TR201908262A2 - DEVICE TO DETECT WATER ICE FORMATION - Google Patents

Abstract

A device 10 for detecting water ice formation in a substructure 122, having a first permanent magnet 204 and a second permanent magnet 206. The magnets 204, 206 are separated from each other and arranged such that the north pole of one magnet 204 is opposite the south pole of the other magnet 206. A container 200 includes a mass of water 202 in the space between permanent magnets 204, 206. At least one of the magnets (204) can move in the container (200). A heat conducting arrangement 208 conducts heat conduction between the substructure 122 and the mass of water 202 contained in the container 200. As the heat is transmitted from the mass of water (202) in the container (200) to the substructure (122) and the temperature of the water (202) mass decreases below the temperature at which the density of the water is at its maximum, the volume of the mass of water increases, making the said first and second permanent magnets (204, 204, 206)

Description

DESCRIPTION DEVICE FOR DETECTING THE FORMATION OF WATER ICE Technical Area The present disclosure relates to a device for detecting the formation of water ice.

Many Appliances and apparatus that are sensitive to freezing or icing, i.e. sensitive or prone to ice formation on a part of said device or apparatus equipment and apparatus are available. Among some examples, particularly freezers and refrigeration apparatus, air-conditioning 'units etc., including refrigerators and the like. are available.

The so-called frost-free cooling apparatus, such as freezer, refrigerator and so on. Apparatuses use many methods to prevent ice formation. An example of this The method is the periodical heating of the freezer or refrigerator, possible melting of ice. For example, a freezer sensitive to ice build-up or refrigerator section for 5 or 10 minutes, or every 8 or 10 or so one can be heated. This process does not take into account whether ice has actually formed. can be wasteful and inefficient.

Examples of other frost-free refrigeration apparatus are, for example, a device that can measure temperature and humidity. or more electronic sensors and based on the output from these sensors It is based on a microcontroller that determines when decoding is required. this type arrangements are complex, requiring programming of the microcontroller and may not be reliable.

Short Description According to one aspect described here, a first permanent magnet; a second permanent magnet; wherein the first and second permanent magnets mentioned are separated and north of a magnet its pole will be opposite the south pole of the other magnet, the first and second permanent magnets are normally arranged to attract each other; At least one of the permanent magnets containing a mass of water in the area between the permanent magnets a container in which one of these permanent magnets can move relative to the other; and for conduction of heat between a said infrastructure and the body of water in the container comprising a thermal conductor arrangement; In use, heat is transferred from the water mass in the said container to the said infrastructure. as it is transmitted through the conductor arrangement, and the water body temperature, the density of the water As the temperature drops below its maximum, the volume of the water mass increases, the first and second permanent magnets are moved away from each other, A device is provided for detecting the formation of water ice in a substructure.

To detect ice build-up or to control a defrosting process in such a device electronic sensors or a microcontroller or a different processor or the like. is not needed. Therefore, the manufacture of this device is relatively simple and inexpensive. can happen.

In one example, the container containing the water mass is thermally insulating.

In one example, the device is the first and second permanent magnet, this is the first and second permanent magnet. A device that works when moved such that the distance between contains the key.

In one example, the threshold distance is the switch only when the mass of water in the container freezes. is the way it will work.

In one example, the switch includes a first electrical conductor and a second electrical conductor. said first electrical conductor is movable to move with the movable permanent magnet. it is fixed relative to the permanent magnet, the second electrical conductor is relative to the other permanent magnet are fixed, where the first electrical conductor and the second electrical conductor, the first and the second to operate the switch when the distance between permanent magnets exceeds the threshold distance. are in contact with each other.

In this example, when the first and second electrical conductors come into contact with each other, the ice in the substructure an electrical resistance heater that can be used to provide heat to dissolve can create. In other words, the device detects the ice formation in the infrastructure. and automatically performs a defrost operation to defrost when ice is detected. can be carried out as

Moreover, an infrastructure sensitive to icing; and containing a device as described above, the water mass of the heat conductor arrangement of the device, the infrastructure and the container of the device It is in thermal contact with the mentioned infrastructure to conduct heat transfer between apparatus is provided.

In an example where the device contains a key as described above, this device work will allow a heater to work to defrost the infrastructure are arranged in sequence.

The appliance ensures that the operation of the switch works as a heater is described above. The heater mentioned in an example where it is arranged in such a way as to provide can be provided by the conductor and the second electrical conductor.

In one example, when the first and second electrical conductors come into contact with each other, the apparatus said first and second electrical power when electrical power passes through the and second electrical conductors a second heat transfer arrangement to transfer heat from electrical conductors to the infrastructure contains.

In one example, the apparatus is a cooling apparatus and the substructure is refrigerated from this cooling apparatus. It is a tube carrying matter.

Brief Description of Figures To help understand the current explanation and how to apply the applications Reference is made to the attached figures by way of example to show that it can be put Figure 1 shows an example device and an example cooling suitable for an application in the present disclosure. shows its apparatus schematically; and Figure 2 schematically represents a more detailed and partially fictitious view of the device in Figure 1. shows.

Detailed Description will be used to cover the like. "cooling apparatus" as used herein The expression also refers specifically to a refrigerant unless the context requires otherwise. sensitive to icing, including devices or apparatus based on It may include air-conditioning units and other devices or apparatus.

For detecting water ice formation in a substructure in the samples in the present disclosure A device is provided, which is protected from the magnetic force of permanent magnets and water. expansion of water when its temperature drops (approximately) below 4°C andi'or water at 0°C it takes advantage of the fact that it freezes to form ice. Defrosting this appliance electronic sensors or a microcontroller or a different No processor or similar is needed. In some instances the device is also a contains a switch to operate the heater and/or the appliance itself can work as

Now looking at the figures, Figure 1 shows that the existing illustrates schematically an exemplary device (10) suitable for an embodiment in the disclosure.

In this example, the cooling apparatus 100 is a refrigerator or freezer. In some examples refrigerator, air conditioner or those who are sensitive to frost or There may be another apparatus with counter sensitive parts.

The cooling apparatus (100) is used to cool an area (110) within this cooling apparatus (100). uses a vapor compression cooling cycle. Specifically, in this example the steam The compression refrigeration cycle (described in more detail below) (110) is applied to cool a freezer section (111) below 0°C.

Other parts of the said area (110) are also dependent on the temperature of the freezer section (111) and It will be cooled depending on the arrangement of the cooling apparatus (100). In any case, the freezer section (111) mentioned alanine (110), eg food item etc. substances such as denotes a subdivision in which it can be placed to be frozen. More generally, the vapor compression refrigeration cycle, such a freezer in the refrigeration apparatus (100) to cool an area (110) of the said cooling apparatus (100), even if there is no section. can be used.

The refrigeration apparatus (100) is to remove the interior of a space (110) (for example, the food of a refrigeration apparatus). substance storage section) with a refrigerant selected to cool the closed circuit piping system (120). Specifically, the piping circuit (120) an interior (122) located within the freezer section (111) and an outside space (110) a disc portion (124).

As the refrigerant absorbs the heat from the inside of the freezer section (111), it moves inside (122) It is selected to have an evaporation temperature so that it will evaporate. This For this reason, core 122 is often referred to as an evaporator 122.

Compressing the evaporated refrigerant and thereby greatly increasing its temperature There is a compressor (123) for High pressure and high temperature refrigerant substance vapor from said compressor via the "hot" disk 124 of circuit 120 (123) passes. The disk 124 acts as a condenser in the cooling loop. it transfers heat to the environment (for example, to the room where the cooling apparatus (100) is located). Heat A heat sink or fan may be provided to improve transmission. Heat transfer on the outer part (124) at least part of the refrigerant vapor back into a liquid form. it provides concentration.

High pressure, currently refrigerated and at least partially in liquid form The refrigerant causes its expansion and cooling by lowering the refrigerant pressure. It passes to an expansion valve (121) which is Then low pressure and low temperature refrigerant, heat from the inside of said freezer section (111) freezer section by acting as an evaporator in the cooling cycle to absorb It passes through the evaporator (122) in (111). As a result mentioned The refrigerant liquid passing through the evaporator (122) completes the cooling cycle. It evaporates before passing to the compressor (123) for

Compressor (123) is connected to the refrigerant vapor pressure and the outer part of the circuit (124). according to the temperature required and the required cooling rate for the evaporator (122) of the circuit can be driven by a selected, low-power DC motor.

by the evaporator (122) of the piping system (120) in the freezer section (111). Due to the low temperatures created, moisture in the air freezes to the evaporator (122). Over time, it causes the formation of an ice layer. In the evaporator (122) and/or ice formation on other parts of the cooling apparatus (100) (as "icing" also called ) is undesirable because said freezer section (111) or in other parts of the refrigeration apparatus (100), otherwise for storage purposes. (eg storage of foodstuffs) takes up space in usable areas and reduces the efficiency of the cooling apparatus (100). A user of the cooling apparatus, allowing the freezer section (111) to warm up to a point where the ice melts and The resulting liquid water is thrown out and the cooling apparatus (100) is periodically manually operated. Some known refrigeration apparatus is used to melt the layer of ice and thereby freeze it. to heat the freezer section for a short time in order to defrost the section. It has an arrangement such as a heating resistor or another heating element. This type is known defrosting in a refrigeration apparatus determines how much ice actually is in the evaporator. automatically and periodically in a cycle, regardless of when realizable. This process takes into account whether ice has actually formed. It can be wasteful and inefficient because it does not have Non-icing cooling apparatus Other examples of When is defrosting necessary based on the sensor and the output from these sensors? It is based on a microcontroller that determines Such arrangements are complex, requires programming of the microcontroller and may not be reliable.

According to an example of the present disclosure, the device (10) is in a part of the cooling apparatus (100). It is used to detect the formation of ice or “frost”. In this example device (10) although it is used specifically to detect ice formation in the evaporator 122, It can also be used to detect ice formation in other sections. This is the device (10) For example, there is no need for an electronic sensor or controller or the like.

Referring specifically to Figure 2, a more detailed and partially imaginary view of the device 10 displayed schematically. Said device (10) is a vessel in which a mass of water (202) is present. container (200). This container 200 is a hollow cylinder. of the container (200) its walls are thermally insulating. Container (200) eg made of plastic material can be achieved. separated from each other by its mass. The aforementioned magnets (204, 206) are of opposite poles. They are arranged in such a way that they are opposite to each other. In other words, you are a magnet (204) the north pole is opposite the south pole of the other magnet (206). So magnets (204, is in motion. In the example shown, the magnet (204) at the top of the figure is the container. (200) is mobile. (Uses such as “top”, “bottom” and the like here refer to figures. It is used to provide convenience when referring. In general, the upper magnet vertical orientation where it can move vertically up and down is probably the most suitable and device 10 can be arranged in other orientations, although this is an efficient orientation.) In this example, the other The magnet 206 is fixed against movement inside the container 200. In this direction, said magnets (204, 206) are normally connected to each other by magnetic attraction. water (202) is kept separate by the mass.

The device 10 is anti-icing, which in this example is the evaporator 122 of the cooling apparatus 100. It is in thermal communication with the sensitive infrastructure or department. Specifically, water (202) The mass is in thermal communication with the evaporator (122). In the example shown, this is A first heat conducting arrangement (208) extending between the mass (202) and the evaporator (122) is carried out with In the example shown, the heat conductor arrangement 208 is either copper or aluminum etc. metal rods with high thermal conductivity, such as is created. In this specific example, the thermal conductor arrangement 208 is connected to the device 10 two clamps extending out from the body and clampable around the evaporator (122) it has a clamping section (210) formed from the arm. A high thermal conductivity another heat conductor (212) which may consist of metal or the like, said clamp It extends from the section (210) to the body of the device (10) and is in thermal contact with the water (202) mass. doing. Cover the container so that the heat conductor (212) is in contact with the water (202), for example. 200 can pass through an opening or through hole in the wall. As an alternaive, the wall of the container 200 (generally thermally insulating) is a thermally conductive panel or may have an insert or the like, and said thermal conductor (212) is connected to a thermally conductive part. is in contact.

In use, if and when ice forms on the evaporator (122), the thermal conductor arrangement is transmitted. This causes the temperature of the water 202 to drop. As known the maximum density of water is (approximately) at 4°C, that is, above the freezing point of 0°C. Water is somewhat exceptional because it is at a temperature above (standard pressure). This The temperature of the water (202) in the container (200) in the direction of when it falls, the volume of water (202) increases. These permanent magnets (204, 206) it removes. Also, as it is known, water reaches 0°C to form ice. when frozen, the volume increases quite drastically by about 9%. This in direction, as the temperature of the water (202) in the container (200) drops to 0°C, the water Freezing (202) separates the permanent magnets (204, 206) by a relatively high amount (particularly, if the walls of the container 200 are preferably rigid, it will take about approx. this separation movement is an indication that ice has formed in the evaporator (122). can be counted. What does this mean (electronic or similar) temperature sensor, humidity sensor, etc.? It should be taken into account that it was obtained without any need.

Therefore, in this example the device (10) described so far, the cooling apparatus (100) It works to detect ice formation on the infrastructure with an evaporator (122).

Said device (10) is also used to melt or defrost the ice in the evaporator (122). It can be arranged so that the evaporator 122 is heated. For this, the device (10), such that movement of the moving magnet 204 at a threshold distance will operate a switch can be arranged. Threshold distance, eg water falling somewhere between 4°C and 0°C (202) It may be small to correspond to the temperature. Alternatively, the threshold distance, for example Corresponds to the temperature of the water (202) falling to 0°C and thus the time when the water (202) freezes may be larger. 216) eg nichrome (NiCr, nickel-chromium), cupro nickel or nickel copper (CuNi) etc. as For example, it can be formed from metal. A first (214) of the electrical conductors is movable. it is fixed with respect to this movable magnet (204) to move with the magnet (204) (for example, by connecting directly to the moving magnet (204)). Second electrical conductor (216) other it is fixed according to the magnet (206). Said second electrical conductor (216) opposite the electrical conductor (216) and in the travel path of the first electrical conductor (214). will be arranged as follows. Also, the two electrical conductors (214, 216) are normally (202) when the temperature is relatively high (which means ice in the evaporator (122) states that it does not occur) are separated from each other. Electrical conductors (214, 216) as the temperature of the water (202) drops and, in one example, as the water (202) freezes, the first moving electrical conductor (214) of the movement of the moving magnet (204) to the second electrical It is such that it comes into contact with the conductor (216). The two electrical conductors mentioned (214, 216) has the effect of closing a switch. For example, two electrical conductors (214i 216) are in contact with the evaporator (122) or connected to a heater (not shown) located at least in the vicinity of the evaporator (122) It can be part of an electrical circuit. Two electrical conductors (214, 216) are connected to each other. contact, this can be used to turn on the heater and thus the ice formed in the evaporator 122 is melted.

In another example, the device 10 is provided when two electrical conductors 214, 216) are brought into contact with each other. an electrical resistance heater to melt the ice formed in the evaporator (122) can provide. For example, two electrical conductors (214, 216) are connected by a power source. It can be connected to opposite sides of the power supply to form a circuit. Mentioned when two electrical conductors (214, 216) are brought into contact with each other, the circuit is closed, of electrical power, heating two electrical conductors (214, 216) between these two electrical It is provided to pass through the conductor (214, 216).

In another example shown in Figure 2, the device 10 is for two electrical conductors 214, 216). formed of an electrically conductive material that may be the same material used it has a main tooth slot (218). Container 200 for water (202) and two permanent magnets from one side to the socket (218), and from the other side to the first (moving) electrical conductor (214). is connecting. The power supply 220 is ultimately powered from an AC mains power source. can obtain. Connection of power supply 220 to first electrical conductor 214 It is carried out through the long slot 222 in a wall of the housing 218, so that as the first electrical conductor (214) moves back and forth within the housing (218) continuation is provided. Two electrical conductors (214, 216) are brought into contact with each other, which it closes the circuit with the power supply (220). In this example, this is the case with slot (218) and the first causes the secondary electrical conductors (214, 216) to heat up.

In both of these last two examples, the first and second electrical conductors (214, 216) and optionally, as the housing (218) heats up, this heat is used to melt the ice in the evaporator (122). is used.

In these last two examples, the first and second electrical conductors (214, 216) and optionally Several options are possible for transferring heat from slot 218 to evaporator 122.

In one example, the device 10 is simply placed near the evaporator 122 so that The heat is transferred via convection. Alternatively or additionally, the device (10) having a second heat conductive arrangement (224) extending between (218) and evaporator (122) can happen. As in the aforementioned first heat conductor arrangement (208), the second heat conductor conductor arrangement (224), extendable from device (10) and evaporator (122) having a clamping section (226) consisting of two clamping arms that can be clamped around can happen. In this way, the heat passes to the evaporator (122) by conduction, which It can also ensure that the work is melted faster and more efficiently. the heat Several such secondary heat-conducting arrangements may be available for passage through the evaporator 122.

This is especially true if several specific evaporator (122) parts are sensitive to icing. found, it may be useful as work can be directed more specifically to these parts.

On the other hand, it is more important to heat the evaporator 122 more generally. there are situations where it is appropriate. In this case, said evaporator (122) There may be no thermal conduction, instead the heat transfer is by convection. can be done.

In any case, when the ice in the evaporator (122) melts and its temperature rises above 0°C The heat is transferred from the evaporator (122) by the first heat-conducting arrangement (208) to the container. (200) is transferred to the “water” (202) mass (which is currently ice). This, it melts the ice (202) in the container (200) and causes its volume to decrease. Two pulling, breaking the contact between the two electrical conductors (214, 216). This is an external heater of the heater, regardless of whether it is or is supplied by the device (10). causing it to shut down.

The device (10) is therefore, in this example, the evaporator (122) of a cooling apparatus, however, in other examples, a different part of a cooling apparatus or other apparatus It enables the detection of ice formation in an infrastructure that may be a component or component of it.

This does not require an electronic sensor or microcontroller or other processor or the like. achieved without being heard. In one example, the device 10 is also used to melt the ice. provides a heater for warming the ice, or at least ice formation in the infrastructure a heater for a heater that automatically turns on to melt ice when detected provides key.

In the example shown, the first electrical conductor 214 is a sphere, or at least a hemisphere. and the second electrical conductor 216 is correspondingly hemispherical.

This provides a large and large contact area between the first and second electrical conductors (214, 216). it provides. Alternatively, the first and second electrical conductors 214, 216) may be cylindrical, such as may be in a different form.

The device (10) is essentially powered by a cooling apparatus (100) such as a refrigerator or freezer. use for detecting and defrosting ice formed in the evaporator (122) has been explained. As mentioned, said device (10) is, for example, a heat exchanger or including air-conditioning units or different apparatus with other parts prone to icing can be used in other applications as well.

The device (10) may also be associated with the sample in which the liquid (202) in the container (200) is water. has been explained. As will be appreciated, this includes a property of water called "abnormal", in other words, a constant volume of water body, which is more common as the water freezes. It is based on the property of increasing instead of falling. Even if it is frozen or not at least other, whose volume increases as the temperature drops from a certain temperature to another materials are also available. Such materials include fused silica, silicon, gallium, germanium, antimony and bismuth. Depending on the specific application and the temperatures involved Depending on the container (200), such materials can be used instead of or in addition to water. possible to use.

The examples described herein serve as illustrative examples of embodiments of the invention. is to be understood. Other applications and examples are envisaged. any sample or any feature defined in relation to the application alone or other features Can be used in combination with Also, any example or application any of the features described in relation to it are furthermore examples or applications of one or in combination with more features, or in other examples or applications Can be used in any combination. Also, equivalents not described here and modifications may also fall within the scope of the invention as set forth in the claims.

Claims (10)

REQUESTS 1. A first permanent magnet; a second permanent magnet; wherein said first and second permanent magnets are separated and arranged such that the north pole of one magnet is opposite the south pole of the other magnet, the first and second permanent magnets normally attracting each other; a container containing a mass of water in the area between the permanent magnets, in which at least one of the permanent magnets can move relative to the other of these permanent magnets; and a heat conducting arrangement for conducting heat between said infrastructure and the body of water contained in the container; in use, as the heat is transmitted from the water body in said container to a said infrastructure by means of a heat-conducting arrangement and the temperature of the water body falls below the temperature at which the water density is at its maximum. A device for detecting the formation of water ice in a substructure, in which the volume of the body of water is increased and said first and second permanent magnets are moved away from each other. 2. A device according to claim 1, wherein the container containing the water mass is thermally insulating. 3. A device according to claim 1 or claim 2, comprising a switch that operates when the first and second permanent magnet is moved such that the distance between this first and second permanent magnet exceeds a threshold distance. 4. A device according to claim 3, wherein the threshold distance is such that the switch will only work when the mass of water in the container has frozen. 5. A device according to claim 3 or claim 4, wherein the switch comprises a first electrical conductor and a second electrical conductor, said first electrical conductor being fixed relative to the movable permanent magnet to move with the movable permanent magnet, the second electrical conductor being fixed to the other permanent magnet. and the first electrical conductor and the second electrical conductor are brought into contact with each other to operate the switch when the distance between the first and second permanent magnets exceeds the threshold distance. 6. An infrastructure sensitive to icing; and comprising a device according to any one of claims 1 to 5, wherein the thermal conductor arrangement of the device is in thermal contact with said infrastructure to conduct heat transfer between the infrastructure and the body of water in the container of the device. Apparatus according to claim 6, wherein the device is a device according to any one of claims 3 to 5, arranged such that the operation of the switch causes a heater to operate to defrost the substructure. 8. Apparatus according to claim 1, wherein the device is a device according to claim 5 and the heater is provided by the first electrical conductor and the second electrical conductor of the device. 9. Apparatus according to claim 8, comprising a second heat transfer arrangement for transferring heat from said first and second electrical conductors to the infrastructure when electrical power passes through these first and second electrical conductors when the first and second electrical conductors come into contact with each other. 10. Apparatus according to any one of claims 6 to 9, wherein the apparatus is a cooling apparatus, and the substructure is a tube carrying refrigerant from this cooling apparatus.