This review contains single-test results using the Trash Panda on the Remington 700 rifle, chambered in .308WIN with an 20-inch barrel. Federal Gold Medal Match (GMM) 168gr. ammunition was used in the test.

6.4.1 Trash Panda Sound Signature Test Results

A summary of the principal Silencer Sound Standard performance metrics of the Trash Panda is shown in Table 1. The data acquired 1.0 m (39.4 in) left of the muzzle is available for viewing to all. The data acquired 0.15 m (6 in) right of the shooter’s ear is only available to membership supporters of PEW Science and the Silencer Sound Standard. You can support PEW Science testing, research, and development with a membership, here. State-of-the-art firearm sound signature testing and research conducted by PEW Science is supported by readers like you.

6.4.1.1 SOUND SIGNATURES AT THE MUZZLE

Real sound pressure histories acquired with PEW-SOFT™ are shown below. The waveforms are not averaged, decimated, or filtered. The data acquisition rate used in all PEW Science testing is 1.0 MS/s (1 MHz). The peaks, shape, and time phasing (when the peaks occur in relation to absolute time and to each other) of these raw waveforms are the most accurate of any firearm silencer testing publicly available. PEW-SOFT data is acquired by PEW Science independent testing; the industry leader in silencer sound research. For more information, please consult the Silencer Sound Standard.

The previous Sound Signature Review 6.3 featured a different host weapon and ammunition. However, the sound signatures from the Remington 700 and Savage Model 10 are very similar, even when comparing the different ammunition types used. Figure 1 shows three unsuppressed baseline shots of each ammunition type with the two different host weapons on the day of the VOX S test in the previous review and on the day of the Trash Panda test in this review. The waveforms were measured 1.0 m left of the muzzle. Only the initial shockwave portions of the waveforms are shown, for clarity. Early time pressure comparisons are shown in Figure 1a and early time impulse comparisons are shown in Figure 1b. These waveform comparisons should give you confidence that the host weapon platforms are comparable, and therefore the suppression performance evaluations of the subject silencers are also comparable.

The primary sound signature pressure histories for all 5 shots with the Trash Panda are shown in Figure 2a. A zoomed-in timescale displays the region of peak sound pressure in Figure 2b. The real sound impulse (momentum transfer potential) histories from the same 5-shot test are shown in Figure 3. Again, full and short timescales are shown.

Figure 2 shows a pressure regime first-round-pop (FRP), when comparing Shot 1 to Shot 2. Figure 3 also shows FRP in the impulse regime, albeit with less significant magnitude, when comparing the same shots. Note that the faster rise to peak pressure during Shot 1, coupled with the negative-phase transition during Shot 2, results in different initial impulse waveform slopes. Nonetheless, the overall shape of the impulse waveforms from shot-to-shot are extremely consistent, highlighting the silencer’s sound performance consistency, as well as the consistency of the tested firearm configuration.

The rise to peak pressure measured from the Q Trash Panda is significantly different than seen from the Energetic Armament VOX S in previous Sound Signature Review 6.3. The gas dynamics within the Trash Panda are significantly different due to both baffle geometry and overall internal volume. Although a different host weapon and ammunition was used in Review 6.3, the barrel length and cartridge are extremely similar.

Shot 3, which triggered data acquisition 0.15 ms late, appears to also have an early impulse rise-time in Figure 3a. This is misleading and is an artificial relative time-phase anomaly due to the pre-trigger time being different for that shot (PEW-SOFT triggered later due to the actual pressure threshold from the waveform, thus the captured waveform is shifted in time, artificially). This is only a visual anomaly, and PEW Science has not shifted the shot forward in time in the reported figures due to the nature of this instrumentation-based phenomenon. If the pressure and impulse histories for that shot are shifted forward in time by 0.15 ms, they overlay consistently onto the shots subsequent to Shot 1, confirming the data integrity.

PEW Science note: First-round sound signatures always differ from subsequent shots, as the atmosphere within the silencer changes. The FRP phenomenon cannot always be shown by viewing only the peak sound pressure. This is one of the reasons why The Silencer Sound Standard requires examining multiple sound signature metrics. Ammunition consistency does play a role in the determination of FRP, however, the close examination of measured pressure and impulse waveforms typically excludes ammunition from the possible factors influencing true FRP, due to the consistency of most high quality factory ammunition.

6.4.2 Review Summary: Q Trash Panda on a Remington 700 .308 with 20-in Barrel

When paired with the Remington 700 20” .308 and fired with Federal GMM, the Trash Panda achieved a Suppression Rating™ of 33.1 in PEW Science testing.

PEW Science Subjective Opinion:

The Q Trash Panda is a compact, lightweight, and high performance 30 caliber silencer that takes advantage of its length footprint efficiently with its larger diameter design. The silencer must use the Cherry Bomb muzzle brake to mount to the host weapon. It is important to note that the Cherry Bomb acts as a diffusing element which helps to reduce the impingement of combustion products onto the leading edges of the first baffles in the silencer. As the silencer is fully constructed of titanium, the brake may help to prevent significant baffle erosion and will prolong service life when compared to similar silencers that do not utilize a stainless steel brake mount, on shorter barrels. The durability of titanium silencers used with heat-treated stainless steel blast-shielding muzzle brakes has not been experimentally evaluated by PEW Science and is a subject of continued research interest.

The high gas flow rate through the silencer is evident in the measured data from this test. There is an observed relatively fast rise to maximum peak sound pressure for most shots and the measured peaks are relatively consistent. The combination of high gas flow rate and significant sound suppression is notable. Practically, “blow back,” or increased “back pressure” on a particular host weapon can be reduced when using a silencer that possesses high gas flow rate for a given cartridge, barrel length, and weapon system configuration. Achieving significant sound suppression, and therefore a high(er) PEW Science Suppression Rating while also possessing high gas flow rate, is a combination of silencer traits that indicates high performance. It is postulated that the Trash Panda is able to achieve this combination of favorable traits due to three primary factors; larger internal volume due to its 1.75-inch diameter, over-sized bore aperture, and a baffle geometry that maximizes the efficiency of the two aforementioned factors.

In this review, the Trash Panda performance metrics depend upon suppressing a supersonic centerfire rifle cartridge; no easy task. PEW Science encourages the reader to remain vigilant with regard to all supersonic centerfire rifle suppression claims. The gas volume and combustion products created by the firing of the supersonic .308WIN cartridge are significant; the measured pressure and impulse magnitudes, and their durations, illustrate this fact.

The hearing damage potential of supersonic centerfire rifle use is significant. PEW Science encourages the reader to consider the Suppression Rating when deciding on an appropriate silencer and host weapon combination for their desired use.