Handles

Part Number	Description / PDF	Quantity
7175 Keystone Electronics Corp.	HANDLE INSTR RND .312"DIA ALUM	103172
7147 Keystone Electronics Corp.	HANDLE INSTR RND .312"DIA BRASS	97191
496 Keystone Electronics Corp.	HANDLE BRASS 10/32THR .312"DIA	87141
7173 Keystone Electronics Corp.	HANDLE INSTR RND .250"DIA ALUM	205196
7176 Keystone Electronics Corp.	HANDLE INSTR RND .312"DIA ALUM	0
490 Keystone Electronics Corp.	HANDLE BRASS 10/32THR .312"DIA	62101
525 Keystone Electronics Corp.	HANDLE .312"DIA 10-32THREAD ALUM	58684
7150 Keystone Electronics Corp.	HANDLE INSTR RND .375"DIA BRASS	424
9118 Keystone Electronics Corp.	HANDLE RND .187"DIA 1.00"H ALUM	7111929
495 Keystone Electronics Corp.	HANDLE RND 0.312"DIA 1.75"H BRSS	687
7140 Keystone Electronics Corp.	HANDLE INSTR RND .156"DIA BRASS	450434
548 Keystone Electronics Corp.	HANDLE .625X.281" 10-32THR ALUM	418
7172 Keystone Electronics Corp.	HANDLE INSTR RND .156"DIA ALUM	440
516 Keystone Electronics Corp.	HANDLE .250"DIA 8-32 THREAD ALUM	5855
543 Keystone Electronics Corp.	HANDLE .625X.281" 10-32THR ALUM	234
523 Keystone Electronics Corp.	HANDLE .312"DIA 10-32THREAD ALUM	99193
7170 Keystone Electronics Corp.	HANDLE INSTR RND .156"DIA ALUM	4504
7199 Keystone Electronics Corp.	HANDLE CONTEMPORARY CHROME PLATE	532
7188 Keystone Electronics Corp.	HANDLE INSTR OCAL 6.437"DIA ALUM	0
7187 Keystone Electronics Corp.	HANDLE INSTR OCAL 6"DIA ALUM	0

Handles

1. Overview

Handles for boxes, enclosures, and racks are critical mechanical components designed to facilitate safe and ergonomic handling of technical equipment. These components enable efficient installation, maintenance, and mobility of enclosures housing electrical, electronic, or mechanical systems. In modern industrial, data center, and automation environments, standardized handle solutions ensure operational reliability while meeting safety and durability requirements.

2. Major Types and Functional Classification

Type	Functional Characteristics	Application Examples
Flush Mount Handles	Low-profile design with concealed mounting	Server racks, control cabinets
Foldable Handles	Space-saving retractable mechanism	Portable test equipment, mobile racks
Overcenter Latches with Handles	Integrated locking and lifting functionality	Industrial enclosures, NEMA-rated cabinets
Knob Handles	Ergonomic rotary grip design	Toolboxes, small instrument enclosures

3. Structural and Technical Composition

Typical handle systems consist of: 1) Load-bearing base plates (steel/aluminum alloys), 2) Gripping elements (thermoplastic/nylon coatings), 3) Mechanical fastening systems (stainless steel screws/pins), and 4) Optional sealing interfaces. Advanced designs incorporate vibration dampening materials and corrosion-resistant surface treatments like powder coating or electropolishing.

4. Key Technical Parameters

Parameter	Importance	Typical Values
Load Capacity	Ensures structural integrity under stress	25-200 kg
Material Grade	Determines environmental resistance	Stainless steel, PA66
Installation Dimensions	Guarantees compatibility with enclosures	M4-M8 threaded holes
Operating Temperature	Defines environmental adaptability	-20 C to +80 C

5. Application Fields

Industrial automation (PLC control cabinets)
Data centers (server rack systems)
Telecommunications (outdoor enclosures)
Medical equipment (diagnostic instrument cases)
Military/defense (ruggedized transport cases)

6. Leading Manufacturers and Products

Manufacturer	Representative Product	Key Features
Panduit	Toolless Rack Handle Kit	Quick-release mechanism
Rittal	TS 8 Cabinet Handle	IP54 sealing compatibility
Hammond Manufacturing	1551XX Series	UV-resistant polymer construction

7. Selection Recommendations

Key considerations: 1) Environmental conditions (temperature, corrosive agents), 2) Mechanical load requirements, 3) Compatibility with enclosure standards (IEC 60529), 4) Maintenance accessibility, 5) Cost-efficiency ratio. For high-vibration environments, select handles with anti-loosening features. In cleanrooms, specify non-shedding materials.

8. Industry Trends

Current developments include: 1) Integration with smart monitoring systems (IoT-enabled handles), 2) Adoption of composite materials for weight reduction, 3) Modular quick-swap designs, 4) Enhanced ergonomics through biomechanical research. Sustainability trends drive the use of recyclable thermoplastics and powder coating processes with 95%+ material efficiency.