Patent Publication Number: US-2011071603-A1

Title: Cyclic Heat Therapy Device

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application claims the benefit of U.S. Provisional Patent Application Ser. No. 61/245,651 filed Sept. 24, 2009 and entitled CYCLIC HEAT THERAPY DEVICE, the contents of which are herein incorporated by reference in their entirety. 
    
    
     BACKGROUND OF THE INVENTION 
     Many injuries to the human body such as sprains, damaged ligaments or tendons, torn or bruised muscles, aching joints, and post surgery recoveries are commonly treated with the application of hot and or cold therapy. Such therapy involves the application of heat or removal of heat to the afflicted area of the human body. This temperature treatment helps to reduce swelling, pain, and promote healing. In many instances it is also recommended that cyclic heat treatment, hot-cold-hot-cold, or cold-hot-cold-hot-cold-hot or similar patterns offers superior health benefits over that of constant heat or constant cold treatments. In the past heat treatments have been applied using hot water bottles, ice bags, frozen gels, microwave materials, and disposable chemical bags to produce exothermic or endothermic reactions. Large hot and cold baths have been used to provide contrast therapy for athletes but these systems are large, expensive, and there are patient compliance issues associated with moving persons from hot to cold baths and with non-localized treatment of the affected area of the body. Smaller systems are available that use heated or cooled water and circulate the fluids through tubes around the afflicted areas of the body to provide cyclic relief, but these are bulky, expensive, and have slow cycling times due to large volume fluid changeover. All of these cyclic contrast therapy systems have disadvantages. 
     One common limitation to heat treatment using the present devices is the need for prepared devices. For example, ice bags and frozen gels need to be frozen and stored in a freezer prior to the occurrence of an injury to be useful as a cooling aid. This requires freezer space and precognitive thought that injury may occur. Likewise, a hot water bottle and some heat gels need to be placed in boiling water to reach an effective hot temperature. The use of cold packs and ice bags also results in significant condensation and moisture build up. Since these types of devices cool in all directions moisture from the air can drip on floors or saturate clothing and fabrics. Chemical hot and cold packs solve the issue of preparing the devices in advance but are only one time use. By breaking chemical packets inside a bag a chemical reaction takes place to produce the desired hot or cold effect. However, this chemical solution is designed for either hot or cold and specific bags are needed for each application. The chemical reaction is not reversible and its operating life is limited to the length of the chemical reaction. Once the reaction is completed the bags are useless and must be discarded. There are some heat blankets and wraps available that can provide hot therapy, but there is no portable device available that can produce both hot and cold therapy in cyclic succession. With the above mentioned examples there is no way to cycle between hot and cold quickly without manually alternating between heating and cooling devices. Similarly, there is poor control over the temperatures and durations that the devices operate. A need exists, therefore, for a device that can automatically cycle between hot and cold treatments providing heating, cooling, and contrast therapy relief with accurate temperature and cycling duration controls. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       To further clarify certain aspects of the present invention, a more detailed description of the invention will be rendered by reference to example embodiments thereof which are disclosed in the appended drawings. It is appreciated that these drawings depict only example embodiments of the invention and are therefore not to be considered limiting of its scope. Aspects of the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings in which: 
         FIGS. 1A-1D  disclose various views of an example cyclic heat therapy device shown with an example wrap. More specifically  FIG. 1D  shows an exploded view of an example cyclic heat therapy device; 
         FIGS. 2A-2B  disclose various views of an example cyclic heat therapy device from  FIG. 1  showing the cyclic heat therapy device with the wrap removed. More specifically  FIG. 2B  shows an exploded view of an example cyclic heat therapy device; and 
         FIG. 3A  discloses a view of an example cyclic heat therapy device from  FIGS. 1 and 2  showing the device in application on a human hand. 
     
    
    
     DETAILED DESCRIPTION OF EXAMPLE EMBODIMENTS 
     Example embodiments of the present invention relate to an example cyclic heat therapy device used to heat or cool human, animal, or similar bodies by external application of the device. The example cyclic heat therapy device disclosed herein can aid in the localized temperature control of joints, muscles, tendons, ligaments, or any part of a human or animal body that is contacted by the device. The example cyclic heat therapy device is capable of both cooling and heating in succession on demand and repeating in a cyclic manner with precise temperature and cycle duration control. The device is capable of being used in a heating only mode, a cooling only mode, or a cyclic mode where the output surface temperature of the device cycles between hot and cold phases. The novel stacked configuration of this invention having the control circuits between the heat dissipating and the heat absorbing surfaces allows use without the need for additional cooling fans or fluids. This reduces power consumption and overall package size and allows for internal temperature monitoring of both the heat dissipating and heat absorbing surfaces by the control circuits. 
     Reference will now be made to the drawings to describe various aspects of exemplary embodiments of the invention. It is to be understood that the drawings are diagrammatic and schematic representations of such exemplary embodiments, and are not limiting of the present invention, nor are they necessarily drawn to scale. 
     1. Example Cyclic Heat Therapy Device 
     With reference first to  FIG. 1 , aspects of an example cyclic heat therapy device are disclosed. In particular, an example embodiment of a cyclic heat therapy device is shown.  FIGS. 1A through 1C  shows multiple views of the cyclic heat therapy device  100 . The heating and cooling unit  300  is secured to the human body (not shown) using a flexible wrap  200 . Shown is an example wrap made from neoprene or similar flexible rubber covered with a fabric  210  and secured to the human body (not shown) using hook  220  and loop  230  or other fastener materials which may include snaps, buckles, tied fabric, laces, or other fastener materials. The wrap  200  shown is a generic wrap. In another embodiment of the wrap  200  the wrap is designed to secure the heating and cooling unit  300  to a shoulder, back, or other body part that requires a unique wrap configuration and the wrap  200  would then take on a shape corresponding to that body part. The heating and cooling unit  300  can also be considered to be representative of the present invention without a wrap  200 . In such an embodiment as shown in  FIGS. 2A and 2B , and explained in more detail in the following section, the heating and cooling unit  300  is secured to the body by the human or external interface surface  360  using adhesive pads, gels, pastes, tapes or similar tacky medium which would provide the thermal contact and holding strength for the unit to the body. In such a case no additional wrap would be required.  FIG. 1D  shows an exploded view of the example cyclic heat therapy device  100 . In particular the view shows the various components included in the heating and cooling unit  300  which will be explained in more detail in  FIGS. 2A-2B . The cyclic heat therapy device is not limited to the example configurations disclosed in  FIGS. 1A-1D . In another embodiment the cyclic heat therapy device could consist of one or more heating and cooling units  300  in various wrap  200  configurations or without wraps and adhered to the body using multiple external interface surfaces  360 . 
     2. Example Cyclic Heat Therapy Device 
     With reference to  FIGS. 2A and 2B , aspects of an example cyclic heat therapy device heating and cooling unit  300  are disclosed. In particular, the example cyclic heat therapy device heating and cooling unit  300  consists of a heat sink  310 , a thermoelectric module also known as a thermoelectric cooler (TEC)  350 , a printed circuit board (PCB)  330 , a thermally conductive base  320 , a thermally conductive compliant external interface surface  360 , thermally conductive pads  370 , a switch  340 , and indicator lights  390 .  FIG. 2A  shows an assembled heating and cooling unit  300  without a wrap  200 . From this view the top surface shows the heat sink  310 , the conductive base  320  and the external interface surface  360 . Both the heat sink  310  and the conductive base  320  are made from machined aluminum, but could also be made from copper or any other material with a high thermal conductivity. The heat sink  310  and the conductive base  320  could also be produced using casting, injection molding, stamping or other suitable processes. As shown the human interface material  360  is made from a compliant thermally conductive material such as a thermal gel in a pouch or other flexible thermally conductive material. The external interface surface  360  could also be produced from rigid thermally conductive materials such as aluminum or copper or be integrated as part of the conductive base  320 . In one embodiment the external interface surface  360  has adhesive properties and is used to hold the heating and cooling unit on the body. As stated in section 1 this could include pads, gels, pastes, tapes or other similar tacky medium which would provide the thermal contact and holding strength for the unit to the body. Also shown in  FIG. 2A  is a user switch  340  that allows the user to select the operating mode of the heating and cooling unit  300 . Example heating and cooling modes include: 1) always heat, 2) always cool, 3) cycle between hot and cold or between cold and hot, and 4) off. It can also be envisioned that additional operating modes or functionality could be added to the device such as user controlled options like temperature and cycle time settings. Additional predefined modes could also be included such as certain cycling time and temperature combinations could be encoded into the device and would then be selectable by additional positions on a switch  340  or by actuation of additional switches. In this embodiment only one user input device is shown represented by the user switch  340 . It can be envisioned that one or more switches, dials, buttons, or touch screens could be included within the scope of this device for use as user input or operational displays. Indicator lights  390  are also shown which produce different colors depending on the different operating modes. For example blue light indicates cooling, red light heating, and flashing red or flashing blue for cycling mode heating or cooling. It can be envisioned that visual display screens could be used as replacement for or in addition to the indicator lights  390  to provide similar user feedback about operating conditions, cycle times, temperatures, or modes of operation. These operating modes and lighting configurations given are for example only are not limiting of the scope of the cyclic heat therapy device  100 . 
       FIG. 2B  is an exploded view of the construction of an example heating and cooling unit  300  for an example cyclic heat therapy device. The construction shows a stacked configuration where the TEC  350  is sandwiched using thermal pads  370  between the heat sink  310  and the external interface surface  360 . The conductive base  320  and the heat sink  310  protects and contains the PCB  330  which is used to control the operating mode, mode duration, and temperatures of the cyclic heat therapy device. The PCB  330  includes circuitry and electrical components  331  such as a 555 timer, microprocessor and other timing and switching circuits that enables the TEC  350  to switch automatically between heating and cooling operations when the cyclic heat therapy device is in the cycle operating mode. As part of the circuitry and electrical components  331  the PCB also contains temperature sensing components on the primary and secondary sides which are in direct thermal contact with the heat sink  310  and the conductive base  320 . This enables the circuitry to monitor and reliably control the temperatures of the heat sink  310  and the conductive base  320  at the desired temperatures. As a safety feature the circuitry can then disable the device if the temperatures exceed a programmed high or low value. The timing and temperature sensing circuitry allows the cycle times and temperatures for the device to be set and reliable controlled. Such control allows different contrast therapy programs to be programmed for different treatments or injury types. 
     In the heating mode the portion of the TEC  350  contacting the conductive base  320 , known here as the bottom portion, becomes hot and warms the external interface surface  360 . In the cooling mode the portion of the TEC  350  that is contacting the conductive base  320 , the bottom portion, becomes cold and cools the external interface surface  360 . The heat that is removed from the human body contacting the external interface surface  360  is transferred through the TEC  350  to the portion of the TEC  350  contacting the heat sink  310 , known here as the top portion, and dissipated to the ambient air by the heat sink  310 . The PCB  330  also includes a DC power jack  332  that is used to supply electrical power to the heating and cooling unit  300  from an AC/DC adapter (not shown). 
     The example configuration of a heating and cooling unit  300  for a cyclic heat therapy device is not limiting of the example shown. It is also envisioned that this device can run on a battery supply. In this alternate embodiment of a cyclic heat therapy device the battery could be included within the heating and cooling unit  300 , attached to the wrap  200  or otherwise externally mounted and connected through the DC power jack  332  on the PCB  330 . The use of a battery pack would allow increased portably for the cyclic heat therapy device. 
     3. Example Cyclic Heat Therapy Device 
     With reference now to  FIG. 3A , an example cyclic heat therapy device in application is disclosed. In general, the example cyclic heat therapy device  100  is shown being installed onto a human hand  400 . In this embodiment the wrap  200  will be secured to the hand  400  by putting the two ends of the wrap together and securing the hook  220  and loop  230  fasteners together. The external interface surface  360  makes contact to the back of the hand and the heat sink  310  faces out towards the environment. This enables the user to select a heating, cooling, or cyclic heating and cooling setting for the example cyclic heat therapy device. In an alternate embodiment the adhesion surface of the external interface surface  360  provides the holding strength for the heating and cooling unit  300  to the hand  400  and the wrap is not needed. The external interface surface  360  then transfers heat to, or removes heat from, the affected area of the body depending if the unit is operating in the heating or cooling portion of the contrast therapy cycle. The application shown in  FIG. 3A  is not limiting of the scope of the cyclic heat therapy device. For example, shoulders, back, neck, forehead, ankles knees or other parts of human or animal bodies could all be treated by the device. The device can be used on any part of the body where selective heating, cooling, or cyclic heating and cooling are desired. 
     The example cyclic heat therapy device may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive.