How to Achieve CNC Machining for Electric Mosquito Swatter Prototypes?

Electric mosquito swatters are essential household tools, and their prototype quality directly affects subsequent mass production. Usinage CNC, as a core process in prototype manufacturing, determines the precision, sécurité, and functionality of the product. This article will systematically explain the full process of CNC machining for electric mosquito swatter prototypes, helping engineers and manufacturers solve key problems in the production process.

Table des matières

1. Pré-masseur: Conception & Sélection des matériaux

Avant de commencer l'usinage CNC, a scientific design scheme and appropriate material selection are the foundations of prototype success. The design stage needs to balance ergonomics, fonctionnalité, et faisabilité de l'usinage, while material selection must consider cost, performance, and processing difficulty.

1.1 3D Modélisation & Structural Design Details

Composant	Design Requirements	Considérations clés
Poignée	Ergonomic curved grip, non-slip texture	Easy to hold for long periods; compatible with CNC clamping
Grid Frame	Three-layer structure (outer protective net, middle high-voltage grid, inner support frame); grid spacing ≤ 2mm	Prevent mosquito escape; avoid sharp edges
Circuit Board Compartment	Reserved space for step-up transformers, 18650 lithium battery packs, interrupteurs, and indicators	Convenient for wire connection; ensure insulation
Boutons & Indicators	Waterproof silicone material, integrated at the handle end	Smooth pressing; easy to machine counterbores

1.2 Material Comparison for Core Components

Composant	Optional Materials	Avantages	Désavantage
Poignée	Plastique abs	Faible coût, bonne isolation, Facile à machine	Faible résistance, poor heat resistance
	Alliage en aluminium	Léger, bonne dissipation de chaleur, forte résistance	Coût élevé, requires coolant during machining
Power Grid	Stainless Steel Wire	Good conductivity, résistance à la corrosion	High machining difficulty
	Galvanized Iron Wire	Faible coût, Facile à façonner	Poor corrosion resistance
Circuit Components	PCB Board, High-Temperature Resistant Insulated Wire	Stable performance, safe to use	Need precise positioning during assembly

2. CNC Machining Stage: Équipement, Outils & Paramètres

The CNC machining stage is the core link to realize the prototype structure. The selection of machine tools, outils, and processing parameters directly affects the machining accuracy and efficiency.

2.1 Machine-outil & Préparation des outils

Machine Tool Selection: For small-size precision machining of electric mosquito swatter prototypes, small CNC engraving and milling machines (Par exemple, 3018 Pro) or desktop machining centers are preferred. They are suitable for small workpieces and can ensure high precision.
Tool Library Configuration:
Usinage brutal: Flat bottom knife (Φ6-8mm) – quickly removes residual material, improving machining efficiency.
Finition: Ball head knife (Φ2-4mm) – engraves mesh details and curved surfaces of the handle, ensuring smooth appearance.
Perçage/taraudage: Center drill and tap – used to machine fixing screw holes, ensuring stable assembly of components.

2.2 Key Processing Parameters by Material

Different materials have different physical properties, so corresponding machining parameters must be adjusted to avoid problems such as material melting or tool wear.

Matériel	Rotational Speed (RPM)	Vitesse d'alimentation (mm / min)	Special Requirements
Plastique abs	8,000 – 12,000	400 – 600	Coupure en couches (each layer ≥ 0.5mm) to prevent overheating melting
Alliage en aluminium	12,000 – 20,000	300 – 500	Use coolant to cool down; reduce tool wear
Acier inoxydable	12,000 – 18,000	250 – 450	Slow feed speed; strengthen coolant supply

2.3 Serrage & Component Machining Tips

Méthodes de serrage:
Poignée: Utiliser vacuum suction cups or clamps for fixing to avoid deformation during machining.
Grid Frame: As a thin-walled component, it needs to be clamped lightly to prevent extrusion deformation.
Key Component Machining:
Grid Frame: Adopter linear interpolation processing to ensure uniform grid spacing (≤ 2mm); perform edge chamfering to avoid scratching the skin.
Battery Compartment: Machine card slots on the inner wall to fix the battery position; slot the bottom for wire outlet.
Key Holes: Precisely position the countersinks of the silicone keys to ensure smooth pressing.

3. Post-traitement & Assemblée: Assurer la qualité & Fonctionnalité

Après l'usinage CNC, post-processing improves the appearance and performance of components, and scientific assembly ensures the prototype’s functionality and safety.

3.1 Surface Treatment for Components

Composant	Matériel	Méthode de traitement de surface	But
Poignée	Plastique abs	Sanding burrs + spraying matte paint	Non-slip, improve appearance
	Alliage en aluminium	Anodisation (noir/argent) ou sablage	Résistance à la corrosion, enhance texture
Power Grid	Stainless Steel/Galvanized Iron Wire	Nettoyage + anti-rust treatment (Par exemple, applying insulating paint)	Empêcher la rouille, ensure insulation

3.2 Étapes d'assemblage & Safety Testing

Étapes d'assemblage (Linear Narrative):

Install the grid frame to the handle and test the grid’s elasticity (no deformation under slight stress).
Fix the battery compartment and boost circuit board, then connect the wires (pay attention to insulation to avoid short circuits).
Install the battery, and test the switch, indicator light, and high-voltage output (verify with a test pen).
Adjust the gap between the grid and the handle (recommended ≤ 1mm) to ensure firmness without loosening.

Safety Testing (Key Points):

Use a low-voltage power supply to simulate power-up and check if the grid is short-circuited.
Test the handle’s insulation performance to ensure no leakage.
Continuously trigger the switch 100 times to check the contact status.

3.3 Normes d'inspection de la qualité

Tests fonctionnels: Simulate mosquito contact with the grid to verify the high-voltage effect (conduct a safe voltage test to avoid danger).
Inspection visuelle: Check the uniformity of gaps, surface scratches, and color consistency of components.
Vérification dimensionnelle: Use a caliper to measure grid spacing and handle diameter (tolerance ± 0.1mm).

4. Optimisation & Itération: Améliorer les performances du prototype

To meet market demands, continuous optimization and iteration of the prototype are necessary. This involves structural improvements, material substitutions, and intelligent upgrades.

4.1 Structural Optimization Directions

Reduce handle weight: Adopter un hollow construction to reduce material usage while ensuring strength.
Optimize grid resilience: Add support bars to prevent grid deformation after long-term use.

4.2 Material Substitution & Intelligent Expansion

Material Substitution: Test carbon fiber handles (lighter and stronger than aluminum alloy) or POM gears (for noise reduction if there are moving parts).
Intelligent Expansion: Add USB charging function (convenient for charging) or LED power display (easy to check battery level).

5. Précautions: Ensure Safety & Control Cost

During the entire CNC machining process, safety and cost control are crucial to avoid accidents and reduce production costs.

5.1 Safety Specifications

Porter lunettes de sécurité during machining to prevent chip splashing and injury.
When cutting aluminum alloy, must use coolant to cool down to avoid overheating deformation of the material and tool damage.
During high-voltage testing, operate in accordance with safety regulations to avoid electric shock.

5.2 Coût & Gestion du temps

Cost Control: Prefer standard tools and universal materials (Par exemple, use ABS plastic instead of aluminum alloy for handles if performance requirements are not high) to reduce procurement costs.
Gestion du temps: Adopt phased processing (design → machining → assembly) to avoid long-term occupation of machine tools and improve production efficiency.

Point de vue de la technologie Yigu

For CNC machining of electric mosquito swatter prototypes, precision and safety are the core. Yigu Technology believes that in the design stage, it is necessary to fully consider the compatibility of components with CNC machining to avoid rework caused by unreasonable design. In the machining process, choosing the right tools and parameters can significantly improve efficiency – for example, using a ball head knife for finishing the handle’s curved surface can ensure a smooth touch. En outre, post-processing and safety testing cannot be ignored; good surface treatment enhances the product’s market competitiveness, and strict safety testing ensures user safety. À l'avenir, with the development of intelligent manufacturing, adding IoT functions (such as remote power control) to electric mosquito swatters will be a new trend, and CNC machining technology will need to adapt to more complex structural processing requirements.

FAQ

What is the most suitable CNC machine tool for electric mosquito swatter prototype machining?

Small CNC engraving and milling machines (Par exemple, 3018 Pro) or desktop machining centers are most suitable. They are designed for small-size precision machining, which matches the size of electric mosquito swatter components and can ensure machining accuracy.

Why is the grid spacing of the electric mosquito swatter prototype required to be ≤ 2mm?

The main purpose is to prevent mosquitoes from escaping. If the grid spacing is too large, small mosquitoes may pass through the grid and fail to achieve the mosquito-killing effect. En même temps, a spacing of ≤ 2mm can also ensure the safety of users and avoid accidental contact with the high-voltage grid.

What surface treatment method is recommended for aluminum alloy handles, et pourquoi?

Anodisation (noir/argent) est recommandé. Anodization can form a dense oxide film on the surface of the aluminum alloy handle, which has good corrosion resistance and can prevent the handle from rusting. En outre, anodization can also improve the texture of the handle and make the appearance more beautiful, which is more in line with consumer aesthetic needs.