RU2529969C2 - Device containing boiler for storage and heating of liquid and system for storage of liquid at lower temperature - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: device includes a boiler for storage and heating of liquid and a cold liquid system that is interconnected with the boiler. During operation of the device, the boiler is brought into action for heating of some amount of liquid, which is supplied from the cold liquid system. In order to avoid heating of the liquid that is contained inside the cold liquid system and cooling of the liquid that is contained inside the boiler, measures are taken to prevent the liquid backflow. Such measures include the use of the device located upstream of the boiler, which allows avoiding heat transfer, performing heat insulation in the place located before the boiler and having an air retaining device.

EFFECT: invention relates to heat power engineering and can be used in boilers and water heaters connected to a storage tank and operating at low pressure.

14 cl, 11 dwg

Description

FIELD OF THE INVENTION

The present invention relates to a device comprising:

- a boiler for containing and heating a liquid, such as water; and

- a system for cold liquid, which is in fluid communication with the boiler and which is designed to contain liquid at a lower temperature than the hot liquid from the boiler.

State of the art

The device mentioned in the introductory paragraph is well known in practice. For example, the device may be a water purification device. In most cases, such a device is a gravity-based device in which water flows through the device and the filter, which is part of the device, only under the influence of gravity, without using a pump or the like. Therefore, in such a device, the boiler is located at a lower level than the cold liquid system, which in most practical cases contains a storage tank. In addition, such a device is equipped with a piping system for connecting the storage tank and the boiler. The functioning of various elements of the device takes into account the fact that only very low pressures are used in the device, for example, only pressure due to the height of the water column between the storage tank and the boiler can be applied.

Well-known gravity-based water purification devices are associated with the problem that when the boiler is driven to heat a certain amount of water, the water in the storage tank is also heated. The storage tank is designed to hold water at ambient temperature, however, when the boiler is activated, due to the presence of the connection between the storage tank and the boiler, the water temperature in the storage tank rises. In this regard, it should be noted that between volumes of water with different temperatures there always exists a heat flux independent of the shape or size of pipelines and other elements designed to contain and / or move water. Due to the fact that only low pressures prevail in the device, it is impossible to use complex valves, for example, spring-return valves or valves with moving parts, to separate hot water in a boiler and much colder water in a storage tank.

Hot water in the boiler has a lower density than water in the storage tank and the piping system that connects the storage tank and the boiler. Due to the difference in density, hot water tends to rise to a higher level in the device and move towards the storage tank, while cold water tends to sink into the device. As a result, the water in the storage tank becomes warmer over time, while the boiler needs energy to heat cold water, which has gone down.

Patent Application WO 98/51970 proposes a freestanding, non-pressurized hot and cold water cooler comprising a water tank capable of being replenished with water from an inverted removable bottle mounted on top of the cooler; a cold water tank, a hot water tank, a check valve located in a pipe supplying water from the water tank to the hot water tank to prevent the return of heated water in the hot water tank to the water tank or to the cold water tank; and an expansion chamber connected to the hot water tank to allow the heated water to expand and to maintain the water in the hot water tank, essentially at atmospheric pressure. However, such a cooler is not amenable to thermal insulation.

SUMMARY OF THE INVENTION

An object of the present invention is to solve the aforementioned problem of an undesirable increase in the temperature of the water in the storage tank due to the flow of relatively hot water from the boiler into the storage tank. An object of the present invention is also to solve the aforementioned problem of an undesired increase in energy that is required for heating water in a boiler due to the flow of relatively cold water into the boiler from the storage tank.

According to the present invention, there is provided a device comprising a boiler and a cold liquid system as previously described, wherein the device is further equipped with means for preventing liquid from flowing back from the boiler into the cold liquid system and for insulating it in a place located upstream of the boiler.

It should be noted that the means for preventing the backflow of liquid from the boiler to the cold liquid system and for insulating in the place located downstream of the boiler has a simple structure in which both of these functions are combined. For example, in order to prevent backflow, the device according to the present invention may include a non-return valve, allowing fluid to flow in the direction from the cold fluid system to the boiler and blocking flow in the other direction. In a gravity-based device, the valve may be a low pressure valve, such as an umbrella valve or a duck nose valve. However, usually such a valve is very thin, resulting in significant heat transfer through such a valve. Therefore, in the case of the use of the aforementioned thin valve, despite the fact that with the help of such a valve it is possible to block the direct flow of liquid, a design that performs a heat-insulating function must also be used in order to avoid cooling of the hot liquid under the influence of the presence of cold liquid and heating of the cold liquid under the influence of the presence of hot liquid. For example, a space can be provided near the valve to hold air.

In any case, when the present invention is applied, it provides a structure in which liquid cannot flow in the direction from the boiler to the cold liquid system, and the hot liquid is isolated from the cold liquid. As a useful consequence, there is no longer any inconvenience for the user using the device, who expects to find liquid with an ambient temperature in the cold liquid system, but finds a certain amount of warm liquid there. In addition, the energy consumption of the boiler is reduced, since the temperature from the side of the boiler part of the device no longer drops continuously under the influence of interaction with the liquid from the cold liquid system. Another useful consequence of the improved separation of hot liquid and cold liquid is that in a cold liquid system there is probably no phenomenon known as scale formation (biological fouling), or at least it slows down to such an extent that it does not occur health situations during normal use of the device according to the present invention.

Regarding the possibility of the presence of a check valve in the device to prevent backflow, it should be noted that such a valve may be a type of valve that is configured to open under the influence of fluid pressure. This option is especially useful when it is required that the design of the device according to the present invention is as simple as possible, when there is no need for a valve with moving parts, which must necessarily be actively moved to the open position or closed position using a microcontroller or the like.

Preferably, the device according to the present invention contains a space for holding air, which is located in a place located upstream of the boiler. Using this method, an air plug is created that can be positioned so as to isolate the hot liquid in the boiler from the cold liquid in the cold liquid system. Preferably, the design of the air holding space is such that air is trapped automatically when the device is filled with liquid. In this case, a certain amount of air will remain inside the device until the device is filled with liquid. In addition, the air lock is restored every time the device, including the boiler, is emptied and replenished with liquid.

Within the scope of the present invention, the cold liquid system and the boiler can be directly connected to each other, but it is also possible that the device according to the present invention comprises a piping system interconnecting the cold liquid system and the boiler, which contains a pipe passing between the system for cold liquid and a boiler, in which the space for holding air is located on a section of the pipeline having a larger cross-sectional area than neighboring areas. With this configuration, various kinds of practical measures can be taken to ensure that air stays in a specific section of the pipeline, where you can take advantage of the fact that the barriers will be in those places where the section of the pipeline with a larger cross-sectional area is connected to areas with smaller cross-sectional areas sections.

In a practical embodiment of the invention, the device may comprise means for preventing the space for holding air from being filled with liquid from the side of the cold liquid system in the form of a wall blocking access to the space for holding air. The presence in the device of a physical barrier restricting at least a portion of the space for holding air is a suitable way to ensure that air is held in the space for holding air based on the fact that the liquid cannot reach this space.

According to the first possibility, the device contains a pipeline system containing a pipeline passing between the cold liquid system and the boiler, where the pipe element is located inside the pipe, and where the cross-sectional area of at least the end section of the pipe element, in particular the end section, which located on the boiler side, less than the cross-sectional area of the pipeline at the place where the end section of the pipe element is located. In this case, the wall of the end portion of the tube element forms a physical barrier between the region where the fluid flow is during operation of the device, namely, inside the tube element, and the region that the liquid cannot reach, including the space for holding air that is between the wall end section of the pipe element and the wall of the pipeline.

Preferably, the wall of the tube element is a thin wall and consists of a flexible material, so that the end portion of the tube element can be used as a check valve that can open and close under very low pressures, such as those prevailing in a gravity-based device. Such an embodiment of the invention, comprising a tubular element extending inside the pipeline, at the same time has the advantage of a compact and simple design and a useful valve function and air retention function, thereby preventing fluid from flowing back from the boiler into the cold fluid system and also preventing heat transfer through the valve.

According to the second possibility, existing within the framework of the concept of having a wall blocking access to the space for holding air, the space for holding air is determined by the internal space of the hollow element containing air. In this case, the wall of the hollow element is a wall that prevents filling the space for holding air with liquid. The hollow element can be freely placed inside the pipeline section of the pipeline system having a larger cross-sectional area than the adjacent sections, where the cross-sectional area of the hollow element is larger than the cross-sectional area of the adjacent pipeline sections. Based on the difference in the sizes of the cross-sectional areas, the hollow element and the air contained in it cannot leave a certain section of the pipeline. In addition, due to the free arrangement of the hollow element, the hollow element can serve as a valve. In particular, when a hollow member blocks an opening that is between a portion of the pipeline with a larger cross-sectional area and a portion of the pipeline with a smaller cross-sectional area, fluid backflow from the boiler to the cold fluid system is prevented, despite the fact that under the influence of the fluid flow pressure from the system for cold liquid to the boiler, the hollow element can float inside the pipeline with a larger cross-sectional area so that the aforementioned hole is larger e is blocked.

The hollow element may be of any shape suitable for holding a certain amount of air. For example, the hollow element may have a spherical shape and be completely closed, or may have a domed shape in which one side of the hollow element, in particular the lower part of the hollow element, is open.

According to another option, which is applicable when, in addition to the hollow element, the device comprises a separate valve, the hollow element can be connected to the valve. With this configuration, heat transfer through the valve is minimized, since the insulating effect of the presence of air occurs directly at the location of the valve.

It should be noted that when a hollow element is used, it may be that such an element is filled with other suitable heat-insulating material other than air, especially when the hollow element is completely closed.

When the device contains a space for holding air, another preferred option for creating a check valve function and enhancing the heat-insulating function of the space is a means used to convert a liquid stream flowing from a cold liquid system into a boiler into small droplets. In particular, with the help of the aforementioned means, it is achieved that there is never physical contact between the liquid on one side of the space for holding air and the liquid on the other side of the space for holding air, with the maximum degree of thermal insulation. In addition, liquid cannot flow from the boiler to the cold liquid system, since air blocks the return path for the liquid.

The use of a means for converting a liquid stream into streams of small droplets is particularly useful in a configuration in which the cold liquid system is placed at a higher level than the boiler, and in which the means is placed above the air holding space. Small droplets can then simply fall from such a device in the direction of the pipeline leading to the boiler, crossing the space for holding air. In a practical embodiment, the means for converting a fluid stream into streams of small droplets comprises a number of thin plates, thin tubes, fibers or the like, which are located close to each other with a small space between them. The advantage of using fibers is that the agent can also perform the function of cleaning the liquid.

In the device according to the present invention, at least a portion of the boiler may be located at a lower level than the cold liquid system. In this regard, it should be noted that the device may be a device based on gravity, in which the flow of fluid occurs only under the influence of gravity. A specific aspect of a gravity-based device is that such a device can operate without a pump or the like, so that energy and space can be saved, which may be advantageous in various applications of the device. In a gravity-based device, when the non-return valve is located in the piping of the piping system, it is preferred that the space for holding air is between the valve and the boiler. When the space for holding air is located on the boiler side of the valve, the liquid inside the boiler is maintained at the highest possible temperature, since taking into account the insulating effect of the space for holding air, the process of heat transfer to the valve and the device elements located behind the valve is difficult.

The above and other aspects of the present invention will be apparent and identified with reference to the following detailed description of a number of embodiments of the device according to the present invention, paying particular attention to that portion of the device where the air holding space is located.

A heating and metered water supply system is described in patent application WO 98/51970. The system includes a cooler containing a water tank that can be replenished with water from an inverted bottle. The bottle is installed at the top of the cooler. The system additionally includes a cold water tank, a hot water tank and a check valve, which is located in the tube. The tube delivers water from the water tank to the hot water tank and prevents the return of heated water in the hot water tank to the cold water tank. An expansion chamber is connected to the hot water tank to allow the heated water to expand. The cold water tank is thermally insulated from the expansion chamber and the hot water tank.

Brief Description of the Drawings

Further, the present invention will be explained in more detail with reference to the figures in which equivalent or similar parts are indicated with the same designations, and in which:

1 schematically shows a number of components of a device according to the present invention, including a storage tank, a boiler, and a conduit extending from the storage tank to the boiler;

figure 2 schematically shows a section of the pipeline, where there is a space for holding air;

FIGS. 3–9 illustrate a number of alternative options that exist within the scope of the present invention for constructing a portion of a pipeline in which there is a space for holding air;

figure 10 schematically shows a number of components of an alternative embodiment of the device according to the present invention, including pipelines for cold water and a boiler.

In the figures, the direction of water flow is indicated by arrows.

Detailed Description of Embodiments

1 schematically shows a number of components of a device 1 according to the present invention. In this example, device 1 is a water purification device, but this does not negate the fact that the present invention is also applicable to other types of devices.

The device 1 comprises a storage tank 2 for containing water and a boiler 3 for containing and heating water. Figure 1 illustrates the location of the storage tank 2 and the boiler 3, which refers to the normal arrangement of the device 1, and it is shown that the boiler 3 is located at a lower level than the storage tank 2. The storage tank 2 and the boiler 3 are interconnected pipeline 4, which runs from the storage tank 2 to the boiler 3 and which in the above example occupies, in fact, a vertical position. In addition, in the above example, between the storage tank 2 and the boiler 3 is placed a tube to remove air 5.

The process of filling the boiler 3 occurs under the influence of gravity, in which water flows from the storage tank 2 into the boiler 3 through the pipe 4. The boiler 3 contains a suitable heating means for heating water and / or boiling water.

The device 1 has two water taps 6, 7, namely a water tap 6, which is connected to the storage tank 2 and serves to supply water from the storage tank 2, and a water tap 7, which is connected to the boiler 3 and serves to supply water from boiler 3. The user using the device 1, applies the first water tap 6 in the case when you want to get water from the device 1 with ambient temperature, at the same time when you want to get hot water from the device 1, the user uses a second water tap 7 .

The present invention relates to measures aimed at avoiding an undesirable supply of hot water to the storage tank 2 and an undesirable supply of cold water to the boiler 3 through line 4, which can occur in any case when line 4 is simply opened. In particular, according to the present invention, measures are taken to prevent the backflow of water through the pipe 4, that is, to flow back from the boiler 3 back to the storage tank 2, and in order to create thermal insulation in the place located between the storage tank 2 and boiler 3.

Figure 2 shows a detailed image of figure 1, namely, section 8 of the pipeline 4, having a larger cross-sectional area than the neighboring sections, and thereby illustrates the first example of the implementation of functions to eliminate backflow of water and isolate hot water from cold (c ambient temperature) of the water mentioned in the previous paragraph. In the above example, a thin, flexible pipe element 9 is placed inside a section 8 of the pipeline 4 having a relatively large cross-sectional area, which will hereinafter be referred to as an expanded section of the pipeline 8. One end of the pipe element 9 is located on the expanded section of the pipeline 8 from the side of the storage tank, and the other end of the pipe element 9 is located on the expanded section of the pipeline 8 from the side of the boiler. On the boiler side, the pipe element 9 has a conical shape in which the end 10 of the pipe element 9 is usually closed. Only under the influence of the pressure drop between one side of the normally closed end 10 and the other side, the pipe element 9 opens and allows water to pass through it.

In the device 1 for water purification from the side of the storage tank 2 under the action of gravity is applied pressure. When the pipe element 9 opens under the influence of such pressure, water flows from the storage tank 2 into the boiler 3. As soon as the pressure weakens, the pipe element 9 closes again due to the tendency of the material of the pipe element 9 to take its initial closed position, and / or at the end 10 the tube element 9 is pressurized with a certain amount of air, which serves to block the end 10, as will be explained later. In any case, in the closed state of the pipe element 9, the reverse flow of water from the boiler 3 to the storage tank 2 cannot occur. Therefore, the pipe element 9 acts like a check valve, which is configured to allow water to flow only from the storage tank 2 into the boiler 3, while blocking the passage in the opposite direction. In particular, the tubular element 9 acts like a so-called duck nose valve.

In addition, due to the conical shape of the tube element 9, an air holding space 11 is obtained in an expanded section of the pipe 8, namely, at the place where the space between the outer wall of the pipe element 9 and the inner wall of the pipe 4 is located. The air holding space 11 cannot be filled water flowing from the storage tank 2 into the boiler 3, since it is directed through the expanded section of the pipeline 8 by the pipe element 9, and the air that remains inside the expanded section of the pipe 8, as only the device 1 is filled, held inside the space 11 for holding air, where it is surrounded by the wall of the pipe 4, the wall of the pipe element 9 and water from the side of the boiler, and cannot leave this space.

Based on the air present in the air holding space 11, a heat-insulating effect is created in which the insulation is between relatively cold water from the storage tank side and relatively hot water from the boiler side. Thus, it is achieved that the water temperature in the storage tank 2 is practically independent of the temperature of the water in the boiler 3, and that the water temperature in the boiler 3 is practically independent of the temperature of the water in the storage tank 2.

As a result, the device 1 according to the present invention is capable of performing the same water purification function and the water storage function as the well-known water purification device. Since the tube element 9 can open at low pressure, there is practically no effect on the flow of water from the storage tank 2 to the boiler 3. The beneficial effects of the design with the tube element 9 perform the function of a valve that prevents the backflow of water, and a heat-insulating function that minimizes heat transfer between the water from the storage tank and the water from the boiler.

Within the scope of the present invention, there are many alternative embodiments of valve function and heat insulating function, which are described above. 3-9 serve to illustrate several such alternative options.

Figure 3 shows a first alternative embodiment. According to such an alternative embodiment, the pipe element 9 is rigid, does not have a conical shape and is not capable of performing the function of a valve. Therefore, the tubular element 9 on the side of the storage tank is provided with a separate valve 13, where the valve 13 can be a relatively simple valve that can open under low pressure, such as an umbrella valve. As is the case in the embodiment of the invention described in FIG. 2, an air holding space 11 is located between the outer wall of the pipe element 9 and the inner wall of the pipe 4 to perform an insulating function in place of the expanded portion of the pipe 8.

4 shows a second alternative embodiment. According to such an alternative embodiment, the pipe element 9 is absent, but the air holding space 11 is simply formed by the upper portion of the expanded portion of the pipe 8. At the junction of the expanded portion of the pipe 8 with a nearby portion of the pipe 12 from the storage tank side, there is a valve 13 that is able to provide water with the possibility pass from the storage tank 2 into the boiler 3 through the space 11 for holding air and which is able to block the water path in the opposite direction in this way that air cannot exit space 11 to hold air. For example, valve 13 is an electromagnetic valve that opens by electricity. In this case, the functioning of the valve 13 is not directly dependent on the pressures prevailing on both sides of the valve 13, and the proper operation of the valve 13 is also guaranteed in situations where the pressures are higher than in the device 1 based on gravity.

5 shows a third alternative embodiment. According to such an alternative embodiment, the umbrella valve 13 is located in an expanded section of the pipe 8 from the side of the storage tank, and the space 11 for holding air is located directly below the lower surface of the valve 13, acting from the side of the storage tank towards the boiler.

6 shows a fourth alternative embodiment. According to such an alternative embodiment, an umbrella valve 13 is used as in the third alternative embodiment. However, the air holding space 11 is provided in the form of a hollow member 14 containing air or other heat insulating material that is connected to the valve 13.

7 shows a fifth alternative. According to such an alternative embodiment, a device 15 is used to convert a stream of water into small drops of water. In the above example, such a device 15 contains many thin plates, thin tubes, fibers or the like, which are at a relatively small distance relative to each other. The use of fibers in the droplet forming device 15 is preferable since, based on such application, the droplet forming device 15 can also be used for water purification.

The droplet-forming device 15 is placed on the side of the storage tank close to the expanded section of the pipeline 8, in which the space 11 for holding air is located in the upper part of the expanded section of the pipe 8. Under the pressure that is applied from the side of the storage tank 2, the water flow is supplied to the droplet-forming the device 15, and as water passes through the device 15, small drops of water are formed, which drip in the direction of the expanded section of the pipeline 8 from the side of the boiler. By supplying water in the form of small drops to the boiler 3, there is no direct contact between the water on the storage tank side and the water on the boiler side, so that the heat-insulating function of the air holding space 11 is even further enhanced. Based on the fact that the droplet forming device 15 exerts a certain resistance to flow, the droplet forming device 15 has a valve function. However, if required, an additional valve 13 may be used, such as an umbrella valve, which is shown in FIG.

On Fig shows a sixth alternative. According to such an alternative embodiment, the hollow element 14 containing air or other heat insulating material is placed inside the expanded section of the pipe 8, and such a hollow element 14 floats freely inside the expanded section of the pipe 8. In the above example, the hollow element 14 has a spherical shape, while the cross-sectional area the hollow element 14 is smaller than the cross-sectional area of the extended section of the pipe 8, and larger than the cross-sectional area of the adjacent pipe sections pipelines 12, 16. In this case, it is guaranteed that the hollow element 14 cannot exit the expanded section of the pipeline 8. At the expanded section of the pipeline 8 from the side of the storage tank, the pipe 4 narrows so that the hollow element 14 smoothly pushes towards the blocking passage an expanded section of the pipeline 8 to a nearby section of the pipeline 12 from the side of the storage tank when pressure is not applied. However, when pressure is applied, the hollow element 14 is slightly shifted so that water is allowed to pass between the hollow element 14 and the inner wall of the pipe 4. From the above description it follows that the hollow element 14 has a valve function. However, if required, the device may have an additional valve 13, such as an umbrella valve, which is shown in FIG.

Figure 9 shows a seventh alternative. According to such an alternative embodiment, another type of hollow element is used, namely the hollow dome-shaped element 17, which is open from below. As air rises in the water, there is no risk that air leaves the hollow element 17, despite the presence of an open bottom.

Although the alternatives described above are different from each other, there are two important facts that are common, namely the fact that there is a means to prevent the backflow of water, and the fact that there is a means to carry out a heat-insulating function in a place located between the tank a storage device 2 and a boiler 3. Such means can be implemented on the basis of a single structure, such as a thin, flexible pipe element 9, which is placed inside a section of the pipeline 4, as shown in figure 2, or the hollow element 14, 17, which is shown in FIGS. 8 and 9. It is also possible that a structure comprising several elements is used, such as a combination of a rigid pipe element 9 and an umbrella valve 13, as shown in FIG. In any case, a very practical method for the implementation of the heat-insulating function is proposed, associated with the use of a certain amount of air in the place of separation of water from the storage tank from the water from the boiler.

Only by allowing water to flow from the storage tank 2 to the boiler 3 and preventing backflow, and providing a heat-insulating function, is it achieved that the water that is inside the storage tank 2 remains at ambient temperature, while the temperature is relatively high the water that is inside the boiler 3, is practically independent of the much lower temperature of the water that is inside the storage tank 2.

One skilled in the art will appreciate that the scope of the present invention is not limited to the examples discussed above, and that some improvements and modifications are possible without departing from the scope of the present invention as defined in the appended claims. Although the present invention is illustrated and described in detail in the figures and description, such illustrations and description should be considered only illustrative or typical, and not restrictive. The present invention is not limited to the described embodiments of the invention.

From the study of the figures, description and appended claims, a person skilled in the art in the practical implementation of the claimed invention can understand and make changes to the described embodiments of the invention. In the claims, the word “comprising” does not exclude other stages or elements, and the singular nouns do not exclude the plural. The fact that certain measures are listed in the mutually different dependent claims does not mean that a combination of such measures cannot be applied to gain an advantage. Any reference position in the claims should not be interpreted as limiting the scope of the present invention.

It is not necessary that the device 1 according to the present invention contains a storage tank 2 for holding cold water and supplying cold water at the request of the user. In the General case, the device 1 according to the present invention contains a system for containing liquid outside the boiler 3, where such a system may also have a shape similar to, for example, a piping system. To illustrate such a statement, Fig. 10 schematically shows an embodiment of a device 1 according to the present invention, which does not contain a storage tank 2, but only contains cold water pipelines 18 that are in fluid communication with the boiler 3.

For completeness of description, it should be noted that the present invention is applicable in any situation in which there is a system 2, 18 for cold liquid and a boiler 3, where the system 2, 18 for cold liquid and a boiler 3 communicate with each other by means of a liquid, and where it is required to maintain heating on the boiler side, and maintain cold on the system side for cold liquid. Therefore, the device 1 according to the present invention does not have to be a gravity-based device, but may also contain additional components for achieving the desired fluid supply using the device, in particular a pump. In addition, the present invention is applicable in the field of any type of liquid, where water is just one practical example. As for the boiler 3, it should be noted that such a component of the device 1 according to the present invention can be any suitable type. It is assumed that the design of the boiler 3 with heating means for heating the contents of the boiler 3 is well known and does not need any further explanation here.

The present invention can be summarized as follows. The device 1 comprises a boiler 3 for holding and heating a liquid, such as water, and a system 2, 18 for cold liquid, which is in fluid communication with the boiler 3, and which is intended to contain liquid at a lower temperature than the hot liquid from the boiler 3, i.e., relatively cold liquid. During operation of the device 1, the boiler 3 is activated in such a way that it heats a certain amount of liquid, which comes from the cold liquid system 2, 18. In order to avoid heating the liquid that is inside the system 2, 18 for cold liquid, and cooling the liquid that is inside the boiler 3, under the action of the usual movement of relatively cold liquid and relatively hot liquid in the device 1, measures are taken to prevent the backflow of liquid . Such measures encompass the use of any component located in front of the boiler 3, and in order to avoid heat transfer through such a component, additional measures are taken to insulate in a place located in front of the boiler 3, which may be a place near the said component. A practical way of providing thermal insulation is to provide a space 11 for holding air in a suitable location.

Claims (14)

1. The device (1, 18, 20), containing:
- a boiler (3) for containing and heating a liquid, such as water;
- a system (2, 19) for cold liquid, which is in fluid communication with the boiler (3) and which is designed to contain liquid at a lower temperature than the hot liquid from the boiler (3); and
- means configured to prevent backflow from the boiler (3) into the cold liquid system (2, 19) and to insulate in a place located upstream of the boiler (3),
wherein the means comprises a space (11) for holding air, in which air is held for thermal insulation. 2. The device (1, 18) according to claim 1, containing a pipeline system that interconnects the system (2) for cold liquid and a boiler (3), which contains a pipeline (4) passing between the system (2) for cold liquid and a boiler (3), moreover, the space (11) for holding air is located in the section (8) of the pipeline (4) with a larger cross-sectional area than in the neighboring sections (12, 16). 3. The device (1, 18, 20) according to claim 1, containing means for preventing the filling of the space (11) for holding air with liquid from the side of the cold liquid system (2, 19) in the form of a wall blocking access to the space (11) to hold air. 4. The device (1) according to claim 3, containing a piping system that interconnects the system (2) for cold liquid and a boiler (3), which contains a pipeline (4) passing between the system (2) for cold liquid and the boiler ( 3), and inside the pipeline (4) the tube element (9) is placed, while the cross-sectional area of at least the end section of the pipe element (9), in particular the end section, which is located on the side of the boiler (3), is less than the area the cross section of the pipeline (4) in the place where the end section is the tubular member (9). 5. The device (1) according to claim 4, in which the wall of the pipe element (9) is a thin wall and contains a flexible material. 6. The device (1) according to claim 1, containing a hollow element (14, 17) for containing a heat insulating material. 7. The device (1) according to claim 6, containing a piping system that interconnects the system (2) for cold liquid and a boiler (3), which contains a pipeline (4) passing between the system (2) for cold liquid and the boiler ( 3), while the hollow element (14, 17) is freely placed inside the section (8) of the pipeline (4) with a larger cross-sectional area than the neighboring sections (12, 16), and the cross-sectional area of the hollow element (14, 17) larger than the cross-sectional area of the adjacent sections (12, 16) of the pipeline (4). 8. The device (1) according to claim 6, in which the hollow element (17) has a domed shape with an open side. 9. The device (1) according to claim 6, containing a valve (13) that allows fluid to flow in the direction from the cold fluid system (2, 19) to the boiler (3) and blocks flow in the other direction, the hollow element (14) connected to the valve (13). 10. The device (1) according to claim 1, containing means (15) such as a plurality of thin plates, thin tubes or fibers that pass next to each other with a small space between them, for converting the fluid flow from the system (2, 19) for cold liquid into the boiler (3) into streams of small drops. 11. The device (20) according to claim 1, containing a piping system that interconnects the system (2) for cold liquid and a boiler (3), which contains a pipeline (4) passing between the system (2) for cold liquid and the boiler ( 3), and a tube (5) for removing air, having a relatively small diameter, which is located between the system (2) for cold liquid and the boiler (3), and the space (11) for holding air is in the system (2) for cold liquid while the end section of the tube (5) for air removal passes inside the space properties (11) for holding air. 12. The device (20) according to claim 11, containing two non-return valves (13, 23), and one non-return valve (13) is located inside the pipe (4) and serves to allow fluid to flow through the pipe (4) in the direction from the system (2) for cold liquid to the boiler (3) and block the flow in the other direction, and another check valve (23) is located at the end of the tube (5) to remove air that is inside the system (2) for cold liquid, and serves to allow fluid to flow through the tube (5) to remove air in the direction apart from the boiler (3) to the system (2) for cold liquid and to block the flow in the other direction. 13. The device (1, 18, 20) according to item 12, which is a device based on gravity, in which the movement of fluid occurs only under the influence of gravity, while at least part of the boiler (3) is at a lower level than system (2, 19) for cold liquid. 14. The device (1) according to item 13, comprising a valve (13) that allows fluid to flow in the direction from the cold fluid system (2) to the boiler (3) and blocks flow in the other direction, and a space (11) for holding air in the device (1), while the space (11) for holding air is in place between the valve (13) and the boiler (3).

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