NL1008624C2 - Electrically powered heat reservoir for bed-warming - Google Patents

Abstract

The cylindrical reservoir is placed on the base station (10) which supplies electric current to the heating element (7). The heat is transferred to glass particles (6) and to a small quantity of water (2). As the water boils, resultant bubbles of steam rise through the coagulated paraffin (3), transferring heat. After heating, the reservoir is used to heat beds. Paraffin has a greater heat carrying capacity than water. The reservoir therefore stays hot longer than a traditional hot water bottle.

Description

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Title: Heating reservoir such as a jug or the like in particular for bed heating.

The present invention relates to a heating reservoir such as a jug and the like for use in household use, in the healthcare and in the care sector, in particular suitable for bed heating and the like, comprising a shape-resistant enclosure containing a heat storage medium.

Heat reservoirs of the kind to which the present invention pertains have long been used in the form of hot water bottles for bed heating of particularly tired needy or sick people and small children. These jars are made of metal and usually have an elongated cylindrical shape with a filling opening which can be closed with a screw cap. In these known jars, water is usually used as the heat storage medium, which is first brought in a kettle over open fire or electrically at a high temperature and then poured into the jug via the filling opening. To store as much heat as possible in the jar, the water is heated as high as possible, i.e. to 100 degrees Celsius. A drawback of these known jars is that the water has to be heated externally, which is accompanied by a certain heat loss. Furthermore, the heated water must be poured into the jug through the rather narrow filling opening, which can easily lead to spillage. The filling opening is then closed with a screw cap, which again and again gives a chance of leakage, with all the ensuing consequences. Because of all these actions to be performed, the known jars are not really user-friendly.

In order to at least partially overcome the aforementioned problems, reservoirs of the present type are also known which are closed and wherein the heat storage medium contained therein is heated by placing the reservoir in a specially equipped oven which is then brought to a high temperature . A drawback of these reservoirs is that a special oven must always be available for their application. Because of the cost of the furnace this makes such reservoirs in practice only suitable for use in larger institutions and care homes where large numbers of reservoirs are used.

A further disadvantage of the known jars lies in the fact that in order to store a sufficient amount of heat in the jug, the water has to be heated to about 100 degrees C, so that a high temperature occurs on the outside of the metal casing. contact gives this chance of burning. To overcome this, the jar is usually covered with a wool or molton cloth. The disadvantage of such a coating is that these substances attract dirt and collect bacteria and other germs in it. This makes regular changing and cleaning desirable. Furthermore, DE 297 13 963 U discloses a flexible reservoir which is closed on all sides and filled with a heat storage medium undergoing a phase transition. In the reservoir a heating element is arranged which can be connected to an external voltage source. Corresponding reservoirs are shown in GB 2 160 965; GB 2 135 860; GB 2 192 118 and GB 2 291 321. Although such flexible reservoirs in situations wherein a large contact surface with a body to be wound is desired to be used; there are also circumstances in which such a large contact surface is not desirable and even impermissible. In those circumstances, recourse should be had to the aforementioned conventional metal jug. A further disadvantage of the aforementioned flexible reservoirs is that the wall can easily come into direct contact with the heating element, with the risk of damage thereof. the heating element itself must also be constructed such that it does not suffer any damage as a result.

The object of the present invention is to provide a heating reservoir of the above-described type which primarily overcomes the drawbacks mentioned of the already known reservoirs.

A further object of the present invention is to provide a heating reservoir with a large heat storage capacity at moderate temperature which can be manufactured at an acceptable cost.

In order to achieve the intended purpose, the heating reservoir according to the invention has the feature that the enclosure is closed on all sides and the heat storage medium is a medium with a phase transition from solid to liquid at a temperature corresponding to a main operating temperature of the reservoir, with or without the casing comprises one or more electric heating elements which are connectable via 100862 4 3 a electric conductors to an external voltage source and wherein the reservoir is further provided with means for accommodating expansion differences at the phase transition of the medium. In this way, a reservoir is obtained which can be heated very simply and efficiently to the desired operating temperature and which, due to its shape-resistant enclosure, has a limited contact surface with a body to be heated and which hardly, if at all, damages the heating element% is present..

A further embodiment of the reservoir is characterized in that the heat storage medium consists at least partly of one or more phase transition substances or mixtures thereof with a phase transition from solid to liquid and vice versa at a temperature corresponding to a main use temperature of the reservoir.

According to a further favorable embodiment, the heat storage medium is formed by a combination of one or more phase transition substances and at least one substance which is liquid in the operating temperature range of the reservoir.

15 The combination of characteristics outlined above provides a heating tank that is particularly safe and very easy to charge with heat, simply by connecting the tank to an external voltage source, usually the public electricity grid. By using a storage medium that at least partly consists of a substance with a phase transition from solid to liquid in the cooling range of the reservoir, relatively much heat can be stored in the medium, which is released during said phase transition at constant temperature, which, when suitable selection of the phase transition substance, corresponds to a main use temperature of the reservoir. In general, the fabric will be chosen so that the phase transition takes place at a temperature of about 60 degrees C. Such a temperature is such that the reservoir can be put into bed without protective casing without there is a risk of burns

Although the heat storage medium can consist entirely of one or more phase transition materials, it has been found to be advantageous, in connection with the heat transport in the medium and also the heat transfer from the medium to the wall of the reservoir, to use a combination of one or more more phase transition substances and a substance that remains liquid in the temperature range in which the reservoir is used.

1 008624 3b

Since the heat storage medium can undergo thermal volume changes during cooling and heating, which can lead to large stresses and even breakage in the enclosure, in a further embodiment of the reservoir according to the invention, measures have been taken to compensate for the effects of said thermal volume changes .One of those measures is to form an oval cross-section for a casing of a substantially cylindrical shape.In another embodiment, a hollow flexible element is arranged within the casing, which connects to the inner wall and there through a small opening in the wall is connected to the environment.

According to a further embodiment of the invention, the storage medium consists essentially of a wax, fat, stearin, salt or mixtures thereof with a high phase transition heat and a phase transition temperature from solid to liquid and vice versa corresponding to the said main operating temperature of the reservoir, optionally in combination with a liquid which remains liquid. Waxes, fats and stearins are substances with long chains of carbon atoms, whereby the phase transition temperature can be chosen by choosing the length of these chains. Furthermore, these substances have a number of properties, which makes them exceptionally suitable for use as heat storage medium in a closed reservoir. Some of these properties are; a high phase transition heat; not aggressive; low vapor pressure; not dangerous or toxic ; chemically stable; high crystal dexterity so that hypothermia is low; little volume change at phase transition; good heat conductivity; and further cheap and common.

According to a further favorable embodiment of the invention, the heat storage medium is a substance such as, for instance, paraffin of the type which forms a porous mass upon solidification, wherein the casing also contains an amount of water which collects on a bottom of the reservoir which in contact with an electric heating element and a pressure prevailing in the reservoir such that the boiling point of the water almost corresponds to the melting temperature of the paraffin. Paraffins of the type which form a porous mass upon solidification are known per se and are described in the International patent application. WO 94 / 12588. Application of this kind of paraffin in a reservoir of the present form has the result that the water collects at the bottom of the reservoir with a solidified porous mass of paraffin above it. By setting a certain pressure in the reservoir the boiling temperature of the water can be set to correspond to the melting temperature of the paraffin. Usually this will be a negative pressure in order to reduce the boiling temperature of the water to a temperature desired for the reservoir. When the water is brought to boiling and evaporation with the aid of the heating elements, the vapor will penetrate into the porous paraffin mass and condense on the surface of the pores. During condensation, the vapor gives off its heat to the paraffin which thus it is heated and the condensate sinks back through the pores back to the bottom to be reheated and evaporated. In this way a very fast and efficient way of heating and melting the paraffin is obtained.

According to a further embodiment of the reservoir according to the invention, a number of granules of a temperature and chemical resistant substance such as glass are arranged on the bottom of the reservoir in order to counteract an excessive boiling of the water during heating.

It should be noted that the said patent application shows a reservoir with an all-round closed casing, which reservoir, however, is not provided with means for supplying heat to the paraffin. This makes this reservoir less suitable for domestic and applications in the healthcare and the care sector because of the drawbacks mentioned above in connection with the pitcher. Also, this known reservoir does not show any measures to compensate for the volume changes of the storage medium that occur during heating and cooling.

5 It has been found that the said salts and / or salt mixtures can also well meet the requirements in this regard as already mentioned above in connection with wax and stearin; the difference here is that these salts generally have a somewhat lower chemical stability. An example of a salt that lends itself well to use as a heat storage medium in this type of reservoir is sodium acetate.

It has been found that a reservoir filled with the aforementioned substances remains warm for much longer than a pitcher of the same volume, the heat being released most of the time at an almost constant temperature.

A further embodiment of the reservoir according to the invention has the feature that the electrical conductors for the power supply to the heating elements 15 connect to an adapter with plug pins mounted on the outer wall of the enclosure, which adapter can cooperate with an external base station provided with a or more connectors in which said plug pins can be received, the base station being provided with means for coupling to a voltage source. In this way, the reservoir can very easily be placed in the base station in order to be charged with heat. All work related to heating a kettle of water, filling the jar and screwing on the cap with subsequent wrapping of the jar with a protective cover has now been replaced by simply placing the reservoir in the base station.

Optionally, according to a further embodiment, an electric switch can be incorporated in the electrical conductors at the location of the adapter or in the base station for switching on the energy supply to the heating elements, which automatically switches off again after a certain, possibly adjustable, time. the reservoir will be placed in the base station without charging being started immediately and charging will only start shortly before the reservoir is to be used. Furthermore, the electrical conductors may also include a thermostat switch, possibly in combination with the aforementioned on / off switch, which interrupts the charging process when a certain temperature, which may be adjustable, has been reached. This last temperature will practically be correspond to or exceed the phase transition temperature of the medium used.

The heat reservoir according to the invention as described above can be further implemented in many ways. Special features thereof are further described in the appended claims and will be further mentioned and explained in the description of the figures below, in which, by way of example, some embodiments of heat reservoirs are according to the invention.

Show in the figures below; FIG. 1 schematically and not to scale in cross-section, an embodiment of a heating reservoir according to the invention, which contains a heat storage medium consisting essentially of a porous solidifying wax.

Figures 2,3 and 4 show diagrammatically and not to scale different embodiments of a heating reservoir according to the invention.

Fig. 5 shows the cooling progress of a jar with water storage medium and a jar with sodium acetate as storage medium, respectively.

In FIG. 1 shows a heating reservoir provided with a metal inner casing 1 containing a small amount of water 2, a relatively large amount 20 of a porous solidifying paraffin 3 and a small amount of air 4. The pressure in the inner casing is chosen in this way that the boiling point of the water substantially corresponds or is preferably slightly higher than the melting point of the paraffin 3. On the bottom 5 of the inner envelope, a number of glass granules 6 are arranged, while one or more heating elements 7 are mounted against the outside of bottom 5 .

The inner casing 1 is surrounded by an outer casing 8 of, for example, plastic, which extends beyond the bottom 5 and there has a shape 9 which fits on a base station 10.1η the shape 9, an adapter 11 is provided, which is provided with plug pins that can cooperate with sockets of a connector 12 that forms part of the base station 10.

30 The base station is provided with electrical cables not shown in the drawing, with which the bass station can be connected to an external voltage source 100 8 6 24 7, for example the electricity network. The adapter 11 is in turn connected to the heating elements 7. The base station is provided of a pressure switch 13 that switches on the power supply to the connector, adapter and heating elements at the moment when this is desired. The switch is preferably of the type that switches itself off again after a certain period of time. This switch is also included in part 9 of the outer casing. Thermostats, etc. may also be included in the power supply lines to the heating elements.

The heating of the reservoir is carried out as follows: Due to the difference in density, the water 2 will collect on the bottom 5 with the mass of porous solidified paraffin 3 above it. After switch 13 is switched on, power is supplied to the heating element. 7 that the bottom heats up 5 This will heat up the water to its boiling point and then the water will evaporate. The vapor will rise in the pores of the paraffin and will condense there giving off its condensation heat. to the bottom 5 where it is evaporated again. This continues until the paraffin has melted completely. In this way, efficient and rapid heating of the paraffin is achieved.

Although in the drawing the heating element 7 is arranged against the outer wall of the bottom 5, it should be clear that the heating elements can also be arranged within the casing. The glass granules 6 ensure that the water is boiled excessively and bubbled is prevented.

Although a porous solidifying paraffin is present as the heat storage medium discussed above, other storage media such as fats, waxes and salts can also be used, on condition that they form a porous structure in which the water vapor formed can penetrate.

In Fig. 2 a heating reservoir in the form of a jug is schematically shown, which comprises a plastic envelope formed by a cylindrical part 21 and an upper and lower head surface 22 and 23, respectively. The cylindrical part 21 can be perpendicular to its axis have a circular or oval shape. In the casing, two heating elements 25 and 26 are arranged, on which aluminum plates 27 are mounted at mutual distances for the purpose of a good distribution of the heat, also 10 0 8 624 δ in the transverse direction. By convection heating of the storage medium in one direction The heating elements are passed through the bottom 23 of the reservoir and are connected to an adapter 28 mounted in the bottom. At the top, the heating element described above can be coupled to the top end surface 22 via a positioning part 29.

The adapter 28 is housed in a housing part 30 which is an extension of the cylindrical housing 21. The end face of this housing part 30 is provided with a passage 31 through which the plug pins 32 of adapter 28 can be reached. which plate when the jug is disconnected from the base station closes the passage 31 against resilience. Housing part 30 furthermore contains a thermostat switch and a fuse in an unspecified manner.

Included in the cylindrical shell of the jar is a heat storage medium 40 which has a phase transition from solid to liquid and vice versa at a temperature in the cooling range of the jar. The storage medium chosen is the salt sodium acetate (CH3C00Na.3H20), but other salts and salt mixtures or fat, wax and stearin may optionally also be used.

An option is also to combine these phase transition storage media with a liquid permanent medium such as water or even to use only a liquid permanent medium. This is shown schematically in the embodiment of a reservoir according to Fig. 3, the reservoir 21 being filled with a mixture of water 50 and spheres or chunks 51 of a waxy substance exhibiting a phase transition. The spheres or chunks 51 may herein be provided with a thin envelope of a plastic material. Above the mixture there is again an air cushion 4 as in the embodiment according to FIG. . 1. The heating element 52 can herein have a simple shape or, if desired, be arranged on the outside of the casing as shown in FIG. 1.

The choice of phase transition storage medium is mainly determined by the following considerations; -high phase transition heat, -a melting / pouring point lying in the operating cooling range of the reservoir, 30 -a low vapor pressure at the working temperature, -chemically stable 10 0 8 6 24 9 -not corrosive, -not dangerous or poisonous, -fast crystal speed, so little hypothermia in the case of salts, - little volume change during phase transition, - good heat conduction, - inexpensive and common.

-degradable and recyclable;

The chosen salt sodium acetate with a melting point of 58 degrees C satisfies the above criteria well, but also other salts, waxes, fats and stearin as mentioned above very well meet the requirements set.

Fig. 5 graphically shows a comparison between the cooling range of a conventional jug filled with water and a jug according to the invention filled with sodium acetate. The graph shows the temperature on the vertical axis and the time on the horizontal axis. line A is the cooling range of water and line B indicates the cooling range of sodium acetate. It clearly shows that the pitcher has cooled to 40 degrees C within 3 hours while the sodium acetate jar takes 7 hours to cool to 40 degrees C. It is striking that the jar filled with a storage medium with phase transition gives off most of its heat at the phase transition. The temperature at which this occurs can be achieved by suitable selection of the storage medium to be used, optionally by a mixture of several of the aforementioned. fabrics are chosen at will.

The underside of part 30 of the jug is configured to cooperate with a base station 42 which is provided with one or more connectors 43 with receptacles into which the plug pins of the adapter 28 fit. In this way it is possible for the user simply place the jug in the base station and activate the power supply to the heating elements via switch 37. The previously necessary cumbersome operations of heating water in a boiler and filling the jug have now become superfluous. Now it is sufficient to place the jug in the base station, after which! the jug is charged and ready for use within a very short time. With a thermostat or otherwise, a maximum temperature can be set which is equal or even higher than the phase transition temperature. At such a temperature, the jug can be placed in bed without further protection without the danger of burning. 10 0 8 6 24 10. Such a jug without covering with a cloth can attract little dirt or germs, which is good for hygiene In this way, a jug is obtained with a number of very user-friendly aspects such as easy to use, safe because fire risk and leakage are excluded, environmentally friendly 5 because of a higher heating efficiency.

In order to properly absorb volume changes of the storage medium, the cylindrical part 21 of the jar is oval in cross-section. Such a shape has the advantage that upon expansion of the medium, a distortion occurs in the direction of the circular shape, creating space and the expansion is compensated-10. Volume changes of the medium can also be compensated, if necessary, by means of a hollow flexible element disposed within the envelope, which extends centrally in the longitudinal direction of the jug and is attached to the inner wall of a front face. schematically shown in Fig. 4 This Figure 4 shows another embodiment of the heat reservoir according to the invention 15 which, as in the embodiment according to Fig 2, is constructed as a jug and differs from the embodiment according to Fig. 2 in that the top head surface 22 is provided with a handle 24. A hollow deformable element 40 is connected to the inner wall of the end face 22. The interior of element 40 is in communication with the atmosphere via a small opening 41 in the end face 22. Apart from a somewhat different embodiment of the heating element 43, the construction is the same as that of the reservoir according to FIG. 2.

The outer casing 21 is preferably made of plastic, under certain circumstances it consists wholly or partly of a plastic which undergoes discoloration when the temperature changes. This makes it possible to immediately see whether the reservoir is charged with heat or not.

From the foregoing it will be clear that the invention provides a heat reservoir which has many advantages over conventional heat reservoirs and which lends itself very well to be designed and used as a pitcher for, for example, bed heating. However, the reservoir can also very well be designed as more or less flat box and then be used, for example, as an incubator for foot warming, in particular wheelchair users.

1008624 '

Claims (7)

11a 1. Heating reservoir such as a jug and the like for use in household use, in the health care and in the care sector; particularly suitable for bed heating, comprising a shape-resistant envelope containing a heat storage medium, characterized in that the envelope is closed on all sides and the heat storage medium is a medium with a phase transition from solid to liquid at a temperature corresponding to a head -use temperature of the reservoir, wherein one or more electric heating elements are arranged inside or against the enclosure, which connections can be connected via electric conductors to an external voltage source and wherein the reservoir is further provided with means for accommodating expansion differences at the phase transition of the medium 2. Heating reservoir according to claim 1, characterized in that the casing has a substantially cylindrical shape with an oval cross-section. 15 3. Heating reservoir according to claim 1 or 2, characterized in that a hollow flexible element is arranged within the casing, which connects to the inner wall and communicates with the environment via a small opening in the wall. 4. Reservoir according to claim 1, 2 or 3, characterized in that the heat storage medium is a substance such as paraffin, for example, of a type which forms a porous mass on solidification, wherein the casing also contains an amount of water which collects on a bottom of the reservoir which is in contact with an electric heating element and wherein a pressure prevails in the reservoir such that the boiling point of the water substantially corresponds to the melting temperature of the heat storage medium. Reservoir according to one or more of the preceding claims, characterized in that the electrical conductors for the power supply connect to the heating elements | an adapter with plug pins mounted on the outer wall of the enclosure, said adapter being able to cooperate with an external base station provided with one or more connectors in which said plug pins can be received, the base station being provided with means for coupling to a voltage source . 12a. Reservoir according to claim 5, characterized in that an electric switch for switching on the energy supply to the heating elements is included in the electrical guides at the location of the adapter or in the base station, which after a certain, optionally adjustable , time switches off automatically. Reservoir according to one or more of the preceding claims, which is designed as a jug with an elongated cylindrical shape, characterized in that the cylindrical envelope closed on all sides is provided on a front side with a first connecting to the cylindrical envelope jacket. extension in which at least the adapter and possibly the switch is accommodated, which extension on its side facing the casing is provided with a closing front surface with a passage opening for the connector therein, on the plug pins of the adapter movable against the spring and over the 15 a sliding slide plate is provided which closes the passage opening when the jug is removed from the base station. 8. Reservoir according to claim 7, characterized in that one or more rod-shaped heating element elements 20 extend between the two end faces of the cylindrical envelope, with which heat-conducting plate-shaped elements are connected at mutually substantially equal distances, which elements extend in planes standing transversely of the rod-shaped elements . 9. Reservoir according to claim 8, characterized in that the mutual distance between the surfaces in which the heat conducting elements are located is approximately 2 cm. amounts. Reservoir according to one or more of the preceding claims, characterized in that the casing of the reservoir is at least partly made of a plastic which changes color when the temperature changes, so that the color of those parts shows whether the reservoir is with heat. charged. 008624 13a V 13. Adapter particularly suitable for use with a reservoir according to claim 9, which adapter is provided with plug pins incorporated in a housing with a passage opening extending transversely of the pins for a connector cooperating with the adapter, characterized in that a sealing plate which is movable against the spring and which is slidable over the plug pins is mounted on the plug pins, which closes the passage opening in the absence of the connector. 1 008624