1 Product applicaiton
Ultrasonic rhytidectomy or medical treatment of cancer. Core components of ultrasonic scalpel and ultrasonic treatment instrument
Product features
The principle of ultrasonic rhytidectomy: through the cluster heat transfer mode of lattice, the skin is circumvent, and under the premise of not cutting the epidermis, the ultrasonic scalpel hairdressing to explore the matrix molecular energy waves that vibrate up to 400-700 million times per second to deep subcutaneous cell damage, and the depth of the hypodermic 1.5-4.5mm left right is directly affected by the deep layer. The fascia, which forms focusing surface in the fascia radio frequency electric field, strongly impacts the dermal tissue and produces the effect of electric field aggregation on the dermal tissue, raising the subcutaneous temperature to 60-75 degrees C, determining the effective heat damage of the heat in the dermal fiber layer, triggering the function of the body to start repairing the regenerated cells and repairing the fascia. The effect of pulling, removing wrinkles and tightening the skin.
The principle of ultrasound focused therapy: the energy of ultrasound in the non treated part of it is not enough to damage the tissue. At the focus of its focus, because of the high sound intensity, the temperature of the tissue rises to 60~100 C by the thermal effect of ultrasound, resulting in protein denaturation and irreversible coagulant necrosis of the tissue cells. Meanwhile, the interstitial fluid, intercellular fluid and the intracellular gas molecules are positive and negative by the cavitation effect of ultrasound. Under the action of phase, bubbles form, and then contract and expand, resulting in the final explosion, resulting in cell damage and necrosis.
High frequency stability
High physical strength
2 Photo show
3 Technical parameter
| Description |
Model |
Frequency |
Power |
Capantiance |
Out Diameter |
Focus distance |
| (Ft) |
W |
(pF) |
mm |
(mm) |
| PZT8 Ceramic |
¢19.5×0.5-SR18 |
800Khz |
30W |
8000±10% |
19 |
18 |
| PZT4 Ceramic |
¢95/¢24×8-SR54 |
250Khz |
600 |
1200±10% |
95 |
54 |
| PZT4 Ceramic |
¢75/¢15×8-SR54 |
250Khz |
350 |
3600±10% |
75 |
54 |
| PZT4 Ceramic |
¢75/¢15×8-SR40 |
250Khz |
350 |
8000±10% |
75 |
40 |
| PZT4 Ceramic |
¢70/¢12×8-SR36 |
250Khz |
250 |
3600±10% |
70 |
36 |
| PZT4 Ceramic |
¢50/¢12×8-SR36 |
250Khz |
250 |
3600±11% |
50 |
36 |
| PZT8 Ceramic |
¢20×2-SR20 |
1MHZ |
20 |
3200±12% |
20 |
20 |
| PZT8 Ceramic |
¢24×2-SR22 |
2MHZ |
15 |
3100±13% |
24 |
22 |
| PZT8 Ceramic |
¢35×1-SR30 |
2MHZ |
15 |
3000±14% |
35 |
30 |
| PZT8 Ceramic |
¢35×1-SR33 |
2MHZ |
15 |
3600±15% |
35 |
33 |
| PZT8 Ceramic |
¢38×1-SR38 |
2MHZ |
50 |
8000±10% |
38 |
38 |
| PZT8 Ceramic |
¢23.2×0.7-SR15 |
3MHZ |
10 |
360±10% |
23 |
15 |
| PZT4 Ceramic |
¢23.2×0.64SR20 |
3MHZ |
10 |
3600±10% |
23 |
20 |
| PZT8 Ceramic |
¢20×0.5-SR20 |
4MHZ |
25 |
6500±10% |
20 |
20 |
| PZT4Ceramic |
¢20×0.5-SR18 |
4MHZ |
10 |
6500±10% |
20 |
18
|
Please contact for more details
