CZ289999B6 - Method of generation of cooling and thermal energy, and equipment implementing this method - Google Patents

Abstract

The invented method of generation of cooling and thermal energy is based on the process at which at least two elastic elements (3) are bent to the limit of elasticity of their materials, then they are connected in such a way that they make contacts between their convex surfaces (7) and the concave surfaces (8) of the adjacent elements (3), then these elastic elements (3) are disconnected and straightened to their initial position. Subsequently the at least one elastic element (3) is rotated by an angle of 180 degrees or a multiple of the angle of 180 degrees along the axis (12), being perpendicular to the axis (11) of bending and straightening of the elastic element (3), and then the whole cycle of bending and straightening is repeated. Equipment for the generation of cooling and thermal energy is arranged in such a manner that at least two adjacent elastic elements (3) are placed in a single plane above each other so that inner surface of the elastic element (3) is in contact with outer surface of the internal adjacent elastic element (3), whereby the marginal internal elastic element (3) is in contact with at least one rotary pulley (2) situated on a rotary one axis (1) and clearances (9) extending between the adjacent elastic elements (3) are created out of the pulley (2) through the mediation of tensioning elements (4), whereby each elastic element (3) has a spot at which it is angularly displaced along a longitudinal axis (12) by an angle of 180 degrees or a multiple of the angle of 180 degrees.

Description

Technical field

The invention relates to a process for obtaining cold and heat and to an apparatus for carrying out the process. The method of obtaining cold and heat and consequently the device is used for cooling or heating in various cooling and heating devices, both domestic and industrial use, in cooling and heating air conditioners for keeping the air temperature at a predetermined level and in other analogous devices.

BACKGROUND OF THE INVENTION

Methods for decomposing thermal energy into a cold component and a hot component compared to ambient temperature are known.

The thermoelectric method is based on the principle of direct current passing through a thermoelectric battery consisting of two connected thermocouples made of two different materials, one of which cools and the other heats.

The main drawback of this method of obtaining heat or cold is the high power consumption for the production of a cooling or heating capacity unit. The advantage is the absence of environmentally harmful substances in the device and during its operation and the absence of moving parts - noisiness, reliability.

Further, an absorption method based on absorption, i.e., liquid or solid vapor scavenger, is known. As a cooling medium, ammonia (NH ₃ ) is generally used, whose water is absorbed by steam, resulting in a solution of ammonia in water, and hunger is produced by boiling the cooling medium in the evaporator.

The disadvantage of this method is the presence of a toxic substance under pressure and high power consumption for the production of a cooling or heating capacity unit.

The advantage is the absence of moving parts - noiselessness, reliability.

Currently, the most widespread of the known methods of obtaining cold is the method of obtaining cold by a compressor method based on adiabatic expansion and compression of the cooling medium. Cold is created by evaporating the coolant in the evaporator and heat by condensation of the gaseous medium in the condenser. The motor compressor is used to obtain the necessary pressure and transport the coolant. Freons of different types are used as cooling medium.

The main drawback of this method of obtaining cold and heat is the presence of an environmentally harmful and expensive refrigerant under pressure, i.e., freon, and an acceptable power consumption to produce a cooling or heating unit.

The advantage of this method of obtaining cold is the fact that this solution is the least energy-intensive to produce a cooling or heating unit.

Thermoelectric devices are also known, consisting of two connected thermocouples made of two different materials, one of which cools and the other heats.

The disadvantage of this device is the high power consumption for the production of the cooling or heating capacity unit.

-1 CZ 289999 B6

The advantage is the absence of environmentally harmful substances in the device and during its operation and the absence of moving parts-noise, reliability.

Furthermore, absorption devices are known whose principle is based on the absorption (absorption) by a liquid or solid vapor absorber of the coolant produced by evaporation in the evaporator. The cooling medium of the absorption devices is ammonia whose water is absorbed by the vapors to form a solution of ammonia in water. Cold is produced by boiling the coolant in the evaporator.

The disadvantages of this device are the presence of toxic gas under pressure and high power consumption for the production of a cooling or heating unit.

The advantage is the absence of moving parts-noise, reliability.

The closest technical solution in terms of the resulting effect, i.e. obtaining cold or heat, to the invention is a compressor type device based on adiabatic expansion and compression of the cooling medium. It consists of a compressor, an outlet, a condenser, a pipe system, a dehumidifier and a coolant filter. Freons of different types are used as cooling medium.

The drawbacks of this device are the presence of environmentally harmful and expensive refrigerant under pressure-freon, and the sustainable consumption of electricity for the production of a cooling or heating unit. The result of the complicated construction of the compressor motor is noise, vibration, failure rate, difficult reparability - the need for soldering, hermetically sealed compressor casing with freon.

The advantage is that this solution consists of the least energy-intensive ones required to produce a cooling or heating unit. This cold production solution is currently the most widespread in the world.

SUMMARY OF THE INVENTION

To a large extent, the method of recovering the cold and heat of the present invention is based on the fact that at least two adjacent resilient elements bend to the limits of their material elasticity, then join by contacting the convex surface with the concave surface of adjacent elements then the adjacent resilient elements are detached and straightened to a starting position, then bent and the resilient elements are re-straightened, with at least one resilient element rotated at 180 ° or a multiple of 180 ° along each axis after each bending and straightening cycle, perpendicular to the bending and straightening axis of the elastic elements.

The principle of the heat and heat recovery device is that at least two adjacent resilient elements are disposed one above the other so that the surfaces of adjacent resilient elements are contacted such that the inner surface of the outer resilient element is contacted with the outer surface of the inner adjacent resilient element wherein the outer - means adjacent but more distant from the pulley, and the inner - means adjacent but closer to the pulley, the extreme inner elastic element being contacted on at least one pulley located on the pivot axis, and gaps are formed between adjacent elastic elements by tensioning means The elements are positioned in the same plane with the resilient elements and the pulley, each resilient element having a location at which it is rotated 180 ° along the longitudinal axis or a multiple of 180 ° relative to the adjacent resilient element.

The main advantage of the method of recovering heat or cold and consequently of the apparatus for carrying out the method according to the invention is seen in the elimination of its negative impact on the environment by avoiding the use of substances harmful to humans, the environment or the atmosphere. heating power.

-2GB 289999 B6

The task is solved by bending different elements, but not more than the elastic limit of the material, then they are joined by contacting the convex surface with the concave adjacent elastic elements, then the adjacent elastic elements are disengaged and returned to their starting position. At the same time, those surfaces which were concave when bent are cooled and the opposite surfaces, i.e. convex, are heated.

The above-described bending and straightening cycle can be performed repeatedly, wherein after each uncoupling and subsequent straightening, the spring elements are arranged such that in the group, after each bending and straightening cycle, alternate even and odd spring elements rotate 180 ° along an axis perpendicular to the axis bending and straightening elastic elements.

The presence of a bending operation of the elastic elements, but not more than within the elastic limit of the material, allows two thermal potentials, positive and negative, to be obtained on opposite surfaces of the elastic elements.

This process is due to the known effect of changing the energy of the elastic bodies during their elastic deformation, which implies that when the body expands within its elasticity, its internal energy decreases and, on the contrary, it increases during compression. In this case, when bending the elastic element, its layers close to the center of the bend are compressed and simultaneously heated, and the layers on the opposite side, distant from the center of the bend, expand and simultaneously cool.

The subsequent joining of the convex and concave surfaces of the adjacent resilient elements makes it possible to compensate, by way of heat transfer between the joined surfaces, the positive and negative thermal potentials formed therein.

The subsequent uncoupling of the elastic elements and their return to their initial position (straightening) leads to the re-emergence, on opposite surfaces of the elastic elements, positive and negative thermal potentials, due to compression and expansion of the respective layers.

Sequence of events where multiple bending and straightening of a plurality of elastic elements, after each bending and joining of adjacent resilient elements, followed by disengagement and straightening, regroup so that in the plurality of elastic elements, alternating dry and odd elements rotate each time an angle of 180 ° along an axis perpendicular to the bending and straightening axis results in a gradual, dependent on a plurality of bending and straightening, addition cycles, on respective sides of the elastic elements, the positive and negative thermal potentials. In this way, on one side of the plurality of elastic elements, the positive and opposite sides of the negative thermal potential increase.

The absolute values of said thermal potentials depend, besides a number of bending and straightening cycles, also on the physical properties of the elastic elements, i.e. on the limit and modulus of elasticity, thermal capacity, thermal conductivity and the like. and also on the number of these elastic elements in the group. The total thermal potential of the whole group of elastic elements is zero after any number of bending and straightening groups of the group.

In addition, the sum of the kinetic and potential energy of the entire group of elastic elements does not change after the group has been brought into the initial position for any number of bending and straightening cycles.

The internal energy of the elastic elements does not change, since the bending and straightening is carried out to the quasi-stationary modes, when the deformation proceeds so slowly that at any moment each part of the elastic element is practically in equilibrium, i.e. external forces equal the elastic forces. In such a mode of elasticity, it is equal to the work of the force applied to the deformation of the body.

Regardless of the number of bending and straightening cycles of the group of elastic elements, the total temperature as well as the kinetic and potential energy of the group of elastic elements does not change, of which

It follows that, in accordance with the law of conservation of energy, it is not necessary to dispense such a quantity of energy in order to carry out said method of obtaining cold and heat, which ensures the exceptional economy of the method.

At the same time, the absence of environmentally harmful substances in the facility and its operation is achieved, ie substances harmful to man, the environment or the Earth's atmosphere.

For the proper functioning of the device, it is advantageous that the elastic elements are belts made of outer elastic layers and inner thermal insulating layer or are of uniform composition, that the flexural stiffness of the elastic elements increases from inner elastic elements to outer, that elastic elements are in the form of closed endless belts and / or mobia leaves.

The Mobi sheet is a flat strip having two surfaces, top and bottom, of any finite length material, the ends of which are joined such that a closed endless ring is formed by having one end rotated 180 ° to the other end before joining. In this way, the upper surface smoothly merges into the lower surface and vice versa. This results in a spatial formation formed by a flat strip but having only one surface.

Placing the elastic elements in one plane on top of each other, while extending them, ensures close contact between the elastic elements, resulting in improved heat exchange conditions between them, helping to reduce the energy consumption for producing the unit's cooling or heating capacity.

Securing the gap between the elastic elements allows the distribution of the thermal potentials arising on the outer layers of the elastic elements as they are bent and straightened, and also allows longitudinal flipping of the elastic elements.

Longitudinal rotation of the elastic elements by 180 ° allows the positive and negative thermal potentials of the outer layers of the elastic elements to be bent and straightened to be added, while the negative thermal potential increases gradually from the middle elastic element to the outer elastic elements and the positive thermal potential increases .

The design of the elastic elements with the outer elastic layers and the middle thermal insulating layer allows to reduce the flexural stiffness of these elastic elements compared to homogeneous elastic elements made of one material. Due to the lower flexural rigidity of the thermal insulation layer, while maintaining the thermal potentials of the surfaces of the elastic elements as they flex, it allows a reduction in the force required to stretch the elastic elements, thereby reducing frictional forces on the pulley axes and tensioning elements. The thermal insulation layer between these resilient layers slows down the undesirable heat exchange between the resilient layers of the same resilient element, occurring at different thermal potentials on both sides of the resilient element and the element, generated at different thermal potentials on both sides of the resilient element. cooling or heating capacity.

The above-mentioned essential features characterize the device according to the invention which does not contain any ecologically harmful substances, substances harmful to man or the earth's atmosphere and also does not have any negative impact on the environment by its operation.

In the device according to the invention, the energy required to bend and not align the elastic elements by the pulleys translates into thermal energy, with a positive potential for the elastic elements close to the pulleys and a negative potential for the outer elastic elements. The energy losses to the operation of the device are limited only by the friction losses during the rotation of the pulleys and on the tensioning elements, and to losses associated with the resistance of the environment in which the device operates, e.g. air.

-4GB 289999 B6

The device according to the invention is considerably more economical with its energy losses for the production of a cooling or heating unit than other known devices.

The design of the tensioning of the elastic elements, with the aid of the tensioning sliding elements, allows the dimensions of the given device to obtain cold and heat to be reduced and the construction of the device to be simplified. The flexural stiffness of the elastic elements increases gradually from the inner elastic elements to the outer ones, despite the increasing radius of movement of the elastic elements allowing to maintain the same value of elastic energy and thus the value of negative and positive thermal potentials occurring on both surfaces of the elastic elements .

BRIEF DESCRIPTION OF THE DRAWINGS

1, 2, 3, 4, 5, 6, 7, 8, 9 show a sequence of steps in performing the method of obtaining cold and heat, with reference numerals 3.1, 3.2, 3.3, 3.4 and 3.5 express the numbers of elastic elements in the group.

Fig. 10 shows a cooling and heat recovery device with two pulleys in a block view, Fig. 11 shows a section AA of an elastic element, Fig. 12 shows a cooling and heat recovery device with three pulleys in a side view and Fig. 13 shows a side view of a single pulley cooling and heat generating device.

DETAILED DESCRIPTION OF THE INVENTION

In Fig. 1, a group 10 consisting of five elastic elements 3 in the starting position is shown. The left side of each elastic element 3 is hatched to illustrate the subsequent manipulations.

The elastic elements 3 bend, but not more than within the elastic limit of the material. Here, the material layers of the elastic elements 3 located on the concave surface 8 are compressed while heating, and the layers located on the convex surface 7 are expanded while cooling. The middle layers of each elastic element 3 are neither compressed nor stretched, thus maintaining their original temperature. We denote the thermal potential of compressed layers as t = +1 and expanded t = -l.

All the elastic elements 3 are joined by concave surfaces 8 and convex surfaces 7, as shown in FIG. 3. Due to the connection, the heat exchange between the joined cooled and heated layers of the adjacent elastic elements 3 takes place, their temperature equals and reaches the initial value .

Thereafter, the elastic elements 3 disengage, as shown in FIG. 2, and straighten, as shown in FIG. 1. As a result of the straightening, the concave surfaces 8 of the elastic elements 3 expand and thereby cool and acquire a thermal potential t = -1. heat and gain a thermal potential of t = +1. The thermal potentials of the elastic elements 3 then obtain the following values: for element 3.1, the shaded side t = 0, the empty side t = 1; for elements 3.2, 3.3 and 3.4 hatched side t = +1, blank side t = -1; for element 3.5 hatched t = +1, blank side t = 0.

Thereafter, the group of elastic elements 3 is rearranged by rotating the even elastic elements 3 through an angle of 180 ° along an axis 12 perpendicular to the bending and straightening axis of the elastic elements 3, as shown in Fig. 4, then the elastic elements 3 bend, 5, and then connect the concave surfaces 8 and the convex surfaces 7 to each other, as shown in FIG. 6, then the elastic elements 3 disengage, as shown in FIG. 5, and then the elastic elements 3 are aligned, see FIG. 4. After the above operations associated with cooling and heating the expanded and compressed layers and the heat exchange therebetween, the thermal potentials of the elastic elements 3 obtain the following values: for element 3.1, the shaded side t = 0, the empty side t = -2; element 3.2 blank side t = 0,

-5GB 289999 B6 Hatched t = 0; element 3.3 shaded t = +2, blank side t = —2; element 3.4 blank side t = 0, hatched side t = 0; for element 3.5 hatched side t = +2, empty side t = 0.

Subsequently, the group 10 of elastic elements 3 is rearranged by rotating the odd elastic elements 3 through an angle of 180 ° along an axis 12 perpendicular to the bending and straightening axis 11 of the elastic elements 3, see Fig. 7, and performing analogous operations described above. Fig. 8,9. The thermal potentials of the elastic elements 3 obtain the following values: for element 3.1, the blank side t = -2, the hatched side t = -1; element 3.2 blank side t = +1, hatched side t = -2; element 3.3 blank side t = 0, hatched side t = 0; element 3.4 blank side t = +2, hatched side t = -1; for element 3.5 blank side t = +1, hatched side t = +2.

From the above, it can be seen that as the number of bending and alignment cycles increases with the rearrangement of the resilient elements 3, the absolute values of the negative thermal potential on the resilient elements 3 distant from the center of the bending and equalization do not increase. the absolute total thermal potential on all elastic elements 3 is zero.

During subsequent cycles of bending and aligning the elastic elements 3 with their regrouping described above, the negative and positive thermal potentials further increase on the respective surfaces of the elastic elements 3.

The maximum value of the thermal potential that can be achieved on any elastic element 3 can be determined by the formula:

+ -T = t.n.2 where:

t- the absolute value of the thermal potential arising on the stretched or compressed layers of the elastic element 3, n - the sequence number in group 10 of the elastic element 3 from the middle (excluding the middle), to the right or left of it,

- (minus) refers to the temperature potential of those resilient elements 3 that are located on the side of the central resilient element 3 that is farther from the center of bending and alignment, + (plus) refers to the temperature potential of those resilient elements 3 that are located on the side of the central elastic element 3, which is closer to the center of bending and alignment.

Referring to FIG. 10, there is shown a cold and heat generating device consisting of rotary pulleys 2 mounted on axes 1, fitted with five infinite spring elements 3 in the form of a mobia sheet, between the pulleys 2 the spring elements 3 are tensioned by tensioning rolling elements 4 , the tensioning roller elements 4 can be slidable (not shown in the figure).

To drive the pulleys 2 with the elastic elements 3, the drive (not marked in the figure) serves.

The elastic elements 3 on the pulleys 2 are positioned in such a way that the longitudinal rotation of the elastic elements 3 by an angle of 180 ° relative to the adjacent elastic element 3 occurs after the adjacent elastic elements 3 on the pulleys 2 have been disengaged in the gaps 9.

The elastic elements 3 can be both homogeneous (not indicated in the figure) and composed of elastic layers 5 on the surface with the thermal insulation layer 6 in between, as shown in FIG. 11.

-6GB 289999 B6

FIG. 11 shows a cross-section of a resilient element 3 composed of resilient layers 5 and a thermal insulation layer 6 fixed therebetween.

Fig. 12 shows a particular embodiment of the device according to the invention, using three pulleys

2. The elastic elements 3 can be designed in the form of both endless belts and mob blades. The Mobius sheet is a flat strip having two surfaces, top and bottom, of any finite length material, the ends of which are joined such that a ring is formed by having the end rotated 180 ° to the other end before joining. In this way, the upper surface smoothly merges into the lower surface and vice versa. This results in a spatial formation formed by a flat strip having only one surface.

Between the pulleys 2, the elastic elements 3 are tensioned by tensioning rolling elements 4, while the tensioning rolling elements 4 can be designed as sliding (not shown in the figure).

Fig. 13 shows a special embodiment of a device using a single pulley 2. The cooling and heat recovery device operates as follows. After switching on the drive (not shown in the figure), the pulleys 2 start to rotate on the axes 1, carrying the spring elements 3 by friction. As a result of the movement of the described device on the respective outer surfaces of the elastic elements 3, positive and negative potentials arise and accumulate in accordance with an analogous process described in the application. As the number of turns (cycles of bending and straightening of the elastic elements 3) increases, the elastic elements 3 closer to the quartz 2 for the middle elastic element 3 gradually gain positive thermal potential and the elastic elements 3 more distant from the pulley 2 for the middle elastic element 3 thermal potential.

In operation of the device according to the invention, a different temperature arises between the opposing surfaces of the elastic element 3, which leads to heat exchange across the body of the elastic element 3, which reduces the absolute thermal potentials on the surfaces of the elastic element 3 thereby reducing cooling and heat output. The heat-insulating layer 6 firmly connected to the two flexible layers 5 reduces losses, thereby increasing the cooling and heating performance of the described apparatus. Operation of the apparatus using more than two pulleys 2 (eg three pulleys 2, see Fig. 12) also produces the effect of cooling and heating the respective elements 3.

When using any number of pulleys 2, the power required to operate the described apparatus is consumed solely on the friction when the pulleys 2 rotate on the axes 1 given by the spring force 3, the friction on the tensioning elements 4 given the spring force 3 and the environment in which the device operates.

Industrial applicability

The method of obtaining cold and heat and the apparatus for carrying out this method are industrially applicable in all areas of the economy, in particular in the manufacture of refrigeration, heating, air conditioning equipment.

Claims (8)

Method for obtaining cold and heat, characterized in that at least two adjacent resilient elements (3) bend to the limit of their material elasticity, after which the convex surface (7) of one resilient element (3) joins the concave surface (8) of the other adjacent to the elastic element (3), then the elastic elements (3) detach and straighten to the starting position, after which the at least one elastic element (3) rotates 180 ° or a multiple of 180 ° along the axis (12) perpendicular to the axis the bending and straightening axis (11) of the elastic element (3), then the entire bending and straightening cycle is repeated. Method for obtaining cold and heat according to claim 1, characterized in that the elastic elements (3) are grouped into groups (10) consisting of even and odd elastic elements (3). Method for obtaining cold and heat according to claims 1 and 2, characterized in that in the group (10) of rotation of the even elastic elements (3), after each cycle of bending and straightening, alternates with the rotation of the odd elastic elements (3). Cooling and heat recovery device, characterized in that at least two adjacent resilient elements (3) are disposed one above the other so that the inner surface of the outer resilient element (3) is contacted with the outer surface of the inner adjacent resilient element (3). 3), wherein the outermost elastic element (3) is contacted on at least one pulley (2) located on the pivot axis (1), and the gaps (9) between adjacent elastic elements (3) are formed outside the pulley (2) by tensioning elements (4), wherein each resilient element (3) has a location at which it is rotated along the longitudinal axis (12) by an angle of 180 ° or a multiple of an angle of 180 ° relative to the adjacent resilient element (3). Cold and heat recovery device according to claim 4, characterized in that the elastic elements (3) are made of an outer flexible layer (5) and an inner thermal insulation layer (6). Cooling and heat recovery device according to claim 4, characterized in that the elastic elements (3) are of uniform composition. Cold and heat recovery device according to claim 4 and 5 or 6, characterized in that the bending stiffness of the elastic elements (3) increases from the inner elastic elements (3) to the outer ones. Cold and heat recovery device according to claim 4 and 5 or 6 and 7, characterized in that the elastic elements (3) are in the form of closed endless belts and / or mobi sheets.