FI12103U1 - Heating pad - Google Patents

Abstract

A modular heat support comprising a substantially flat support structure (2) comprising a bottom layer (21) of a resilient material which impedes heat flow and attached to the bottom layer an aluminum foil (22) reflecting heat radiation; characterized in that the heating pad further comprises a removable protective bag (30) which is placed around the support structure, and the protective bag has substantially the same shape as the support structure spread out in a plane and is intended for use when the heating pad is used; and a flat heating element (10) comprising at least one resistance element, and the heating element is arranged to be placed between the aluminum foil of the support structure and the protective bag according to the plane defined by the support structure, and the heating element is arranged to be coupled to a connection to an energy source. which independently produces direct current. In addition, the protection requirements 2-10.

Description

Field of the Invention

The present invention relates to a modular heating medium according to the preamble of claim 1.

Background of the Invention

In cold conditions, it is sometimes necessary to stay longer. Hikers and hikers also move in cold conditions, and rest and even sleep in very cold conditions. Not only humans, but animals also suffer from the cold. For example, service and exercise dogs may have to stay for long periods of time waiting for their active duties even in cold weather.

Various camping platforms have been developed for hiking and biking, which are quite effective in isolating from cold ground. For example, if you are staying in a car or other vehicle, it is possible to use the car's heating systems for heating, which, however, consume the car's battery and / or use fuel. However, it is very unecological to generate fuel with fuel by keeping the car idle for long periods. The car battery can also be drained easily due to heating.

Therefore, there is a need for an improved solution for heating a substantially stationary object, such as a human or animal, which is capable of using its own independent energy source for sufficiently long periods while being environmentally friendly and safe. The solution also has to take into account the many different places and conditions in which heating can be used.

Brief Description of the Invention

It is an object of the invention to provide a heating pad which solves the drawbacks of the prior art. The objects of the present invention are achieved by a modular heating medium according to the characterizing part of the protective claim 1.

According to the first embodiment, the modular thermal substrate comprises a substantially planar support structure including a heat-resisting base layer of flexible material and an aluminum foil reflecting heat radiation attached to the base layer. In addition, the modular heat carrier includes a detachable separate pouch placed around the support structure, which is substantially planar in shape and intended for use with the heat carrier, and a substantially planar heating element comprising at least one resistor element and which heating element is arranged to be connected to an independently operating direct current power source by a connector.

According to another embodiment, the heat-conductive backing layer of the support structure consists of a foam or numerical sheet of 3-10 mm thickness.

According to a third embodiment, the support structure and the heating element mounted thereon can be enclosed within the pouch using a closure device mounted in the opening of the pouch.

According to a fourth embodiment, the heating element is arranged to be connected to an energy source by a conductor arranged to extend from the inside of the protective bag to the outside and which conductor can be connected to the energy source through at least one connector.

According to a fifth embodiment, a switch for switching the heating element on and off is further provided in the conductor between the heating element and the energy source.

According to a sixth embodiment, the switch further includes means for selecting the power to be supplied to the heating medium.

According to a seventh embodiment, the heating element has a heating power of about 5-50 W, and wherein the direct voltage from the energy source is about 3-24 V.

According to an eighth embodiment, the heating element resistor element consists of at least one thermal resistor fixed to the flexible material.

According to a ninth embodiment, the heating element applied to the aluminum foil of the support structure is detached from the support structure, removably attached to the support structure, or fixedly attached to the support structure.

According to a tenth embodiment, the surface area of the substantially planar heating element is smaller than the area defined by the upper surface of the substantially planar support structure.

Preferred embodiments of the present invention are the subject of dependent claims.

The present invention is based on the idea of combining an active electric heating element with a passive heating medium.

It is an advantage of the present invention that the heat produced by the heating element is efficiently utilized, on the one hand, by reflecting the heat produced by the heating element towards the object to be heated and, on the other hand, preventing the heat from being heated away. Thus, a heating element which is smaller in size than the support substrate is also capable of providing sufficient heat to the object on the substrate. The protective bag protects the heating element from touching the heated object without hindering the heating, while at the same time protecting the heating element itself. The removable protective bag is easy to wash. The heating element is dimensioned so that it delivers comfortable heat with a safe DC voltage and current so that in the event of equipment failure, the heated object is not exposed to danger.

Brief Description of the Drawings

The present invention will now be explained in more detail by means of preferred embodiments with reference to the accompanying drawings, in which:

Figure 1 shows a heating element.

Figure 2 shows a cross-section of the support structure material.

Figure 3 shows a heating element mounted on a support structure. Figure 4 shows a modular heating medium.

Figure 5 shows a modular heating medium with a heating element connected to an energy source.

Figure 6 shows a modular heating medium connected to an energy source via a regulator or a switch.

DETAILED DESCRIPTION OF THE INVENTION

Figure 1 shows the heating element 10. The heating element acting as the active heater of the heating medium is a plate-shaped and preferably flexible electric heater. The heating element has one or more resistance elements 11 in which the electrical energy is converted into thermal energy. Typically, the resistor elements are made of metal wire, but other known electrical resistor elements can also be used in the invention. According to one embodiment, the heating element consists of a metal wire or wires bonded between two layers of fabric material which act as heat resistors. According to another embodiment, the thermal resistor (s) is embedded in a thin, flexible silicone mat. According to a third embodiment, the heating elements' heating resistors are embedded in a thin and flexible polyimide (Kapton) or polyester layer. According to some embodiments, the resistance element consists of a woven textile material acting as a thermal resistance or other electrically heated fabric material. The thermal resistors are preferably connected via a conductor 13 to a connector 12 through which the required electrical energy can be supplied to the heating resistors. The conductor 13 has at least two conductor wires that allow energy to be supplied through the connector 12 to the resistive heating element. In Figure 1, the conductor wires of the conductor 13 are shown separately, but typically the conductor wires are insulated from one another within the common sheath. The heating element 10 is arranged to apply a DC voltage. For example, the energy source may be a battery or accumulator that is coupled to the heating element 10. In one exemplary embodiment, the energy source of the heating element is currently a commonly available backup power source that is powered by a USB connector. For example, a typical commercially available USB backup power supply will provide up to 1.5, 2, 3, or 5A current at 5V, depending on the selected USB standard. For example, a 12,000mAh backup power supply is enough to supply a 10W heating element with 2A current for about 6 hours. 10W power is sufficient to heat the heating element. The temperature to be achieved will depend on the ambient temperature and other environmental factors, but for example, said 10W heating power is well enough to ensure the comfort of a pet resting on a heating pad heated by the heating element 10, but under no circumstance poses a risk of overheating. USB backup power is lightweight and easy to move. When used in a car, a car or other vehicle battery can be used as an alternative source of power, typically providing a voltage of about 12V or about 24V, which can be easily converted to a 5V suitable for heating element 10, for example using a commercially available USB adapter. Alternatively, the heating element may be dimensioned for direct use of a 12V or 24V battery supplied directly from the battery of a car or truck, boat or similar vehicle. In one embodiment, the energy source may be a lithium battery or accumulators with a nominal voltage of 3.7 V. For example, a 3 A current may be used with a 24 V battery to provide a maximum heating element power of about 48 W.

The above examples are not to be construed as limiting in any way, but the heating element may utilize an operating voltage of between 3 and 24 V and the power of the heating element may be rated between 5 and 50 W.

However, for safety reasons, the heating element 10 should not be clearly connected to a power source producing more than 24 V, or to an energy source providing more than 50 W.

The low operating voltage of said range of 3 to 24 V, for example, and in combination with it, the relatively low electric current of 1.5 to 5 A makes the heating element 10 safe for the user even in the event of an electrical failure such as a short circuit. Short circuits can result, for example, from damping the terminals or damaging the conductors. For example, if the heating pad is used as a pet pad, the pet could bite the wire so that it is damaged. However, low operating voltage and current do not pose a significant hazard, even in the event of damage. Many commercially available backup power supplies also have a built-in protection mechanism that would trip in the event of a short-circuit at the output of the backup power supply, which will automatically cut off power in the event of a fault. Thus, the only active part of the heat sink, i.e. the heating element and associated electrical components, is safe even in the event of a failure. In addition, the low heating power of 5-50W eliminates the need for a separate overheat protection.

Figure 2 shows a cross-section of the support structure material. The support structure 20 consists of a resilient base layer 21 and a thin aluminum layer 22 attached thereto, the support structure forming a substantially planar structure which is flexible and resilient. Preferably, the base layer 21 is a material which effectively functions as a heat insulator to prevent heat conduction. For example, the base layer 21 may consist of a foam or foam rubber sheet having a thickness of 3 to 10 mm. The material of the base layer and the thickness of the material may be selected to best suit the application of the substrate, taking into account the thermal insulating capacity, flexibility, stability, weight and wear resistance of the base layer 21. In particular, due to the required stability and abrasion resistance of the substrate support substrate used as an animal substrate, an air pocketed base layer 21 such as an air mattress is not recommended. The support structure 20 further comprises a thin aluminum foil 22 attached to the base layer 21, which is arranged to efficiently reflect thermal radiation. The aluminum foil 22 is preferably so thin that it is also flexible. The thickness of the aluminum foil is 0.006 mm - 0.2 mm.

Fig. 3 shows a heating element 10 mounted on a support structure 20. The heating element 10 is preferably placed parallel to the plane defined by the support structure 20 on the same side of the support structure 20 as the aluminum foil 22. Thus, the aluminum foil effectively reflects the thermal energy generated by the heating element 10 while preventing the heat conduction layer 21 from conducing heat to the environment. In this way, the heating power of the heating element 10 is best utilized. As can be clearly seen in the example shown in Fig. 4, the substantially planar heating element 10 may have a clearly smaller surface area than the support structure 20 located beneath it. Thus, the limited heating power of the heating element is preferably directed to a smaller surface area. for comfortable heating of the object. The aluminum foil 22 reflecting the heat radiation of the support base 20 and the heat resisting base layer 21 contribute to the utilization of the heating power obtained from the heating element 10. If the area of the low-power heating element 10 is wide, the heating power obtained from it may not be sufficient to achieve a sufficient temperature. It has been found that a heating element having a smaller surface area than the supporting structure 20 gives a feeling of sufficient warmth, which makes staying on the heating medium comfortable even in cold conditions. The surface area of the heating element 10 may be designed to cover, for example, up to 50% of the area of the upper surface of the support structure 20 beneath it or of the plane defined by the aluminum foil 22. Advantageously, the surface area of the heating element may also be only up to 30% or even only up to 20% or up to 10% of the surface area defined by the upper surface of the support structure 20 or the aluminum foil 22. If the support structure 20 is small, the surface area of the heating element 20 may also be substantially the same as, but not preferably greater than, the surface area of the support structure 20 or aluminum foil 22, since the support structure 20 also protects the thermal element 10 from mechanical stress. Preferably, the heating element 10 is separate and removable from the support structure 20. The modularity makes the heat sink easy to maintain and long lasting. Should any of the parts be damaged, each part can be easily and cheaply replaced. According to one embodiment, the heating element 10 may be removably attached to the support structure to ensure that the heating element 10 remains in the desired position. The attachment of the heating element 10 to the support structure 20 may be effected, for example, by means of a velcro or snaps (not shown). Alternatively, the heating element may be attached to the support structure, for example by gluing so that the heating element is not detachable from the support structure.

Preferably, the flexible conductor 13 is arranged to extend beyond the area defined by the support structure 20. The conductor 13 has a connector 12 for supplying electrical energy to the heating element 10. In an alternative embodiment, the heating element includes a connector that can be connected to a separate conductor by means of a connector counterpart. In this case, the heating element 10 itself does not include a conductor. A separate, detachable conductor further improves the modularity of the heat sink, as the conductor is easily replaceable.

Figure 4 shows a modular heating medium. The support structure 20 and the heating element 10 superimposed thereon are preferably placed inside the protective bag 30. The shielding bag is shaped such that the flat support structure 20 and the heating element 10 superimposed thereon fit completely inside the sheathing bag so that the conductor 13 and the connector 12 connected thereto can be brought outside the shielding bag. The shield bag 30 is preferably substantially shaped in the form of a support structure, whereby the support structure 20 stays well in place within the protective bag. For the smooth insertion of the support structure into the protective bag 30, the inner dimensions of the protective bag preferably are slightly larger than the outer dimensions of the supporting structure, but not too large for the protective bag to sit snugly around the supporting structure. For example, the shape and size of the protective bag can be compared to a closable mattress cover, whereby the support structure 20 represents a "mattress" which is completely enclosed within the protective bag 30. The protective bag has an opening 33 through which the support structure 20 and the heating element 10 can be located inside the protective bag 30. Aperture 33 can be closed using a closing means. The closure means may be, for example, a velcro, a zipper (not shown) or the like. Conductor 13 may be arranged to pass through aperture 33 outside of shield bag 30 so that power source 50 can be easily connected via connector 12 to heat element 10. Alternatively, shield bag 30 may have a separate opening for conductor 13 or connector 12 (not shown).

The pouch is preferably made of a wear-resistant and wash-resistant textile material, and the pouch may be made of one or more materials. The material of the protective bag may be water permeable or impermeable, and the material of the protective bag may be selected according to the purpose of the heating pad. For example, a protective pouch for a substrate for use in humid or wet conditions may be made of a water impermeable material that protects the thermal element 10 from wetting and, thus, any electrical problems caused by moisture. The pouch may be made of natural fibers or man-made fibers, or a mixture thereof, and may also contain film-like materials, for example to achieve waterproofing. A separate protective bag is an essential part of the modularity of the heat sink. This way the protective bag can be easily washed if necessary and can also be replaced if damaged.

The pouch also protects the heating element 10 from mechanical stress and damage. If the heating medium is used, for example, with a pet, the protective bag 30 prevents the pet from coming into direct contact with the heating element 10.

Fig. 5 illustrates a modular heat sink having a heating element coupled to power source 50 using at least one connector 12. Connector 12 may be designed to be coupled to connector connector and conductor to power source 50. Alternatively, connector 12 may be designed to connect directly to power source 50 with built-in connector connector. In this case, if the power source 50 is a USB backup power supply, at least one connector 12 is preferably a connector according to a known USB standard compatible with the backup power supply. There may be a plurality of connectors 12 between the heating element 10 and the energy source 50. At least one connector 12 further improves the modularity of the heating medium. If the conductor 13 is subjected to mechanical pull, it is more likely that the connector 12 will become detached from its counterpart than that the conductor 13 itself or the connection between the conductor and connector 12 will be damaged. In this way, the durability and service life of the thermal medium assembly is increased when it is easy and inexpensive to replace a potentially damaged part, such as a heating element 10 or a conductor portion with connectors.

The placement of the coupled power source 50 of the connector 12 outside the shielding bag 30 provides an easy way to activate and shut off the power source 50 as needed, or, for example, to easily change the power source 50 even when the heating medium is in use. If the power source 50 has a visual indicator to show the amount of energy available, the state of the power source outside the heat sink is easily monitored.

In one embodiment, the entire conductor 13, as well as the energy source 50, may be housed within a shielding bag 30. Thus, for example, in humid conditions, the pouch can also be used to protect the energy source from moisture. However, in this case, activating, shutting down, monitoring or changing the power source may require opening the protective bag.

Fig. 6 shows a modular heating medium coupled to an energy source 50. In this embodiment, a regulator 55 is connected between the energy source 50 and the heating element 10 to control the power supplied to the heating medium from the energy source 50. The regulator 55 can be connected to both the heating element 12 and the power source 50 using terminals 12, whereby the regulator 55 may be an optional accessory. The controller may be a simple switch for switching the circuit of the power source 50 and the heating element 10 open or closed. Alternatively, the regulator 55 may include means for selecting the power to be supplied to the heating element so as to adjust the power to a value that is not more than the maximum power available from the energy source 50. At lower power, the temperature achieved by the heating element 10 is reduced, but on the other hand, the energy source 50 provides longer energy.

It will be obvious to a person skilled in the art that as technology advances, the basic idea of the present invention can be implemented in a number of ways. The present invention and its embodiments are thus not limited to the preceding examples, but may vary within the scope of the claims.

Claims (10)

protection Requirements A modular sizing device (2), a flexible seating device (21), an elastic material socket and an aluminum foil (22); (30) som placeras runt stödstrukturen, och skyddspåsen har väsentligen samma form som stödstrukturen utspridd i et plan och hån för att använd dåändåd och - ett plant color element (10) som innefattar åtminstone ett motståndselement, och color element för att placeras mellan stödstructurens aluminum foil och paneldspåsen enligt planet som stödstrukturen definierar, och color element för dnat. with energy som självständigt producerar likström. A modular heat carrier comprising: - a substantially planar support structure (20) including a heat-resisting base layer (21) of flexible material and an aluminum foil (22) reflecting a heat radiation attached to the base layer; characterized in that the heating medium further comprises: - a removable separate protective bag (30) which is arranged around the support structure, which is substantially shaped in the form of a support structure for use in use with the heating platform; and - a substantially planar heating element (10) comprising at least one resistor element, the heating element being arranged to be inserted between the aluminum foil of the support structure and the protective bag according to a level defined by the support structure; 2. The modular tumbler enigt krav 1, the stem bottenlager (21) som hindrar tromlöde från stödstrukturen består av 3-10 mm tjocka cellplast-eller cellum rubber. A modular heat carrier according to claim 1, wherein the heat-impervious base layer (21) of the support structure consists of a foam or foam rubber sheet having a thickness of 3-10 mm. 3. The modular color scheme (1-2), and the color scheme (20) and the color scheme in the panel (30) are shown in the table (33). Modular heating medium according to protection claims 1-2, wherein the support structure (20) and the heating element (10) placed thereon can be closed inside the protective bag (30) by means of a closing means mounted in the opening (33) of the protective bag. 4. The modular color scheme is limited to 1-3, and the color elements are selected for use in the energy field (50) med en ledning (13), och ledningen för att stråckas från skyddspåsens insida till dess utsida, andochningning kan kopplas till energälällan med åtminstone ett kopplingsstycke (12). Modular heating medium according to protection claims 1-3, wherein the heating element is arranged to be connected to an energy source (50) by a conductor (13) arranged to extend from the inside of the protective bag and which can be connected to the energy source through at least one connector (12). 5. The modular color scheme enligt krav 4, wherein the color element is energized and the energy element dessutom innefattar et kopplingsstycke (55) för att koppla color element på och av. The modular heating medium of claim 4, wherein the conductor between the heating element and the energy source is further provided with a switch (55) for turning the heating element on and off. 6. The modular color system is ligated to the bottom 5, and the duplex insert (55) is applied to the effect. The modular heating medium of claim 5, wherein the switch (55) further comprises means for selecting the power to be supplied to the heating medium. 7. Provide a moderately low-light output 1-6, dye-element-effect 5-50 W, and a power supply 3-24 V. 7. Modular heating medium according to protection requirements 1-6, wherein the heating element has a heating power of about 5 to 50 W and a direct voltage from the energy source is about 3 to 24 V. 8. Provide a moderately low-melting layer 1-7, and the color-element motståndselement består av åtminstone et tonm-element som fästs i det elastic material. A modular heating medium according to the protection claims 1-7, wherein the heating element resistor element comprises at least one heating element fixed to the flexible material. 9. The modular dye base is selected from the group of 1-8, the dye element being placed on an aluminum foil; - Löstagbart fäst i stödstrukturen; eller - fast fäst i stödstrukturen. A modular heat carrier according to the protection claims 1-8, wherein the heating element applied to the aluminum foil of the support structure is: - detached from the support structure; - removably attached to the support structure; or - fixed to the support structure. A modular heat carrier according to the protection claims 1-9, wherein the surface area of the substantially planar heating element is smaller than the area defined by the upper surface of the substantially planar support structure. SKYDDSKRAV 10. The modular color scheme shall be carried out from 1 to 9, in which case the color scheme of the Plana shall be defined and the definition of the Plana stödstrukturen.