ES2951699T3 - Power distribution system - Google Patents

Abstract

The present invention relates to an energy distribution system (1) for heating/cooling at least part of a space (6) through fluid distribution for the exchange of energy with the space. The system comprises at least a first distributor (10) and at least a second distributor (20), and a tube (30) connected between the first distributor and the second distributor to create a fluid flow path between the distributors and to exchange energy between the heating/cooling fluid flowing through the pipe arranged in the space and the space itself. The invention also relates to a distributor (10, 20) for use in the system and a method of arranging the pipe (30) of the power distribution system (1). (Automatic translation with Google Translate, without legal value)

Description

DESCRIPTION

Power distribution system

Technical field

The present invention relates to an energy distribution system for heating or cooling at least a part of a space. The energy distribution system is at least part of a floor, wall or ceiling or an air ventilation system to heat or cool at least parts of the space.

Background of the technique

Different ways of heating and/or cooling spaces are known using various types of distribution systems or installations by which water and/or air are heated using, for example, electric heaters immersed in water or placed in air flow paths or burners fed with gas or oil or by means of which water and/or air is cooled by heat exchange or similar. Such systems comprise units/devices for subsequently guiding the heated or cooled fluid, for example, water or air, along various routes, commonly various types of piping or ducting, to heating radiators or ceiling or floor heating arrangements or air treatment devices for spaces. These heating and/or cooling systems with heated or cooled fluid transfer heat to the environment and/or colder ambient air or absorb heat from the environment and/or warmer ambient air in said spaces in a controllable manner. The space, as at least a part of a structural unit in the form of a house, normally has its own (domestic) heating and/or cooling system with which at least parts of the space and/or rooms of the structural unit are heated and/or cool in response to energy demand.

Examples of heating systems are central or district heating units that are used to heat a series of heating radiators that directly heat the ambient air or use one or more heat exchangers arranged in a structural unit, such as a residential building, to exchange heat with colder fluid in the building to heat the fluid and therefore heat a space/room or the entire building. Systems of this type are known in which hot water is conducted along heating ducts arranged in a structural part, for example, one or more floors, walls or ceilings. The hot water heats the structural part, which in turn transmits heat to the ambient air. One type of system is known as a floor and/or ceiling heating system, which means a system in which the heating ducts are arranged in a structural part other than the floor, for example in a wall and/or ceiling of the space. room.

An underfloor heating system is usually supplied with hot fluid, such as water, through a central heating unit mentioned above, a district heating system or a domestic heating installation. To provide this hot water, there is a network of tubes or piping of the central heating unit, district heating or domestic heating installation to which at least one distributor is in fluid communication to guide the incoming hot water to the pipes. of heating where the actual heat exchange occurs in an entity, i.e. the space to be heated, and from which entity at least one other distributor receives the return flow of relatively cold water after the heat exchange and conveys it back to the piping network of the central heating unit, district heating or domestic heating installation. The relatively cold water is then reheated and/or mixed with hot water supplied from the central heating system, district heating system or domestic heating installation and returned to the space if heating is demanded. Commonly, prior art systems use about 35°C for heating and about 12°C for cooling.

The current technique of distribution systems in the field of heating, ventilation and/or air conditioning (HVAC industry), such as cooling, heating, collectors and/or energy storage are based on levels of certain settings. These settings, for example, floor heating or radiator heating, are controlled by regulators and the regulators ensure the desired interior temperature in each installation. Distribution systems, such as constant flow soil heating and unregulated processes, have been tested for different purposes and on a smaller scale. Its disadvantages have been too high a flow rate, too low temperatures (biological growth) and complications of lack of adjustment, since balance valves have been used to compensate for variations in flow, pressure and/or temperature, which has been done unsatisfactorily. Examples of distribution systems are described, for example, in EP 1630479 A2 and DE 26 14694 A1. Distributors for controlling distribution are known, for example, from DE 201 11 656 U1 and KR 2009 0029992 A. Distributors are more known in other fields, such as paper making machines or boilers, for example in US 6 083 351 A1 and DE 202009 003191 U1. Other examples of the prior art can be found, for example, in EP 0501 567 A1, GB 350632 A and US 5 707007 A.

Compendium of invention

An object of the present invention is to provide a power distribution system, which is economical and energy efficient in its construction and functionality.

Another object of the present invention is to provide a power distribution system that allows for faster switching/changing of the current heat exchange in response to a new demand for energy supplied or extracted in at least a portion of a space to be heated or cooled. compared to the previous technique.

Another object of the present invention is to provide an energy distribution system that stabilizes the total decrease in pressure in the distributors, achieving a self-regulation/self-adjustment system with self-acting redistribution of heat and/or cold in a space, in principle automatically without need for valves or other regulators in this context. Furthermore, no externally enabled and controlled valves or other regulators are required for the inventive self-acting power distribution of the system according to the invention.

A further object of the present invention is to provide a power distribution system comprising at least one heating/cooling source, which power distribution system itself, i.e., is inherently capable of regulating the indoor climate (as well as any energy storage and any collector) through the heating/cooling source without the need for external controls or regulators. The effects are greater energy efficiency and better temperature gradients (comfort) due to the use of smaller temperature differences in the environment compared to the previous technique. The inventive power distribution system uses about 25°C for heating and about 20°C for cooling compared to prior art systems that use about 35°C for heating and about 12°C for cooling. This means that the invention works in narrower temperature ranges that until now have not been considered realistic and truly useful before the inventors unexpectedly realized this.

Another object of the present invention is to provide an energy distribution system with very low energy loss, so the need for valves in any of its distributors to compensate or balance the variation in pressure and/or temperature and/or is eliminates fluid flow through the system, its piping and any of its distributors.

Still another object of the present invention is to provide a very simple pressure stabilizer, which is adjustably disposed, within at least one distributor, i.e., a manifold, of the power distribution system to ensure the correct flow of fluid to each tube/piping of the system eliminating the need for valves in any of its distributors, not even in any of the inlets and/or outlets of the distributor, to compensate, that is, balance the variation in pressure and/or temperature and/or flow of fluid through the system and any of its distributors and associated components, such as its piping for heat exchange.

Another object of the invention is to provide correspondingly/substantially the same (within the technical field)/the same/equal length of tubing or each tube/tubing of the power distribution system to ensure that pressure losses/drops/decreases are the same. same in each tube that has the same specific length which is between approximately 20 and 40 m or exactly between 20 and 40 m.

Another object of the present invention is to provide a secure fluid/water seal at one or more or each of the inlets and/or outlets of at least one or more or each, that is, all of the distributors of the water distribution system. energy to ensure minimal leakage of liquid/water from it.

An object of the invention is to provide one or more distributors of the power distribution system with as many input/output connections as possible to make regulation in the system as simple, fast and reliable as possible due to a relatively greater size/volume/area between each individual inlet/outlet and the entire distributor compared to the prior art.

Yet another object of the invention is to provide a power distribution system with piping configured to be placed in at least a portion of the space to be heated or cooled, wherein the piping comprises at least 5 - 12 m of piping per m2 of space/area. to heat/cool compared to standardized systems that use around 2 - 4 m/m2, so the inventive system allows the use of a totally higher flow and lower temperature difference and achieves the use of a casing pattern with density/ Variable compactness to vary heat exchange depending on the different energy demands in a space to be heated or cooled. This allows a denser pattern of piping arranged for one part of the space and a less dense pattern of piping arranged for another part of the same space to be used. optionally achieve a heat exchange that adapts to the different energy demands in different parts of the space to be heated or cooled.

Still another object of the present invention is to provide a power distribution system that uses a lower temperature range and temperature difference for heat exchange, that is, about 2-6 K (AT) compared to the prior art systems that use approximately 10-15 K (AT), achieving a very interesting energy distribution system for use in the future heat pump industry and low energy buildings.

According to the present invention, the above objects are achieved by an energy distribution system for heating or cooling a space, at least partially, by means of fluid distribution for heat exchange between the distributed fluid and at least a part of the space. , comprising at least a first distributor comprising a main inlet adapted to receive heating or cooling fluid by means of a fluid inlet for the incoming flow of fluid, at least a second distributor comprising a main outlet adapted to discharge fluid from heating or cooling by means of a fluid return outlet for the outflow of fluid, and tubing connected between the outlets of the first distributor and the inlets of the second distributor to create a fluid flow path between the distributors to allow exchange of heat between the heating or cooling fluid flowing through the tubing disposed in the space and the space, wherein the tubing comprises tubes of substantially the same length, and wherein at least one distributor comprises at least one rail disposed within the distributor , the rail being configured to compensate for the variable pressure in the flow of fluid through the distributor by decreasing its interior volume in the direction of fluid flow from its first inlet or outlet to its last inlet or outlet in relation to the size of each inlet or outlet, and wherein the rail is at least partially movable within the distributor by means of a mechanism in a direction towards or from the inlets or outlets of the distributor to decrease the volume of internal distributor in response to the pressure that varies from the first entry or exit to the last entry or exit of the distributor.

According to the present invention, the above objectives are achieved by a power distribution system comprising at least a first distributor comprising an inlet adapted to receive heating or cooling fluid by means of a fluid inlet for the incoming flow of fluid, at least a second distributor comprising an outlet adapted to discharge heating or cooling fluid through a fluid return outlet for the fluid outlet, and tubes connecting the outlets of the first distributor and the inlets of the second distributor to create a fluid flow path between the distributors to allow energy exchange between the heating/cooling fluid flowing through the tube arranged in at least a portion of the space, wherein the tubing comprises tubes of corresponding or substantially the same length or equal.

In one embodiment, the casing comprises at least 5 to 12 m or 6 to 12 m of casing, preferably at least 6 to 9 m of casing, more preferably 6 to 8 m of casing, or most preferably 6, 5 to 7.5 m of piping per m2 of at least the part of the space to be heated or cooled. The tubing length ranges per m2 are applicable for an entire space or more than one space if one space is a room and another space is another room. That the lengths are the same for each tube is equally applicable in larger spaces that have more than one zone for heating or cooling, for example, one zone with a set of distributors and piping and at least one other zone with another set of distributors and piping. .

In another embodiment, the casing comprises at least one or more tubes having an internal diameter of less than 10 mm; preferably less than 7 to 9 mm; more preferably less than 6 to 7 mm; or most preferably less than or approximately or equal to 5 to 6 mm or 4 to 5 mm or 3 to 4 mm or 4 mm. Optionally, each casing tube is within any of the above inner diameter ranges or has the above inner diameter, preferably 5 mm. Alternatively, each casing tube is most preferably less than 6 mm or about or equal to 5 to 6 mm, 4 to 5 mm, 3 to 4 mm or 4 mm, or preferably has an inner diameter of about 5 mm.

In one embodiment, the casing comprises at least one or more tubes having an internal diameter greater than 2 or 3 mm; preferably greater than 4 mm; or more preferably greater than 4.5 mm; or more preferably about 5 mm or greater than about 5 mm, but not necessarily much greater than 5.5 to 6 or 7 mm. Optionally, each casing tube is within any of the above inner diameter ranges or has any of the above inner diameters.

According to the invention, the rail can be moved at least partially within the distributor by means of a mechanism in a direction towards or away from the inlets or outlets of the distributor to decrease the volume of interior distributor in response to the pressure varying from the first inlet. /output to the last input/output of the distributor. This mechanism may be adjustable manually or by means of predisposition/power, such as an electric motor or a spring or the like, optionally by wireless control, such as Bluetooth® used by a user to control the electric motor. According to one embodiment, The rail can be moved linearly within the manifold to decrease the interior manifold volume as the rail moves toward the inlets/outlets of the manifold. According to yet another embodiment, each distributor of the system comprises at least one pressure compensation rail.

In another embodiment, the casing comprises tubes of substantially the same length or the same length or the same length or the same length between approximately 20 and 40 m.

In yet another embodiment, the space is a residential building, a boat, or a swimming pool. Optionally, one or more or each rail of the distributor is formed with a straight/linear extension/shape or a bent or curved shape or comprises a combination of said shapes and/or comprises a shape with a variable curve and/or curve and/or is wedge shaped with any of these shapes or a combination of these shapes creating an angled inner wall of the distributor through which the fluid flows and/or the rail is adjustable/movable so that it is configured to be arranged in different positions creating angles and/or variable shapes/sizes of the internal volume of the distributor through which the fluid flows.

According to a further embodiment of the power distribution system as above, one or more but one and the same distributor comprises at least two rows of inputs or outputs. Therefore, one or more inventive distributors are usable in the system and a single distributor comprises at least two or more rows of inputs and/or outputs. The rows and/or inputs/outputs of the distributor do not have to be exactly aligned or extend exactly parallel to each other.

The advantages/effects of the previous solutions are, for example, the following: valves are eliminated in the distributor(s) of the system, reducing the number of components that increase pressure loss. As valves are removed from the manifold(s) in the system, one or more valveless manifolds are created.

As the inventive power distribution system can use the same length for each tube/tube loop between approximately 20 and 40 m (within the tolerances of this technical field), a stabilization of the total pressure decrease/drop in its distributors, in combination with other inventive features, which achieve a self-regulating/self-adjusting effect. This same length of tubing in the inventive energy distribution system provides the self-regulating/self-adjusting effect corresponding to an automatic or self-acting functionality with respect to the regulation and redistribution of heat and/or cold within a space for climate control thereof. , for example in terms of temperature. The resulting effect is that the power distribution system of the invention is dynamically stabilized in a self-acting manner, in principle automatically, without the need for external control, that is, the system is provided with inherent self-control, especially when very small differences are used. Of temperature. This allows the surrounding thermal layer/storage (e.g. concrete and other types of screeds) to be used more effectively than in prior art systems. This makes it possible to use a higher temperature sensitivity, that is, instead of using a temperature sensitivity with an accuracy of about 1 °C as traditionally, that is, in prior art systems, the inventive system can use a temperature sensitivity with an accuracy of less than 0.1°C by using the same length of tubing as explained above and below. This, in combination with the correct dimensions and pressures such as up and down, gives a uniqueness in the self-regulating distribution of pressure and temperature, the same length of the tube loops being between 20 and 40 m as up and down and the low temperatures obtained .

The advantageous functionality is applicable for both heating and cooling a space using the energy distribution system of the invention. This means that it is possible to use a low/lower temperature for heating, i.e. less than 28°C (≤ 28°C), preferably about or less than about 25°C, in the supply line/piping/tube to distributors compared to the prior art. This means that it is possible to use a high/higher temperature for cooling, i.e. greater than 19°C (> 19°C), preferably about or more than about 20°C, in the supply line/tubing to the distributors. compared to the previous technique. The resulting effect of a high/higher fluid temperature in the supply line/piping for cooling and a low/lower fluid temperature in the supply line/tubing for heating is that the power distribution system of the invention In a self-acting manner, that is, automatically without the use of external control or regulation, it has the ability to take advantage of overtemperatures in the environment(s) in a continuous and dynamic manner. As an example, solar radiation incident on a ground in which the inventive energy distribution system is installed, the ground of which is only heated just above 30 ° C, and its generated heat has the ability to be transmitted in a downward direction and be redistributed in the remaining part or surface/volume of the soil (or where the tube loops are placed) due to the same length in each tube of 20 - 40 m and the same pressure in the tube loops.

Another advantage of the inventive power distribution system is that heat pumps and refrigeration machines increase their efficiency by means of this inventive principle above and below the efficiency commonly/traditionally achieved in the prior art in terms of coefficient of performance. (COP) from 4 to more or more than 6 (> 6) for the invention.

Additional advantages through the functionality achieved using the same length of tube loops of 20 to 40 m are that large pressure drops/decreases are coped with by using a 5 mm inner diameter for each tube and that the total rotation rate regarding the energy exchanged in an area/space is approximately 120 times per hour while a traditional and prior art system has a rotation rate of approximately 12 times per hour. Therefore, more energy is exchanged per m2 as there are also more tube loops per m2, thus achieving a higher rotation rate compared to prior art systems.

By using the corresponding and/or equal and/or the same length for the tubing of the inventive system, i.e., 10 to 50 m or more preferably 20 to 40 m, an equal/compensated/corresponding pressure is enabled in the tubing for energy exchange, that is, the same/equal pressure is achieved in the tubing of the inventive system. Therefore, equal/compensated/corresponding pressure is achieved in the casing tubes for energy exchange, i.e., equal/same pressure is achieved in each casing tube in the system.

A more efficient fluid flow is allowed, that is, the complete flow of fluid through the inventive system depending on the size, dimension and/or diameter (inner and/or outer diameter) of the tubing and each inlet and/or outlet individual of each distributor is smaller in relation to the prior art.

By using one or more inner rails in the distributor, less fluid pressure loss/variation is generated from a first inlet and/or outlet to another inlet and/or outlet to the last inlet/outlet in the direction of fluid flow. through the distributor. Therefore, optimal pressure and fluid distribution within the distributor is achieved. The rail is adjustable/movable so that it is configured to be arranged in different positions and/or angles. It is easy to vary its angle and the internal volume of the distributor in the correct and optimal positions where fluid flows to facilitate optimal pressure and fluid distribution even further depending on the need of the system application. This is further enhanced by providing the distributor with the mechanism for adjustment of the position and/or angle of the inner rail.

A more efficient fluid flow, that is, the complete flow of fluid through the inventive system comprising at least one or more inventive distributors or each distributor is an inventive one is enabled depending on the size, dimension and/or diameter (diameter interior and/or exterior) of the tubing and each individual inlet and/or outlet of the/each distributor is smaller in relation to the prior art.

A greater interior volume of at least one or each distributor is achieved in relation to the size, dimension and/or diameter of each individual inlet and/or outlet of the/each distributor, since each inlet/outlet of/of each distributor of the invention is minor in relation to the state of the art. This allows a greater number of inputs and/or outputs to be provided in the distributor, that is, a greater density of inputs/outputs is achieved in the inventive distributor compared to the prior art.

By having at least one or more distributors with a smaller size, dimension and/or diameter of each of its individual entrances and/or exits, a greater interior volume of at least one/each distributor is achieved in relation to its entrances and/or exits. individual and a lower pressure loss/variation is generated from a first inlet and/or outlet to another inlet and/or outlet to the last inlet/outlet, that is, step by step, in the direction of fluid flow through the /each distributor, so less passage and energy loss is achieved between each inlet/outlet of each distributor in the direction of fluid flow and the fluid flow is more evenly distributed between each inlet/outlet of each distributor and it is prevented from flowing in the "easiest" way in this context.

By having at least one or more or all the distributors with a smaller size, dimension and/or diameter of each of their individual entrances and/or exits, a greater interior volume of at least one/each distributor is achieved in relation to its entrances and /or individual outlets, whereby an equal or compensated or corresponding fluid pressure and/or pressure variation and/or pressure loss is generated through the distributor. Therefore, a self-regulating capacity of the energy exchange is achieved between at least part of a space to be heated and/or cooled and the piping with hot/cold fluid of the system. This, together with the at least one valveless distributor, generates an equal and compensated fluid pressure, pressure variation and pressure loss through the at least one distributor and the system piping, and creates a self-regulating exchange capability. of energy between the space to be heated/cooled and the system piping.

By using substantially the same or exactly the same length for the tubing of the inventive system, faster fluid flow through the system is achieved.

By using smaller size casing in the inventive power distribution system, such as a smaller diameter, that is, a smaller inner and/or outer diameter of the casing tubes of the system, compared to the prior art, a faster flow of fluid through the system is used, and a faster changeover between variable/different power demands and a faster response to variation in power demands of the system is achieved. a space to heat/cool. The size chosen, that is, the smallest tube diameter used in the invention, depends on the tube thickness, the type of tubes and the tube material.

The use of a faster fluid flow through the inventive system with or without an inventive distributor allows the use of a lower fluid temperature, thereby reducing energy loss in the inventive system. This also means that less insulation is required around/in the inventive system. Additionally, this allows for a faster switch between the current energy exchange and a new one due to a change in energy demand.

The use of a lower fluid temperature in the inventive system achieves lower energy use and lower energy loss due to a lower rate of heat dissipation/radiation.

The use of faster fluid flow through the inventive system achieves greater comfort for residents of a space that is being heated and/or cooled by the use of the inventive system due to faster switching, i.e., response to the variable energy demand by means of the inventive distributor and by the system when it comprises at least one distributor of this type.

By using the same/equal length for the tubing of the inventive system, a higher fluid pressure is achieved through the system.

The use of a higher fluid pressure throughout the system allows the use of a lower fluid temperature and faster fluid flow, thereby reducing energy loss in the inventive system. Therefore, less insulation is required around/inside the system. Therefore, a faster change between the current energy exchange and a new one is allowed due to a change in energy demand according to the inventive system. This also results in lower energy use.

The use of higher fluid pressure through the inventive system achieves greater comfort for the residents of a space that is being heated and/or cooled by the use of the inventive system due to a faster response, that is, a change to the variable energy demand through the distributor and through the system when it includes at least one distributor of this type.

The present invention relates to an energy distribution system for heating or cooling, or both, of at least one or more parts/zones of a space, such as a residential or industrial building, a ship and/or a swimming pool. The power distribution system is used in at least one or more parts/zones of a floor, wall and/or ceiling and/or a space air ventilation system. The present invention relates to one or more distributors adapted for use in said floor, wall, ceiling and/or air ventilation systems, and to said power distribution system with or without at least one of said distributors. In some aspects, the inventive energy distribution system comprising fluid-carrying tubing and at least one inventive distributor is used to heat and/or cool surfaces and/or volumes, for example, by tubing enclosed in at least one or more parts/areas of floors, walls and/or ceilings of the space directly or indirectly to cool and/or heat the space by heating and/or cooling the ventilation air that enters or is extracted from the space by passing the air through the ducting to heat exchange. The features of the inventive distributor can be freely combined with the inventive power distribution system as the distributor is easily added to the inventive power distribution system to enhance its capabilities, however, the inventive power distribution system can be used with other distributors.

Brief description of the drawings

In the following detailed part of the present description, the invention will be explained in more detail with reference to the different aspects shown in the drawings, in which:

Fig. 1 is a perspective representation of at least a portion of a space to be heated or cooled by aspects of the present invention.

Fig. 2 is a sectional view from above of a part of the space of Fig. 1, that is, seen in a direction substantially perpendicular to the plane of a surface of the space, such as the floor of a room, according to aspects of the present invention, the surface of which is shown as a horizontal floor in this Fig. 2 but may also be part of a vertical wall or part of an upper ceiling of the space (not shown).

Fig. 3A is a side view of a part of the space of Fig. 1, where the components on the right of Fig. 1 and the lower left corner of Fig. 2 of the present invention are shown in more detail.

Fig. 3B is a side view of a part of the space of Fig. 1, where the components on the right of Fig. 1 and the lower left corner of Fig. 2 of the present invention are shown in more detail .

Fig. 4A is a side view of at least one component of Figs. 1,2 and 3B partially shown in section to reveal its interior with a mechanism according to one aspect of the present invention.

Fig. 4B is a partial perspective view of at least one component of Figs. 1, 2 and 3B shown partially in section to reveal its interior in an example that does not form part of the invention.

Fig. 5 shows a side view of the component that does not form part of the invention.

Fig. 6 shows side views of the components of Figs. 1, 2, 3A and 3B to better reveal aspects and principles according to the present invention.

Fig. 7A is an end/bottom view of at least one component of Figs. 1 to 6 according to one aspect of the present invention.

Fig. 7B is an end/bottom view of at least one component of Figs. 1 to 6 according to another aspect of the present invention.

Fig. 8 is a perspective view of the end/bottom of the component shown in Figs. 7A and 7B in more detail according to aspects of the present invention.

Fig. 9 is a perspective and partial sectional view of the end/bottom of the component shown in Figs. 7A, ^7b and 8 in more detail to illustrate the location of a component device according to aspects of the present invention.

Detailed description

Figures 1 to 4A and 6 to 9 show a power distribution system 1 and associated components according to the invention. This system 1 is in communication/exchange of energy with at least one part or zone 7 of a space 6 that is to be heated or cooled by means of the inventive system 1 in response to the energy demand of at least one part or zone 7 from space. The type of space 6 has no importance for the invention, the space 6 can be large or small or more than one or be a large space divided into zones 7 or sections or groups or the like. Space 6 is commonly at least part of a residential or industrial building (not shown) or at least part of a ship or at least part of a swimming pool to be heated or cooled. Part 7 of space 6 is at least part of a floor or wall or ceiling (not shown) of space 6 or at least part of an air ventilation system (not shown).

The inventive energy distribution system 1 has the purpose of heating/cooling the space 6 by means of the distribution of fluids for the exchange of energy between the fluid and the structural entities, directly or indirectly, and/or between the fluid and the ambient air directly or indirectly through the structural entity. Therefore, system 1 comprises a heating and/or cooling source or system or unit 8 configured to heat and/or cool fluid, such as water or a mixture of water and substance to prevent the formation of ice if low temperatures are used. of fluid. The heating and/or cooling unit 8 is, for example, a district heating or central heating unit or a domestic heating unit, when used to heat fluid, or a fluid heat pump or a fluid heat pump. air when it cools the fluid. The type of heating/cooling unit 8 is not of great importance in relation to the invention, its purpose is to supply hotter or colder fluid at least to the part/zone 7 of the space 6 for heat exchange therewith and receive hotter or colder fluid from the zone/part 7 of space 6 after heat exchange and to heat or cool the fluid returning from the space, in response to the energy demand of space 6, and to supply fluid, either be it colder or hotter, back to space if demanded. The essence of the heating/cooling unit 8 is to supply heated or cooled fluid within a lower temperature range and at a higher pressure range and/or higher flow rate, for example, water/fluid flow limits reaching 0.8 to 1.4 l/min of each tubing tube of the inventive system has a denser tube pattern, that is, the invention uses more tubing per unit area than in the prior art, which said tubes update the Heat exchange with the space 6 to be heated or cooled means that more fluid per unit of time passes through the space during heat exchange according to the invention compared to the prior art. As an example, at least 5 m of piping is used for the same zone/space/area where approximately 2 m of piping is used in the prior art. Therefore, the difference with a used fluid flow of 1.2 l/min is for the invention = 5 ■ 1.2 ■ 60 = 360 l/h (1.2 l/min and 5 m tubing) versus a 2 ■ 0.85 ■ 60 = 102 l/h for the previous technique (0.85 l/min and 2 m piping). This is commonly translated into a total fluid flow per m2, as follows, i.e. 0.8 - 1.4 l/min translates to 10 - 20 l/(m2-h) for the invention, while the technique above uses 4-6 l/(m2- h). This distinctive difference between the invention and the prior art in combination with The use of a low/lower temperature range of 2 to 6 K (AT) according to the invention compared to prior art systems using approximately 10-15 K (AT) has the effect that more than 100 times the rotation per hour by using the inventive power distribution system compared to less than 20 rotations per hour for prior art systems.

As shown in Figures 1 to 9, the power distribution system 1 comprises at least one or more distributors 10, 20. A first distributor 10 comprises at least one main inlet 12 for receiving heated and/or cooled fluid through a fluid inlet 4 for the incoming flow of fluid 2 downstream of/from a heating or cooling system/unit 8. The warm/heated or cold/cooled fluid is led from the first distributor further into the casing or tubes or conduits 30 of system 1. The piping 30 allows the fluid to exchange heat with at least a part 7 of the space 6. The power distribution system 1 comprises at least a second distributor 20. The second distributor 20 comprises a main outlet 22 for discharging the fluid heated or cooled through a fluid return outlet 5 for the outflow of fluid 3 after heat exchange in the space 6 and back to the heating/cooling unit 8. The system 1 comprises at least one pump 9 to push the fluid through the system and its piping 30 and distributors 10, 20 and heating/cooling 8. System 1 comprises other components, for example, different types of valves, such as shut-off valves, and/or more of a pump 9, as applicable, and pipe/tubing ducts and couplings and regulators, such as thermostats 70 and the like, that are enabled by electrical means to be functional and controlled by at least one control unit, however, such components and power distribution control systems are well known to those skilled in the art and will not be explained in detail. One or more thermostats are applicable, such as an indoor thermostat 70 in the space on the left in Fig. 1 and/or an outdoor thermostat 70 on the right in Fig. 1. One or more or all of the thermostats 70 are in connection operative with the heating/cooling source 8 and any control unit (not shown) via wiring or wireless communication to enable the functionality of the power distribution system 1.

According to system 1 shown in figs. 3 to 9, the tubing 30 is removably connected between the outlets 13, 13', X, X' of the first distributor 10 and the inlets 23, 23', communication fluid between distributors to allow the exchange of energy between the cold/hot fluid flowing through the tubing and the space 6. According to the invention, the tubing 30 comprises tubes of corresponding length L (see Fig. 6).

According to another aspect of the invention, the casing 30 comprises tubes of equal length L (see Fig. 6), and in yet another aspect of the invention, the casing 30 comprises tubes having substantially the same length L (see Fig. 6). According to a further aspect of the invention, the tubing 30 comprises tubes having the same length L (see Fig. 6). According to one aspect of the invention, the tubing 30 comprises tubes of which all tubes have a corresponding length L (see Fig. 6) or each tube has a length L corresponding to the other tubes. According to one aspect of the invention, the casing 30 comprises tubes in which all the tubes have equal length L (see Fig. 6) or each tube has the same length L. According to another aspect of the invention, the casing 30 comprises tubes wherein all of the tubes have substantially the same length L or the same length, that is, each tube has substantially the same length or the same length L as the other tubes. The top and bottom length L of each tube is between approximately 20 and 40 m or between exactly 20 and 40 m. Each pipe loop has exactly the same length L in system 1. Therefore, each pipe length/loop is either 20 m or 40 m in each system 1 or has the same length L anywhere between those lengths in each system 1 or each zone 7 of system(s) 1 and/or space(s) 6 to be heated/cooled. Each tube in each distributor 10, 20 has the same length L as the other tubes in the entire casing 30. In some aspects, a zone of space 6 comprises two or more distributors depending on the need for heat/cooling in the space and/or or the area of space to be heated or cooled. If, for example, four or more distributors 10, 20 are used for space 6, each pair of distributors 10, 20 is arranged or operated in a separate zone, each or both pairs of distributors 10, 20 are arranged or operated in one and the same area of space. If at least one other pair of distributors 10, 20 is used, each additional pair of distributors is arranged or works in a zone separate from itself or cooperates in a common zone with any of the other pairs or cooperates with both pairs or with more than two pairs or with all other pairs of distributors 10, 20 of one or more zones and/or spaces 6. A zone of space 6 comprises at least one pair of distributors 10, 20 or more than one pair. The power system 1 comprises a heating and/or cooling source or system or unit 8 configured to heat and/or cool fluid, such as water or a mixture of water and substance to prevent ice formation if low fluid temperatures are used. . The heating and/or cooling unit 8 is, for example, a district heating or central heating unit or a domestic heating unit, when used to heat fluid, or a fluid heat pump or a fluid heat pump. air or an air conditioning unit. The type of heating/cooling unit 8 is in principle not of great importance in relation to the invention, its purpose is to supply low temperature fluid at least to part 7 of space 6 for heat exchange therewith and receiving fluid hotter or colder part of the space after heat exchange and to heat or cool the fluid that is returned, in response to the energy demand of the space 6, and supply fluid back to the space if demanded.

For simplicity, the following description of the inventive system 1 will focus on the heating and/or cooling of at least part of a floor or one or more floors of space 6, but is equally applicable if the heating and/or cooling of at least part of a wall or one or more walls of the space 6 and/or if heating and/or cooling of at least part of a ceiling or one or more ceilings of the space is to be carried out. The fluid used for this is preferably water at low temperature. As seen in figs. 1 to 6, heated or cooled water is supplied from the heating and/or cooling unit 8 by means of at least one water pump 9 through conduits as fluid inflow 2 to the first distributor 10 and is guided through this first distributor 10 through its inlet 12 and the fluid inlet 4 and its interior volume to its outlets 13, 13', floor 7 of space 6 which is a residential building (see fig. 1). Then, the "hot" or "cold" water, but still at a low temperature, from the pipe 30 arranged in the floor exchanges heat with the floor 7. The floor either radiates heat and heats the ambient air, if space 6 is due heat, or absorbs heat and cools the ambient/surround air, if the space 6 is to be cooled, so that the warmer or colder water flows further and towards the second distributor 20 through its inlets 23, 23 ^, X" , X" after heat exchange. The water is then conducted through the interior volume of the distributor 20 and exits through its outlet 22 and return outlet 5 as an outflow of fluid 3 through ducts back to the heating/cooling unit 8. The tubes 30 are arranged as fluid transport channels arranged for, for example, a concrete floor or the floor covering provided thereon or fixed to an intermediate or top layer of the floor 7 depending on the configuration of the floor.

The power distribution system 1 comprises one or more first and/or second fluid distributors 10, 20. The power distribution system 1 is characterized in that the tubing 30 comprises tubes of substantially the same or equal or exactly the same length L which is between approximately 20 and 40 m. The length L of the piping 30 is at least 5 to 12 m or 6 to 12 m of piping 30 per m2 of at least part 7 of the space 6 or the entire space to be heated and/or cooled. The length L of the piping 30 is preferably at least 6 to 9 m of piping per m2 of at least part 7 of the space 6 or the entire space to be heated and/or cooled. The length L of the piping 30 is more preferably at least 6 to 8 m of piping per m2 of at least part 7 of the space 6 or the entire space to be heated and/or cooled. The length L of the piping 30 is most preferably 6.5 to 7.5 m of piping per m2 of at least part 7 of the space 6 or the entire space to be heated and/or cooled.

One or more or each distributor 10, 20 comprises at least one or more inner rails 11, 21 to compensate for the variable pressure in the fluid flow through the distributor by allowing to alter, that is, decrease the volume of inner distributor in the direction of the fluid flow from its first inlet and/or outlet 12, 13, 23 to its last inlet and/or outlet 22, X, X'. Pressure compensation is achieved because the greater volume of interior distributor relative to the size of each inlet/outlet is reduced along the direction of flow passing through it. The rail 11, 21 is at least partially movable within its associated distributor 10, 20 by means of a mechanism 60 in a direction towards or from the inlets or outlets 13, 13', 23, 23', X, X', X ", In an aspect that is not part of the invention, the rail 11,21 is fixedly arranged within one or more distributors 10, 20 to decrease its internal volume in response to the variation in fluid pressure from its first inlet and/or or exit 12, 13, 23 to its last entry/exit 22, X, X'. Optionally, the system 1 comprises one or more distributors 10, 20 with a fixedly attached rail 11, 21 in an aspect that does not form part of the invention and/or one or more distributors 10, 20 with a movable/adjustable rail 11, 21 or comprises distributors 10, 20 of which each distributor comprises at least one pressure compensating rail 11, 21 which may be fixed in an aspect not forming part of the invention or adjustable.

One or more of the distributors 10, 20 comprises at least two or more rows 14, 15, 24, 25 of inputs or outputs 13, 13', 23, 23', /or one and the same distributor 10, 20 comprises at least two or more rows 14, 15, 24, 25 of inputs or outputs 13, 13', 23, 23', or more or each distributor 10, 20, the inputs and/or outputs 13, 13', 23, 23', 25 move at a distance D, D' from the inputs and/or outputs of another row of inputs and/or outputs in a direction substantially perpendicular and/or parallel to the longitudinal direction of the associated distributor. In one or more or each distributor 10, 20, each input or output 13, 13', 23, 23', displaces a distance D, D' corresponding to or equal to each other along each row. In one or more or each distributor 10, 20, the inputs or outputs 13, 13', 23, 23', , 25 are arranged so that a zigzag and/or staggered pattern of the entrances/exits is achieved along the distributor. In one or more or each distributor 10, 20, the at least two inlet or outlet rows 14, 24, 15, 25 move a distance D'''' from each other in a direction substantially perpendicular to the longitudinal direction of the distributor associated. In one or more or each distributor 10, 20, its connection part 100, 200 comprises at least 2 to 8 inputs or outputs 13, 13', 23, 23', X, X', X", X" by 50 mm length of the distributor 10, 20. In one or more or each distributor 10, 20, its connection part 100, 200 preferably comprises at least 3 to 7 inlets or outlets per 50 mm length of the distributor 10, 20. In one or more or each distributor 10, 20, its connection part 100, 200 more preferably comprising at least 3 to 6 inlets or outlets per 50 mm length of the distributor 10 20 In one or more or each distributor 10, 20, its connection part 100, 200 most preferably comprises 3 to 5 or 3 to 4 inlets or outlets per 50 mm length of the distributor 10, 20. The inlets or outlets 13, 13' ^, 23, 23 ^, X, X', X", The inlets/outlets 13, 13', 23, 23', X, X', X", of the length of L ^d and/or the width of the distributor.

The distances D or D' in figs. 7A and 7B between inlets or outlets 13, 13', 23, 23', different distances, that is, distance D is different from distance D' or corresponds to or is the same/same distance. The distance D" from either end of the distributor 10, 20 to the first or last inlet/outlet 13, 13', 23, 23', X, X', X", X" along the length of the distributor is established with the corresponding/same/same distance or a different distance than distances D and D' (distance D" is only shown measured from one end of the distributor, but can be measured from either end or both ends of the distributor). The arrangement of the distances D, D', D” along the distributor 10, 20 is uniform or regular or equally divided to achieve optimal distribution of the internal pressure. The distances are also dimensioned, that is, they adapt to the length L ^d of the distributor. The distances D" or D"" in Figs. 7A and 7B between inlets or outlets 13, 13', 23, 23', X, X', X", X" along the width of the distributor 10, 20 They are arranged with the same or corresponding or equal distance or with different distances, that is, the distance D" is different from the distance D"" or corresponds or is the same/same distance. The length L ^d of the distributor 10, 20 is expressed in the following equation L ^d = 2 ■ D" I x ■ (D or D')/2 where x is the number of inlets or outlets 13, 13', 23, 23 ', X, X', " and/or D'''' is between 10 - 25 mm or preferably 12 - 20 mm. The above distances depend on the available space and the correct pressure distribution, for example, the distributors 10, 20 must fit in a standard closet.

One or more or each distributor 10, 20 comprises inside the rail 11,21 fixedly arranged in an aspect that is not part of the invention and/or comprises inside the rail as at least partially movable by means of the mechanism 60 ( see Fig. 4A) in relation to the inputs and/or outputs 13, 13', 23, 23', is an internal division that adjusts liquid pressure for optimal pressure distribution through the manifold and tubing/tube connectors. This rail in combination with the distance arrangement D, D', D" and/or D" and/or D"" along the length and/or width of the distributor 10, 20 further improves optimal pressure distribution.

In figs. 1 and 2 show examples of tubing arrangement patterns 30 according to the invention. Any of these piping arrangement patterns 30 can be combined with any other piping pattern arranged according to the invention if, for example, there are two spaces 6 and they are to be heated and/or cooled, such as two rooms next to each other. Then more than two first and second distributors 10, 20 would be used and additional equipment would be added in proportion to this, making the power distribution system 1 in principle, or at least functionally, and in number of associated components almost or two times larger. If more than two rooms 6 comprising one or more zones are to be heated and/or cooled, the number of distributors and associated equipment is multiplied in one aspect proportionally to the number of spaces/rooms 6 and zones.

Another aspect that is not part of the invention refers to a method of placing piping 30 of the energy distribution system 1 to heat and/or cool at least a part 7 of the space 6 or the entire space if applicable. The method is adapted to be used, for example, in a residential building, a boat or a swimming pool according to any of the above aspects. The method comprises placing the tubing 30 with a variable distance, such as a distance between the C/C centers of the tubes (see Figs. 1 and 2). The method comprises placing the casing 30 in different patterns as required for the different power demands of the space 6, optionally in combination with a variable C/C distance between each tube of the casing (see Figs. 1 and 2). The method comprises placing the casing 30 in different patterns as required for the different power demands of the space 6, optionally, that is, if required, in combination with a variable C/C distance between each tube of the casing and/or along along each individual or separate path or winding of each individual tube of the casing 30 (see Figs. 1 and 2). This C/C distance is less in areas of the space that have a higher energy demand, such as in a W window or door with or without a W window, creating a denser ducting pattern in that area/those areas. This C/C distance is greater in areas of the space 6 that have a lower energy demand, which creates a less dense casing pattern 30 in those areas, such as on an interior wall that does not directly connect to the exterior or a part coldest of a building. The energy or power demand of each m2 depends or is due to the center-to-center distance (C/C) between tubes and between the winding(s) of the same piping tube 30. Referring to figs. 1 and 2, the casing closest to window W has a C/C of 50 - 100 mm, while the casing in the rest of the floor/part 7 of the space has a C/C of 100 - 300 mm. This provides a mixed exposure/placement of pipe or casing 30 compared to the prior art where the casing is arranged with the same center-to-center (C/C) distance between pipes. The Inventive placement patterns of the invention create a pressure balance in the power distribution system 1 and allow the system to self-regulate.

The method according to the above comprises connecting a first end 31 of each tube of the casing 30 to an associated outlet 13, 13', X, X" of a first distributor 10. The method comprises adapting (for example, cutting) the length of each individual tube of the casing 30 in a length L corresponding to or substantially the same or the same length L as the other tubes, that is, at L = about 20 to 40 m or any intermediate length. This adaptation of the tube length is performed before connecting the first end 31 of each tube of the tubing 30 to the associated outlet 13, 13', X, X" of the first distributor 10 or after. This tube length is adjusted so that the tubing 30 can be placed in/on/above a floor, wall or ceiling in a pattern with a different arrangement for each of the tubes in at least a part 7 of the space 6 to be heated. and/or cool. The method comprises placing each casing tube 30 in the pattern adapted to the required heating/cooling demand of the space. The method comprises connecting the second end 32 of each tubing tube 30, Y to an associated inlet 23, 23 ^, X', X" of a second distributor 20 before or after placement.

The method for placing the tubing 30, Y of system 1 according to the previous aspects comprises connecting the first end 31 of a first tube of the tubing 30 in a separable manner to the first outlet 13, 13' of the first distributor 10. The method comprises adapting ( for example, cutting) the length L of the first casing tube to a length L corresponding to or substantially the same or equal to or of the same length L as the other tubes before or after connecting the first end 31 of the first casing tube 30 is separable to the first outlet 13, 13' of the first distributor, so that the length L is 20 to 40 m depending on the shape, size and energy demand of the space. The length of the tube L is prepared to be placed on/above/on a floor, wall or ceiling in a first pattern in space 6. The method comprises placing the first casing tube 30 in the first pattern adapted to the required energy demand of the space. The method comprises releasably connecting the second end 32 of the first tube of the casing 30 to the first inlet 23, 23' of the second distributor 20 before or after its placement. The method comprises releasably connecting a first end 31 of a next tube Y of the tubing 30 to a next outlet length L that corresponds to or is substantially the same as or is equal to the length L of the first arranged tube of the casing before or after connecting the first end 31 of the next tube Y of the casing in a separable manner to the next outlet X, X" of the first distributor. The length of the L tube is adjusted to be placed on/on/above a floor, wall or ceiling in a following pattern in space. The method comprises placing the next tube Y of casing 30 in the following pattern adapted to the required energy demand of the space. The method comprises connecting the second end 32 of the next tube Y of the casing 3o in a separable manner to another inlet X', the previous stages until all the Y tubes of the casing 30 are arranged and connected to the distributors 10, 20.

According to the inventive system 1 and its method of placement and inherent advantages, such as the use of tubing 30 that does not have tubes of different lengths, valves are eliminated in at least one or each distributor 10, 20 which means that the distributor does not It has valves. An effect of the inventive system 1 and its method is that each of the distributors 10, 20 is made without valves. The Figs. 5 and 6 show the inventive principle where two distributors 10, 20 are arranged so that the tubes of the casing 30 are more clearly displayed with their lengths L that correspond or are substantially the same or the same or the same if the tubes were connected to the distributors before being arranged/extended at least partially in the space 6 shown in Figs. 1 and 2.

A same distributor 10, 20 in the inventive system 1 comprises at least two rows of inlets and/or outlets 13, 23, X, X' aligned substantially in parallel along the length of the distributor. The rail/internal division/pressure rail 11, 21 of the distributor 10, 20 is movable so that the internal volume of its associated distributor can be adjusted.

The rail 11, 21 may be movably attached within the distributor 10, 20 by means of a hinge, or pivoted at one end so that its adjustability/mobility is realized by changing its angle by rotating the rail about a axis of rotation, its angle a being variable with respect to the longitudinal direction of the distributor. The right end of the rail closest to the main entrance 12 of the distributor in fig. 4A is the fixed point around which the rail is adapted to move/rotate. This angle a is between 5° and 40° or is variable between 5° and 40° in relation to the longitudinal direction of the distributor 10, 20 or the horizontal (see Figs.

4A and 6). The angle of the rail allows it to function as an anvil-like wall along which the approaching fluid moves, so that the pressure variation along the length of the distributor is compensated, that is, balanced . The rail 11, 21 is arranged so that the interior volume of the first distributor 10 decreases from its inlet 12 or first outlet 13, 13' to its last outlet X, X' for the first distributor 10. Optionally, a rail is arranged 11, 21 so that the interior volume of the second distributor 20 decreases from its first inlet 23, 23' to the outlet 22 and its last inlet X'', X'''. Each distributor optionally comprises one or more rails 11 21 or only one distributor comprises one or more rails. If more than two distributors 10, 20 are used in system 1, as an option, only one, only two or more distributors can be equipped with one or more pressure equalization rails 11,21. The angle a for the rail 11, 21 is measured in relation to or from the top of the distributor in front of its inlets and/or outlets 13, 13', 23, 23', X, X', X", X" (see Figs. 3B, 4A, 4B and 6). The rail 11, 21 is a linear element or linearly straight (see Figs. 4A and 6) or bent or curved with a certain constant radius R or bent/curved with a variable radius R from a larger radius at the entrance 12, 22 from the first or second distributor to a smaller radius at the last exit X, X' of the first distributor/last entrance X", X" of the second distributor (see Figs. 3B and 4A).

The rail 11, 21 can be joined by means of linear guides at each end, which guides are connected to the inside of the distributor 10, 20 or to a part thereof, so that the adjustability of the rail, that is, the mobility of the rail, is realized. moving the rail linearly along the guides in a direction within the distributor that is substantially perpendicular or substantially parallel to the length, that is, the longitudinal extension of the distributor towards or from the inlets/outlets of the distributor.

The rail 11, 21 can be fixedly integrated inside at least one, two or more distributors 10, 20 in an aspect that does not form part of the invention. The rail 11, 21 in some aspects can move linearly within the distributor 10, 20, so the interior distributor volume decreases when the rail moves towards the inputs / outputs 13, 13', 23, 23', X, X', X", X" along and/or perpendicular to the length of the distributor, that is, to its longitudinal axis. Therefore, the rail 11, 21 is configured to move axially and/or radially relative to the longitudinal extension of any distributor 10, 20. Regardless of whether a fixed or adjustable/movable rail 11, 21 is used, said rail can be arranged/integrated within at least one, two or more distributors 10, 20, for example, only in the first distributor 10 or only in the second distributor 20 or in both.

Nomenclature

1 Power distribution system

2 Fluid inflow

3 Fluid outflow

4 Fluid inlet

5 Fluid return outlet

6 Space to be heated/cooled, e.g. residential/industrial building, boat, swimming pool

7 Area/Part/Zone of space to be heated and/or cooled

8 Heating and/or cooling system/unit

9 Fluid pump

10 First distributor/distribution piping/manifold

11 First manifold inner volume increase/reduction/pressure equalization member/rail 12 First manifold main fluid inlet

13, 13' First fluid outlet from first and second row of outlets from first distributor

X, X' Arbitrary/Last fluid outlet of the first/second row of outlets of the first distributor

14 First row of outlets 13, X of the first distributor

15 Second row of outlets 13', X' of the first distributor

20 Second distributor/distribution piping/manifold

21 Second manifold internal volume increase/reduction/pressure compensation member/rail 22 Second manifold main fluid outlet

23, 23' First fluid inlet of the first and second row of inlets of the second distributor

X", X" Arbitrary/Last fluid inlet of first/second row of inlets of second distributor 24 First row of inlets 23,

25 Second row of inputs 23', X" of the second distributor

30 EPDM ethylene-propylene rubber tubes/tubing/hoses/Cross-linked Polyethylene (PEX)

31 First end of a tube

32 Second end of a tube

33 Female member at the end of a tube, for example a slot.

Y Arbitrary/Last casing tube

40 Female section, p. e.g. in the form of a slot, in the connection part of a distributor

50 Sealing, p. e.g., O-ring, gasket, packing ring, packing made

60 Device/Mechanism for adjusting/moving the pressure compensating rail

70 Device for controlling heating/cooling, such as a thermostat

100 First distributor pipe/hose connection/coupling piece

200 Second distributor tube/hose connection/coupling

D, D', D", D", D"" Distance between the ends of the distributor and the inlets/outlets and between the inlets/outlets R radius of the rail if bent/curved

at angle between the inside top of the distributor and the rail

W Window or door (with or without window) facing/leading to a roof/balcony/terrace

X Number of inputs or outputs of the distributor

L Length of casing tubes

L ^d Distributor length

Claims (8)

1. Energy distribution system (1) for heating or cooling a space (6), at least partially, by means of fluid distribution for heat exchange between the distributed fluid and at least a part (7) of the space, comprising - at least a first distributor (10) comprising a main inlet (12) adapted to receive heating or cooling fluid by means of a fluid inlet (4) for the incoming flow of fluid (2), - at least a second distributor (20) comprising a main outlet (22) adapted to discharge heating or cooling fluid through a fluid return outlet (5) for outflow of fluid (3), and - tubing (30) connected between the outlets (13, 13', X, X') of the first distributor (10) and the inlets (23 ^, 23, fluid flow between the distributors to allow heat exchange between the heating or cooling fluid flowing through the tubing arranged in the space (6) and the space, characterized in that the tubing (30) comprises tubes of substantially the same length (L), and that at least one distributor (10, 20) comprises at least one rail (11, 21) arranged within the distributor, the rail being configured to compensate the variable pressure in the flow of fluid through the distributor by decreasing its internal volume in the direction of fluid flow from its first inlet or outlet (12, 13, 23) to its last inlet or outlet (22, X, X') in relation to the size of each inlet or outlet, and that rail (11, 21) is at least partially movable within its distributor (10, 20) by means of a mechanism (60) in a direction towards or from the inlets or outlets (13, 13', 23, 23', X, X', X') of the distributor. 2. Power distribution system (1) according to claim 1, wherein the tubing (30) comprises at least one or more tubes having an internal diameter of less than 10 mm. 3. Energy distribution system (1) according to claim 1 or 2, wherein the tubing is configured to be placed in at least a part (7) of the space (6) to be heated or cooled, wherein the tubing (30) It comprises 5 to 12 m of piping (30) per m2 of at least the part (7) of the space (6) to be heated or cooled, preferably 6 to 9 m of piping per m2 of at least the part (7) of the space (6) to be heated or cooled, more preferably 6 to 8 m of piping per m2 of at least the part (7) of the space (6) to be heated or cooled, or more preferably 6.5 to 7.5 m of tubing per m2 of at least the part (7) of the space (6) to be heated or cooled. 4. Power distribution system (1) according to any of the preceding claims, wherein the tubing (30) comprises at least one or more tubes having an internal diameter greater than 2; preferably greater than 4 mm; or more preferably greater than 4.5 mm. 5. Power distribution system (1) according to any of the preceding claims, wherein the rail (11, 21) can move linearly within the distributor (10, 20), so that the internal distributor volume decreases when the rail moves towards inputs or outputs (13, 13', 23, 23', X, X', X", Xm). 6. Power distribution system (1) according to any of the preceding claims, wherein each distributor (10, 20) of the system (1) comprises at least one pressure compensating rail (11, 21). 7. Power distribution system (1) according to any of the preceding claims, wherein the piping (30) comprises tubes of substantially the same length or the same length or the same length being between approximately 20 to 40 m. 8. Energy distribution system (1) according to any of the previous claims, wherein the space is a residential building, a warehouse or a swimming pool.