The trigger group is the mechanical heart of any firearm, directly dictating accuracy, safety, and control. Understanding its core components—the trigger, hammer, sear, and disconnector—transforms a shooter from a user into a master of their weapon. Mastering this hidden assembly is the single most effective upgrade for precision and reliability.

Anatomy of the Trigger Group: Core Components

The anatomy of a trigger group centers on three core components: the trigger, sear, and hammer. The trigger’s precise geometry and pivot point directly influence pull weight and creep, while the sear’s angle and surface finish determine a clean break versus gritty stacking. The hammer stores and releases kinetic energy, its rotation speed dictating lock time. Together, these elements form a mechanical triad where the sear engagement depth is the critical variable—too shallow risks accidental discharge, too deep cripples accuracy. A polished trigger bow, tuned disconnector, and hardened springs further refine this system, eliminating over-travel and ensuring consistent reset. Mastery of these interdependent parts yields a crisp, predictable trigger break every shooter demands.

The Trigger Shoe: Where Your Finger Connects

The Trigger Group’s anatomy hinges on three core components that dictate its lethal precision: the trigger blade, the sear, and the disconnector. The trigger blade acts as the direct interface, transferring the shooter’s finger pressure into mechanical motion.

This force engages the sear, a critical catch piece that holds the hammer or striker under tension. Its geometry defines the trigger pull weight and break quality. The disconnector then ensures semi-automatic operation, interrupting the sear engagement after each shot to prevent uncontrolled fire.

• Trigger Blade: Transfers input, often adjustable for reach.
• Sear: Dictates break point and safety margin.
• Disconnector: Resets the cycle; its timing is crucial for rapid follow-up shots.

Mastering these elements—particularly the sear’s engagement surface—transforms a system from unreliable to battlefield-proven. Each component’s engineered tolerance directly impacts accuracy, safety, and perceived quality.

The Sear: A Small Part with a Big Job

The Trigger Group isn’t a vague concept—it’s a precision system built from three core components that lock in a user’s decision to act. First, the *Activating Stimulus* lands like a subtle signal, a specific sensation or context cue that primes the brain to shift from idle to alert. Next, the *Conditioned Response* fires, a learned behavior forged from past repetition that bypasses conscious thought, like a drummer tapping a beat without looking. Finally, the *Reinforcement Loop* seals the deal: a small, immediate reward that cements the entire sequence, turning a single action into a repeating habit. Together, these parts form the anatomy of a behavioral trigger—habit formation triggers rely on this exact design to make actions feel automatic. Think of it as a three-pin lock; if one pin is missing, the door stays shut.

• Activating Stimulus: The environmental or sensory cue that initiates the sequence.
• Conditioned Response: The automatic behavior linked to that cue through repetition.
• Reinforcement Loop: The reward that validates and strengthens the pattern.

Q: Can a Trigger Group be broken intentionally?
A: Yes—by interrupting the Reinforcement Loop. Without the reward, the conditioned response gradually fades, and the stimulus loses its power to prompt action.

Hammer and Striker: The Energy Source

The trigger group in a modern firearm is a precision assembly of core components that collectively control the sear-to-hammer interface, dictating shot release. Its fundamental parts include the trigger itself, a sear, a hammer or striker, springs, and often a disconnector. Each component must maintain exacting tolerances to ensure safe, consistent function and a predictable trigger pull weight. Reliable trigger group performance depends on the smooth interaction between the sear’s angled surfaces and the hammer’s notches, which prevents accidental discharge under recoil. Springs must provide sufficient force for reliable primer ignition while returning the trigger forward without drag.

Disconnector: Preventing Slam-Fires

The trigger group’s anatomy is the silent conversation between steel and spring. At its core, the trigger shoe awaits the operator’s touch—a polished lever that transfers intent into action. Beneath it, the sear holds the hammer or striker at bay, a tiny ledge where safety and firepower balance. The disconnector steps in after each shot, resetting the sequence and preventing unintended fire. These components live within the trigger housing, a chasis that aligns them against the frame of a firearm.

• Trigger shoe: Point of contact; shape and texture affect feel.
• Sear: Locking mechanism; its angle dictates trigger pull weight.
• Disconnector: Interrupts the cycle; ensures single-shot operation.
• Trigger bar: Connects shoe to sear; transmits motion.
• Springs: Provide resistance and return force.

Q&A:
What happens if the sear angle is off?
A sear with too steep an angle can slip, causing an unintended discharge—a hammer following the bolt home when the trigger isn’t pulled. Too shallow, and the pull becomes gritty or heavy.

Trigger Springs: Tension and Reset Dynamics

The anatomy of the trigger group is simpler than most beginners think. At its core, you’ll find the trigger itself, which is the only part your finger touches, along with the trigger bar that connects it to the sear. The sear is the crucial component that holds the hammer or striker back until you pull the trigger. These parts work in a precise sequence to release the firing pin. Handgun safety mechanisms are often integrated here, with features like a trigger safety blade or a drop safety preventing accidental discharges. Understanding this layout helps you diagnose common issues like a gritty pull or a dead trigger, saving you a trip to a gunsmith.

How Single-Action Triggers Function

A single-action trigger mechanism is defined by its singular function: performing only the hammer or striker release upon being pulled. Unlike double-action designs, the shooter must manually cock the hammer before the first shot, often via a thumb-operated lever or slide manipulation. This pre-cocking fully tensions the mainspring, resulting in a lighter and crisper trigger pull for enhanced accuracy. The subsequent trigger pulls only release the already-cocked hammer, eliminating the long, heavy stroke required to both cock and release the component. This mechanical simplicity typically yields a shorter reset and more consistent break point. First-shot readiness, however, requires the deliberate action of manual cocking. The design’s reliability and precision make it a staple in many target pistols and classic revolvers where consistent shot placement is prioritized over speed.

One Pull, One Purpose: The Mechanics of SAO

A single-action trigger works exactly the way it sounds: it only does one thing. When you pull frt-15l3 it, the hammer or striker is cocked and released in a single, smooth motion. This design means the trigger has a lighter and shorter pull compared to double-action mechanisms, which manually cock the hammer first. Firearm trigger pull weight is significantly reduced here, making it a favorite for precision shooting. You’ll find this setup in many target pistols and competition rifles because it helps avoid disturbing your aim. Just remember, you need to manually cock the hammer or rack the slide for the first shot—after that, the slide’s recoil does the work for you. It’s simple, consistent, and highly repeatable.

Why Competition Shooters Often Prefer It

A single-action trigger operates through a straightforward mechanical sequence where the hammer or striker must be manually cocked before each shot. This foundational design ensures that the trigger’s sole function is to release the pre-tensioned mechanism, resulting in a consistently light and crisp pull weight. The sear engagement is critical, as it must hold the cocked hammer securely until sufficient pressure is applied. This system eliminates the heavy, stacking pull common to double-action designs, offering unmatched shot-to-shot consistency.

• The shooter manually cycles the slide or uses the hammer spur to cock the mechanism.
• Internal springs compress to hold the striker or hammer under full tension.
• Trigger pull moves the sear directly out of engagement, releasing the stored energy.

This predictable, single-stage release is why precision single-action trigger systems dominate target shooting and long-range applications, where absolute control over the break point is non-negotiable.

Single-Action in Pistols vs. Rifles

A single-action trigger performs only one mechanical function: releasing the hammer or striker. After each shot, the shooter must manually cock the hammer—either by thumb or by cycling the slide—before the trigger can fire again. This design eliminates the double-action’s long, heavy pull, delivering a short, crisp, and lightweight break. Because the trigger’s sole job is to drop the sear, pull weight stays consistently low, often two to four pounds. This predictability allows for exceptional accuracy, as the trigger finger does not fight through excess resistance. Single-action triggers deliver unmatched precision for competitive and hunting handguns. For users who demand a hair-trigger response without staging or stacking, this mechanism remains the gold standard for repeatable, clean shots.

Understanding Double-Action Trigger Systems

A double-action trigger system represents a pinnacle of defensive firearm engineering, performing two critical functions in a single, continuous pull: it both rotates the cylinder or cocks the striker and then releases it to fire. This design eliminates the need for a separate manual safety on many models, as the longer, heavier trigger pull itself acts as a passive safety, making negligent discharges far less likely. The consistent, albeit stiffer, pull weight also simplifies training, preventing the “short reset” confusion common with single-action triggers. For self-defense, this system offers a decisive advantage: you draw, point, and pull, with no external levers to fumble under duress. The result is a brutally reliable, intuitive platform that prioritizes safety without sacrificing combat readiness.

Q&A
Q: Is a double-action trigger suitable for competition shooting?
A: While not ideal for precision target work due to the heavier pull, many shooters successfully use it in defensive-oriented competitions, as it perfectly mimics real-world carry conditions and builds superior trigger discipline.

Longer Pull, Heavier Feel: The Trade-Off

A double-action trigger system does two jobs with one pull: it cocks the hammer and releases it to fire. In double-action mode, the trigger stroke is longer and heavier—typically 10 to 12 pounds—because you’re manually moving internal parts. This design adds a layer of safety since the longer, stiffer pull helps prevent accidental discharges. Many shooters find it ideal for concealed carry or home defense because there’s no manual safety to fumble with. Key benefits include:

• Simplified operation – just point and pull.
• Consistent shot-to-shot pull on revolvers.
• Safer carry without a cocked hammer.

The trade-off is reduced accuracy at long distances due to the heavier trigger weight. Double-action trigger control is crucial for maintaining steady aim during that longer pull. Practice smooth, constant pressure to avoid jerking the muzzle off target.

The Role of the Hammer in DA Revolvers

A double-action trigger system combines two distinct functions into a single pull: cocking the hammer or striker and then releasing it to fire. This means every shot starts with the trigger fully forward, requiring a longer, heavier pull compared to a single-action system. Understanding double-action trigger mechanics improves shooting accuracy because you must learn to manage that consistent, smooth pull through the entire cycle.

Key benefits and challenges include:

• Safety: No manual safety needed, as the long trigger pull acts as a built-in safeguard.
• Consistency: Every trigger press feels the same, simplifying training.
• Drawback: The heavier pull can negatively affect precision at longer ranges.

Double-Action Only (DAO): Simplifying the Cycle

A double-action trigger system performs two mechanical functions in a single pull: it both cocks and releases the hammer or striker. This eliminates the need for a manual safety on many designs, as the longer, heavier pull acts as a primary safeguard against accidental discharge. For expert shooters, understanding this mechanism is critical because it directly affects shot-to-shot consistency. Key distinctions include:

• Double-Action Only (DAO): Each pull is a full, long stroke, common in modern defensive pistols for a uniform trigger feel.
• Traditional Double-Action (TDA): The first pull is heavy and long (double-action), while subsequent shots use a lighter, shorter single-action pull after the slide cycles.

Mastering the double-action trigger pull requires a smooth, steady squeeze without disturbing sight alignment, often practiced through dry-fire drills to build the necessary muscle memory.

Striker-Fired Triggers: Modern and Popular

When the striker-fired system first slipped into holsters, it felt like a revolution. Gone was the heavy hammer of old-school designs; instead, a spring-loaded firing pin sat partially cocked, waiting only for a clean trigger press. For shooters, this meant a reliable trigger pull that felt consistent—no learning two different stages, just a smooth, predictable break. Law enforcement and everyday carriers quickly fell in love with the simplicity: fewer parts meant fewer failures. Glock didn’t just perfect this; they turned it into a modern icon. Today, from the firing range to the dark of a nightstand drawer, the striker-fired trigger dominates. It’s not just popular—it’s become the standard. The old hammers still have fans, but the striker’s crisp, no-fuss action tells a story of progress, one pull at a time.

Pre-Cocked vs. Fully-Cocked: Key Differences

The striker-fired trigger system revolutionized handgun design by eliminating the traditional hammer, creating a sleek, consistent pull that shooters trust. This modern striker-fired trigger mechanism pre-cocks the striker partially as the slide cycles, then completes the tension only when the trigger is pulled, offering a predictable break every time. Glock popularized this in the 1980s, and today it dominates law enforcement and civilian carry due to its reliability and simplicity. Fewer internal parts mean fewer failure points, while each trigger press feels nearly identical—no heavy double-action first shot, no hammer to snag. From duty holsters to concealed waistbands, this design has become the standard for those who demand speed and safety in a chaotic world.

How Trigger Travel Affects Accuracy

Striker-fired triggers have become the go-to choice for modern handguns, especially in the concealed carry and home defense worlds. Unlike traditional hammer-fired designs, these triggers rely on a spring-loaded striker that’s partially cocked when you rack the slide. Pulling the trigger finishes the job, sending the striker forward. This setup gives you a consistent, often lighter pull every single time—no first-shot heavy trigger like you’d get with a double-action revolver. That predictability makes follow-up shots faster and more accurate under stress. It also simplifies the gun’s internals, boosting reliability and reducing the risk of snagging on clothing. Major brands like Glock, Sig Sauer, and Smith & Wesson have all embraced it, which is why you’ll see striker-fired pistols dominating police holsters and range bags alike.

Safety Features Built into the Striker System

Striker-fired triggers are the go-to choice for countless modern handgun owners, thanks to their consistent pull and simplified design. Unlike traditional hammer systems, the internal striker is partially cocked when you rack the slide, then fully released when you pull the trigger, creating a smooth, predictable cycle. This design is a major reason why striker-fired handguns dominate the self-defense market today. They’re popular because they eliminate external hammers and manual safeties on many models, making them snag-free and intuitive to operate. Whether you’re looking at a Glock, a Sig Sauer P320, or a Smith & Wesson M&P, you’re getting a trigger that balances safety and speed for everyday carry.

Two-Stage vs. Single-Stage Triggers

When building a custom rifle, the choice between a two-stage vs single-stage trigger often comes down to feel and intent. A single-stage trigger offers a consistent, crisp break with no take-up—just pull and fire, making it popular for rapid shots. A two-stage trigger, by contrast, has a preliminary slack that stops at a wall, then a distinct second break. This can help you “stage” the shot for precision. For hunting or tactical builds, the single-stage trigger is simpler under stress. For target shooting or precision accuracy, the two-stage is favored. Ultimately, trigger selection for performance influences shot control and accuracy, but personal preference always wins.

The Creep and Wall of a Two-Stage Pull

The first time I tuned an AR-15, my finger met a wall of gritty resistance before the break—a single-stage trigger stacking pressure until it snapped. That’s the hallmark of a single-stage: one consistent pull weight, ideal for rapid fire where predictability matters. In contrast, a two-stage trigger feels like two distinct chapters. You take up slack effortlessly in stage one, then hit a firm wall before the clean, crisp break of stage two—a design prized for precision shooting. Understanding the difference between single-stage and two-stage triggers is essential for optimizing firearm accuracy. Single-stages excel in speed, while two-stages reward deliberate, controlled trigger presses. Mastering this choice transforms your shooting rhythm from a blunt command into a refined conversation between you and the rifle.

Single-Stage: Crisp Break and Fast Follow-Ups

Choosing between a two-stage and single-stage trigger defines your shooting experience. A two-stage trigger offers a distinct take-up wall for precision, ideal for long-range accuracy where a defined “first stage” creep is followed by a crisp, predictable break. In contrast, a single-stage trigger provides a direct, consistent pull weight with no slack, preferred for rapid, instinctive fire. Consider these key differences:

• Two-stage: Better for benchrest shooting and hunting where a heavier initial pull prevents accidental discharge.
• Single-stage: Superior for competition and defensive use, enabling faster follow-up shots.

Q: Which is safer for a home-defense firearm?
A: Two-stage triggers often provide an added safety margin due to their defined first stage, reducing the chance of a surprise discharge under stress.

Choosing Based on Shooting Discipline

Two-stage triggers in firearms require a distinct take-up of slack before reaching the wall and final break, offering a predictable two-step pull that aids precision. Single-stage triggers, by contrast, have no take-up and break at a consistent point of resistance, providing a faster, more direct activation. Choosing between trigger designs balances speed versus accuracy based on application.

FAQs
Q: Which is better for competition shooting?
A: Two-stage triggers are favored in precision rifle events, while single-stage triggers are common in action pistol sports for rapid firing.

Drop Safety and Trigger Group Design

Drop safety is the bedrock of modern firearm reliability, ensuring a loaded weapon cannot discharge if accidentally dropped. This critical protection is engineered through a sophisticated trigger group design, where precision-machined components interact with fail-safes like a firing pin block or a hammer notch. A drop safety mechanism physically obstructs the firing pin or hammer until the trigger is deliberately pulled, neutralizing inertial forces that could cause an accidental discharge. Engaging with this engineering marvel reveals how each spring, sear, and disconnector must work in flawless harmony, balancing a crisp trigger pull with absolute security. The result is a system that feels both responsive and reassuringly robust, proving that trigger group design is where battlefield-tested reliability meets daily carry confidence.

How Inertia Prevents Accidental Discharge

Drop safety in firearms hinges on a mechanically robust trigger group design that prevents unintentional discharge from impact. A critical element is the inertia-activated firing pin block, which disengages only when the trigger is deliberately pulled, physically blocking the striker until a proper cycle occurs. Modern designs integrate multiple redundancies: a hammer catch notches secure the hammer from falling unless the trigger is fully depressed. To visualize this, consider key safety components that work in unison to ensure reliability during a fall:

• Trigger disconnect – interrupts the sear engagement if the slide is out of battery.
• Positive sear engagement – requires a crisp, deliberate trigger pull to release the striker.
• Drop-safe cam – redirects inertia away from the sear during sudden impact.

By engineering these parts with tight tolerances and hardened materials, manufacturers eliminate the risk of a mechanical “slam fire” if the weapon is jarred, making drop safety a non-negotiable benchmark of trustworthy sidearm design.

Transfer Bars and Safety Blocks

Drop safety in firearm design ensures the weapon cannot discharge if accidentally dropped, a critical feature for concealed carry and duty use. Modern trigger group design incorporates a firing pin block or a transfer bar that mechanically interrupts the firing sequence unless the trigger is intentionally pulled. Key design elements include:

• Inertia firing pins: Lightweight pins require a direct strike to ignite the primer, preventing release from impact.
• Trigger disconnect: A drop-safe design disengages the sear if the slide or bolt moves out of battery.
• Spring tension: Heavier springs on safeties resist inertia forces during a fall.

These systems must work with zero user engagement—safety is purely mechanical. For example, in a striker-fired pistol, the striker is partially cocked but held by a sear block, and only full trigger pull clears it. Trigger group design must prioritize these redundancies without adding drag or creep to the pull.

The Debate: Light Triggers vs. Carry Safety

The heart of any reliable firearm lies in its trigger group design, where precision engineering meets the unforgiving physics of drop safety. Imagine a rifle carried through rough terrain, jostled against a rock; a poorly designed sear could slip, releasing the hammer. To prevent this, modern trigger groups use a disconnector and a sear engagement point with a geometric safety margin. This ensures that only a deliberate, horizontal trigger pull—not a vertical shock—can break the sear. *One misplaced tolerance can turn a tool into a tragedy.* The design must balance a crisp pull weight against a block that physically stops the hammer from falling unless the trigger is pressed. This interplay of springs, angles, and steel creates a silent pact between the shooter’s finger and the uncocked hammer.

Adjusting and Upgrading Your Trigger Group

When you’re ready to enhance your firearm’s performance, adjusting and upgrading your trigger group is the single most impactful modification you can make. A gritty, heavy factory pull undermines accuracy, while a crisp, tailored break transforms your shooting experience. Start by polishing engagement surfaces—this reduces creep and friction. For a more dramatic change, swap in an aftermarket drop-in unit. These components offer adjustable pull weight, over-travel, and reset, allowing you to dial in a feel that matches your shooting discipline. Whether for competition or defense, a refined trigger eliminates hesitation and ensures consistent shot placement. Don’t settle for mediocrity; upgrade your trigger group and unlock your firearm’s true potential.

Q&A:
Is a trigger upgrade safe for a carry gun?
Yes, provided you choose a reputable brand and maintain a pull weight above 4–5 pounds. This prevents accidental discharges while still offering a crisp break. Always function-test thoroughly before carrying.

Tuning Pull Weight with Springs and Polishing

Adjusting your trigger group can transform a firearm’s accuracy, centering on trigger pull weight optimization. Begin by testing current pull with a gauge, then adjust the over-travel screw to eliminate excess creep without compromising sear engagement. Upgrading to a high-quality drop-in trigger unit, such as those from Timney or Geissele, often yields a cleaner break and shorter reset. After installation, perform a safety function check: ensure the sear catches with the safety engaged and the trigger resets audibly during cycling. For AR-15 platforms, confirm the hammer pin is fully seated. A lightened trigger—around 3–4 pounds for precision rifles—reduces torque but requires vigilance against slam-fires, especially on military-spec carriers. Always torque adjustment screws to manufacturer specs to prevent movement under recoil.

Drop-In Trigger Kits: Pros and Cons

Upgrading your trigger group is one of the most impactful accuracy modifications you can make to a rifle. A high-quality drop-in trigger, such as a two-stage or single-stage unit from Geissele or Timney, instantly eliminates creep and grit, delivering a crisp, consistent break that shrinks group sizes. Optimizing trigger pull weight for precision shooting typically involves selecting a 2.5–4 lb pull for competition or a heavier 4.5–6 lb weight for duty or hunting use. Adjusting over-travel and pre-travel screws on adjustable triggers further refines shot release, but always use thread locker and verify function with dummy rounds. Avoid common pitfalls: never file sear surfaces, as this voids warranties and creates safety hazards, and always confirm the disconnecter reset after installation. For a list of necessary tools:

• Punch set and small hammer for pin removal.
• Trigger weight gauge for verifying pull.
• Torque wrench for mounting screws (typically 15-25 in-lbs).

Common Mistakes When Modifying the Sear

Upgrading your trigger group is a fundamental step in refining rifle accuracy, as it directly controls the sear engagement and break consistency. Trigger group upgrades often involve replacing factory components with aftermarket units that offer reduced creep and a lighter, crisp pull weight. Adjusting a drop-in trigger module typically requires minimal tools; you can dial in pull weight via a small set screw, and adjust overtravel to prevent the trigger from moving excessively after the break. For two-stage triggers, careful tuning of the pre-travel screw ensures a distinct first stage before the wall. Always verify safe sear engagement with a live-fire safety check: load a round, apply slight forward pressure, then release the bolt; if the hammer follows, your adjustment is unsafe. Common upgrade paths include single-stage units for precision gas guns or two-stage triggers for long-range precision bolt actions. A quality trigger group transforms platform performance.

Troubleshooting Common Trigger Group Issues

When tackling troubleshooting common trigger group issues, the first step is always verifying battery contact and sear engagement. A gritty trigger pull often points to burrs on the hammer or disconnector, which you can polish with fine stones but never remove material aggressively. Creep after a trigger job usually signals an improperly adjusted over-travel screw or a worn sear face. For reset failures, check that the trigger return spring is not binding or collapsed. Always function-test with snap caps before live fire, and remember that even premium upgrades require breaking in. If you get a dead trigger, inspect for a disconnector that hasn’t re-engaged the sear—often due to binder pins or poor geometry. Master these checks to maintain reliable, crisp performance from your firearm trigger system.

Failure to Reset: Causes and Fixes

When troubleshooting common trigger group issues in firearms, start by verifying that all spring components are correctly seated and not fatigued. Diagnose inconsistent trigger pull weight by inspecting the sear engagement surfaces for burrs or excessive wear. If the trigger fails to reset, check for binding in the trigger bar channel or a compromised disconnector spring. For binary or aftermarket triggers, ensure the hammer disconnect has proper shelf clearance to prevent unintended full-auto fire. Always use a function-check gauge to confirm sear engagement depth—too shallow risks accidental discharge, too deep creates a gritty, heavy pull. Lubricate pivot points sparingly with a light grease to avoid debris attraction, and torque all retaining pins to manufacturer specifications to eliminate creep.

Trigger Sticking or Gritty Feel

When troubleshooting common trigger group issues, start by verifying that components are free from debris and properly lubricated. A gritty trigger pull often results from carbon buildup or insufficient oil on contact surfaces. Check that the disconnector and sear engagement angles are correct, as worn or incorrectly adjusted surfaces cause creep or failure to reset. For light primer strikes, inspect trigger spring tension and hammer spring weight to ensure they meet the factory specification. Common fixes include cleaning the trigger mechanism with a solvent, replacing damaged springs, and polishing engagement points with fine grit. If the trigger fails to reset, confirm the trigger bar is not bent and the trigger return spring is intact. Always test function with dummy rounds after adjustments.

Light Strikes: When the Hammer Doesn’t Hit Hard

When your trigger group malfunction causes missed shots or inconsistent fire, start by checking the hammer springs and sear engagement surfaces. Common glitches often stem from worn components or improper reassembly.

Follow these steps for a quick fix:

• Disassemble and inspect the trigger assembly for burrs or carbon buildup.
• Lightly polish the sear and hammer contact points with a fine stone.
• Verify the disconnector moves freely and resets correctly.
• Test function with snap caps before live ammunition.

Q: Why does my trigger feel gritty after cleaning?
A: Likely excess lubricant attracting debris—wipedown all surfaces and apply only a tiny drop to pivot points.