Thermal Agents PHYSICAL PRINCIPLES_SRS.ppt
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This document discusses physical thermal agents and the principles of heat transfer. It covers the following key points in 3 sentences: Matter can exist in solid, liquid, or gas states depending on the balance between cohesive and kinetic forces. Heat is transferred between materials via conduction, convection, conversion, radiation, or evaporation. The rate of heat transfer and temperature change depends on factors like an object's specific heat, thermal conductivity, circulation of transferring medium, radiation intensity, and distance from the heat source.
![Sreeraj S R
References
1. Cameron MH. Physical Agents in Rehabilitation: An Evidence-Based Approach to Practice. In:
5th ed. St. Louis, Missouri: Elsevier, Inc; 2018. p. 398–411.
2. Bellew JW, Michlovitz SL, Nolan T. Modalities for therapeutic intervention. In: 6th ed.
Philadelphia, Pa: F.A. Davis Company; 2016. p. 21–6.
3. Admin. Latent Heat - Definition, Types, Formula, Fusion and Vaporization [Internet]. BYJUS.
BYJU’S; 2019 [cited 2021 Mar 14]. Available from: https://tinyurl.com/xukpjmsc
4. Heat Transfer [Internet]. Mesonet.org. 2021 [cited 2021 Mar 14]. Available from:
https://tinyurl.com/efy5y62z
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Thermal Agents PHYSICAL PRINCIPLES_SRS.ppt
- 1. Sreeraj S R Dr Sreeraj S R, Ph.D. THERMAL AGENTS: PHYSICAL PRINCIPLES
- 2. Sreeraj S R States of Matter o Matter can be solid, liquid or gaseous. E.g., water may exist as ice water or steam. o The molecules of a substance are influenced by two forces: 1. Cohesive force, which attracts the molecules of the substance to one another and a 2. Kinetic force of movement of the molecules o Kinetic force depends on the thermal energy contained by the mass of molecules. 2
- 3. Sreeraj S R Specific Heat o It is the amount of energy required to raise the temperature of a given weight of a material by a given number of degrees. o Materials with high SH require more energy to achieve the same temperature increase than materials with low SH. o They hold more energy at a given temperature than materials with low specific heat. o SH of Water 4.19 J/g/°C o SH of Air 1.01J/g/°C o 3 Specific Heat of Various Tissues Body Tissue Specific Heat in J/g/°C Skin 3.77 Muscle 3.75 Fat 2.30 Bone 1.59 Water has the second highest SH capacity of any known chemical compound. Source: https://www.physicsforums.com/threads/properties of-air-vs water.293733/
- 4. Sreeraj S R Mode of Heat Transfer o Heat can be transferred by; 1. Conduction 2. Convection 3. Conversion 4. Radiation 5. Evaporation 4
- 5. Sreeraj S R Conduction o Heat loss or gain through direct contact between materials with different temperatures. o The thermal conductivity of a material is a measure of its ability to conduct heat. o Hot Packs and Cryotherapy transfer heat by conduction. 5
- 6. Sreeraj S R Conduction o The rate at which heat transfers by conduction between two materials depends on 1. The temperature difference between the materials, 2. Their thermal conductivity, and 3. Their area of contact. o Water’s thermal conductivity is higher than air's (0.6 vs 0.025 W/(m.K)Source: https://www.physicsforums.com/threads/properties-of-air-vs- water.293733/ 6
- 7. Sreeraj S R Conduction o Thermal Conductivity of Various Tissues 7 Body Tissue Thermal Conductivity (W/m-K) Bone 2.28 Muscle 0.42 Fat 0.16 Skin 0.21 Blood 0.52 Rugh JP, Bharathan D. Predicting Human Thermal Comfort in Automobiles. SAE Technical Papers. 2005;2508–16. DOI: 10.2172/15016823
- 8. Sreeraj S R Conduction o Heat may also transfer to or from a patient by conduction. o If the physical agent used has a higher temperature than the patient's skin, heat will transfer from the agent to the patient, and the temperature of superficial tissues in contact with the heating agent will rise. o If the physical agent used is colder than the patient’s skin, the opposite will happen. o Rate of temperature rise decreases in proportion to tissue thickness. 8
- 9. Sreeraj S R Convection o Heat transfer by convection occurs as the result of direct contact between a circulating medium and another material of a different temperature. o Since the thermal agent is in motion, a constant temperature is maintained with the patient's body part. o Example: Whirlpools and fluidotherapy transfer heat by convection. 9
- 10. Sreeraj S R Convection Heat transfer by blood circulation; o Vasodilation increases the rate of circulation, increasing the rate at which the tissue temperature returns to normal. o The circulation constantly moves the heated blood out of the area and moves cooler blood into the area to return the local tissue temperature to a normal level. o This local cooling by convection reduces the impact of superficial heating agents on the local tissue temperature. o To protects the tissues by reducing the risk of burning. 10
- 11. Sreeraj S R Conduction vs Convection o Heat transfer by stationary medium o Transfers less heat o Heat transfer by circulating medium o Transfers more heat Conduction Convection 11
- 12. Sreeraj S R Conversion o Heat transfer by conversion involves the conversion of a nonthermal form of energy, such as mechanical, electrical, or chemical energy, into heat. o Example: Diathermy and ultrasound heat patients by conversion. 12
- 13. Sreeraj S R Conversion o When heat is transferred by conversion, the rate of heat transfer depends on the power of the energy source. o Heat transfer by conversion does not require direct contact between the thermal agent and the body; o But the intervening material should be a good transmitter of that type of energy. o For example, transmission gel, lotion, or water must be used between an ultrasound transducer and the patient. o Air transmits ultrasound poorly. 13
- 14. Sreeraj S R Radiation o This involves the transfer of energy from a material with a higher temperature to one with a lower temperature without an intervening medium or contact. o This is conversion of non thermal form of energy into Heat o Example: Infrared lamps transfer heat by radiation. 14
- 15. Sreeraj S R Radiation o The rate of temperature rise caused by radiation depends on 1. The intensity of the radiation, 2. The distance of the source from the treatment area, and 3. The angle between the radiation and the tissue. 4. The relative sizes of the radiation source, 5. The area being treated, 15
- 16. Sreeraj S R Evaporation o A material must absorb energy to evaporate or change from a liquid to a gas (or vapor). o This energy is absorbed as heat derived from the material itself decreasing its temperature. o So, evaporation is a cooling process. o Example: A vapocoolant spray evaporates at an even lower temperature than water. 16
- 17. Sreeraj S R Latent Heat o Latent heat is defined as the heat or energy that is absorbed or released during a phase change of a substance. o Energy is required to change from 1. solid to liquid , 2. liquid to gas (evaporation), or 3. solid to gas (sublimation). o Energy will be released to change from 1. liquid to solid (solidification), 2. gas to liquid (condensation), or 3. gas to solid. 17 • Latent Heat of Fusion • Latent Heat of Vaporization
- 18. Sreeraj S R Temperature influences: o Viscosity o Nerve conduction—heat increases nerve conduction velocity; cold decreases it o Blood flow—heat increases arterial and capillary blood flow; cold decreases blood flow o Collagen extensibility—heat increases tendon extensibility; collagenase activity is increased; cold decreases enzyme activity o Temperatures > 45–50°C or < 0°C can injure tissue 18
- 19. Sreeraj S R Physical Principles of Heat o The greatest temperature elevation with heating modalities occurs in the skin and the subcutaneous tissues within 0.5 to 2 cm of the skin surface. o In areas of adequate blood supply, temperature will increase to a maximum within 6 to 8 minutes of exposure. o Muscle temperature will require a longer duration of exposure of 15 to 30 minutes to reach peak values. o At a depth of 3 cm, using clinically tolerable intensities, muscle temperature elevation can be expected to be about 1°C or less. 19
- 20. Sreeraj S R Physiological Effects of Heat o Therapeutic levels of heating are categorized as 1. Mild, less than 40°C and 2. Vigorous 40°C to 45°C o At vigorous temperatures, hyperemia or erythema or redness of the skin is noted, caused by an increase in the blood flow in the capillaries (hyperemia) in the lower layers of the skin. o Temperature greater than 45° results in thermal pain and irreversible tissue damage. 20
- 21. Sreeraj S R References 1. Cameron MH. Physical Agents in Rehabilitation: An Evidence-Based Approach to Practice. In: 5th ed. St. Louis, Missouri: Elsevier, Inc; 2018. p. 398–411. 2. Bellew JW, Michlovitz SL, Nolan T. Modalities for therapeutic intervention. In: 6th ed. Philadelphia, Pa: F.A. Davis Company; 2016. p. 21–6. 3. Admin. Latent Heat - Definition, Types, Formula, Fusion and Vaporization [Internet]. BYJUS. BYJU’S; 2019 [cited 2021 Mar 14]. Available from: https://tinyurl.com/xukpjmsc 4. Heat Transfer [Internet]. Mesonet.org. 2021 [cited 2021 Mar 14]. Available from: https://tinyurl.com/efy5y62z 21
Editor's Notes
- #6: watts per meter-kelvin [W/(m⋅K)]