry in 24 hours

5).Professional technical team 24 hours online service

6).Provide sample service

Main products

Machines

 

Exbihition

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Application: Machinery
Hardness: Hardened Tooth Surface
Gear Position: Internal Gear
Manufacturing Method: Hobbing
Toothed Portion Shape: Spur Gear
Material: Steel, Nylon
Samples:
US$ 50/Piece
1 Piece(Min.Order)

|
Request Sample

Customization:
Available

|

Customized Request

plastic gear rack

How do rack and pinion systems handle different gear ratios?

Rack and pinion systems can accommodate different gear ratios by adjusting the size and number of teeth on the gears. The gear ratio determines the relationship between the rotational motion of the pinion gear and the linear motion of the rack. Here’s a detailed explanation of how rack and pinion systems handle different gear ratios:

In a rack and pinion system, the pinion gear is a small gear with teeth that meshes with the rack, which is a long, straight bar with teeth along its length. As the pinion gear rotates, it translates rotational motion into linear motion along the rack. The gear ratio is defined as the ratio of the number of teeth on the pinion gear to the number of teeth on the rack. It determines how much linear motion the rack will produce for each revolution of the pinion gear.

To handle different gear ratios, the following approaches can be taken:

  • Varying the Number of Teeth: By changing the number of teeth on the pinion gear and the rack, different gear ratios can be achieved. Increasing the number of teeth on the pinion gear relative to the rack will result in a higher gear ratio, providing more linear motion per revolution of the pinion gear. Conversely, reducing the number of teeth on the pinion gear relative to the rack will yield a lower gear ratio, producing less linear motion per revolution of the pinion gear.
  • Modifying the Module and Pitch: The module and pitch of the gear teeth can also be adjusted to accommodate different gear ratios. The module refers to the size of the teeth, while the pitch determines the spacing between the teeth. Changing the module and pitch can alter the gear ratio without significantly affecting the overall dimensions of the rack and pinion system. This approach allows for more flexibility in achieving specific gear ratios while maintaining compatibility with existing system components.
  • Using Gear Reduction or Multi-Stage Systems: In certain applications where a wide range of gear ratios is required, gear reduction or multi-stage systems can be employed. Gear reduction involves incorporating additional gears between the pinion and the rack to achieve the desired gear ratio. Each additional gear stage introduces its own gear ratio, allowing for more precise control over the system’s overall gear ratio. This approach is commonly used in applications that require high precision or a wide range of motion control options.

The selection of a specific gear ratio depends on the application requirements, such as the desired linear speed, torque, or positional accuracy. The gear ratio determines the system’s speed and force transmission characteristics, as well as its ability to handle different loads. It is important to note that changing the gear ratio can affect other system parameters, such as backlash, efficiency, and system dynamics. Therefore, careful consideration and analysis of the application’s needs and trade-offs are necessary when selecting and adjusting the gear ratio in a rack and pinion system.

plastic gear rack

Can rack and pinion systems be applied in both mobile and stationary machinery?

Yes, rack and pinion systems can be applied in both mobile and stationary machinery. The versatility and adaptability of rack and pinion mechanisms make them suitable for a wide range of applications, regardless of whether the machinery is mobile or stationary. Here’s a detailed explanation:

Mobile Machinery: Rack and pinion systems are commonly used in various types of mobile machinery, including vehicles, construction equipment, agricultural machinery, and material handling equipment. Here are some examples of their applications:

  • Steering Systems: Rack and pinion systems are widely employed in the steering mechanisms of automobiles, trucks, and other vehicles. The rotational motion of the steering wheel is converted into linear motion by the rack and pinion system, allowing for precise control over the direction of the vehicle.
  • Lifting and Positioning: Mobile machinery often requires lifting and positioning capabilities. Rack and pinion systems can be utilized in hydraulic lifting systems or linear actuator mechanisms to provide controlled linear motion for raising or lowering loads, adjusting equipment height, or extending and retracting components.
  • Sliding Doors and Gates: Rack and pinion systems can be employed in mobile machinery, such as buses, trains, or elevators, to operate sliding doors or gates. The linear motion of the rack and pinion mechanism facilitates smooth and reliable opening and closing of the doors or gates.

Stationary Machinery: Rack and pinion systems are also extensively used in stationary machinery across various industries. Here are some examples of their applications:

  • Machine Tools: In machine tools like milling machines, lathes, or routers, rack and pinion systems are employed to achieve precise linear motion for tool positioning, workpiece feeding, or spindle movement. The accuracy and repeatability of the rack and pinion mechanism contribute to high-quality machining processes.
  • Industrial Automation: Rack and pinion systems play a crucial role in industrial automation applications, such as robotic arms, pick-and-place systems, or assembly lines. They enable precise and controlled linear motion for manipulating objects, transferring components, or executing complex tasks with high accuracy.
  • Conveyor Systems: Rack and pinion systems can be utilized in stationary conveyor systems to facilitate the movement of materials or products along a linear path. The rack and pinion mechanism provides reliable and precise motion control, ensuring efficient material handling and sorting operations.

The application of rack and pinion systems in both mobile and stationary machinery highlights their versatility and widespread use across different industries. The ability to convert rotational motion into linear motion or vice versa, combined with their precise motion control capabilities, makes rack and pinion mechanisms a popular choice in various machinery and equipment designs.

plastic gear rack

What are the key components of a rack and pinion mechanism?

A rack and pinion mechanism consists of several key components that work together to convert rotational motion into linear motion. Here’s a detailed explanation of the key components of a rack and pinion mechanism:

  • Rack: The rack is a linear gear with teeth along its length. It is a long, straight bar that serves as the linear motion component of the mechanism. The rack is often made of metal or plastic and is designed with precision to ensure smooth engagement with the pinion.
  • Pinion: The pinion is a small gear with teeth that mesh with the teeth on the rack. It is the rotational motion component of the mechanism. The pinion is typically mounted on a shaft and is connected to a rotary motion source, such as an electric motor or a manual crank.
  • Teeth: The teeth on both the rack and the pinion are integral to the mechanism’s operation. The teeth of the pinion mesh with the teeth on the rack, allowing for the transfer of motion. The tooth profile and spacing are crucial for ensuring smooth and efficient engagement between the rack and pinion.
  • Bearing Support: To ensure smooth and reliable operation, a rack and pinion mechanism often incorporates bearing support. Bearings are used to support the pinion shaft, reducing friction and allowing for smooth rotation. Bearings may also be used to support the rack, depending on the specific design and application.
  • Guides: Guides are used to guide and support the linear motion of the rack. They help maintain alignment and prevent lateral movement or misalignment during operation. Guides can be in the form of rails, tracks, or other structures that keep the rack in the desired path of motion.
  • Housing or Mounting Structure: A rack and pinion mechanism may include a housing or mounting structure to provide support, stability, and proper alignment of the components. The housing or structure ensures that the rack and pinion remain securely in place, maintaining the integrity of the mechanism during operation.
  • Additional Components: Depending on the specific application, a rack and pinion mechanism may incorporate additional components. These can include lubrication systems to reduce friction and wear, position sensors for feedback and control, and protective covers or enclosures to shield the mechanism from dust, debris, or environmental elements.

Each of these components plays a vital role in the operation of a rack and pinion mechanism, enabling the conversion of rotational motion to linear motion with precision and efficiency.

China Professional Tianjin Factory CNC Machining M1.5 Helical Rack and Pinion worm gear winchChina Professional Tianjin Factory CNC Machining M1.5 Helical Rack and Pinion worm gear winch
editor by Dream 2024-05-02