CZ307908B6 - Multifunctional mobile mono-block container for a complete heat pump system linked to a transport platform - Google Patents

Abstract

The multifunctional mobile mono-block container (1) of the complete heat pump system (2) coupled to the transport platform (3) consists of a base support skeleton (4) divided, for example, into three separate sections, the first evaporator section (5) has a pair of opposing vertical evaporators (6) alternatively, the second evaporator section (7) has a pair of opposing inclined evaporators (6) alternatively, and the third process section (8) has a heat pump system (2), the base load-bearing shell (4) of the lifting segments (9) and the adjacent outer profiles (10) have, in the area of the evaporator sections (5), (7) installation cut-outs (11) for installing the shielding and control technology (12) of the air streams with a downstream cover plate (13), the continuous anchor segments (14) of the axial fans (15) ) with a central reinforcement (16) of the roof fan segment (17). The working area of the technological section (8) consists of a group of, for example, four heat pumps (53) installed in defined positions on an anchor base (69) for flexible assembly, disassembly or replacing the entire heat pump unit (53), with a multifunctional mobile container mono-block (1) linked to the transport platform (3), to flexibly move the system by a conventional truck with a defined superstructure to accommodate and unload the structure of the transport platform (3) by attaching a pull hook (76) installed in a defined position at the front end structure (75) of the partial reinforcement (77) stressed areas; the frontal structure (75) adjoins the base support frame (72) with several centre stiffeners (73) installed to provide deformation stability to the transport platform (3), an implementation of the multifunctional mobile container mono-block (1) by an anchoring mechanism (71) installed at the ends of the support profiles (74).

Description

Technical field

The solution relates to a complex mobile container monoblock of a geothermal air / water heat pump system with both heating and cooling function and connection to a transport platform.

BACKGROUND OF THE INVENTION

There are a number of solutions for heat pump units taking heat from a variety of environments and solid, liquid or gaseous media through specific types of flushes, but most design solutions require some building readiness and dimensioning for specific offtake parameters related to stationary heat pump unit installation. in the external and internal space of the sampling point object.

Currently, air / water, water / water, ground / water heat pump systems are most often used, depending on the specific location of the installation. The design and performance of heat pump systems are usually of less power, with the need to be combined into cascading sets with the subsequent construction of backbone conduits transferring refrigerant between the indoor and outdoor units.

The above shortcomings can be identified across the full range of commercially available heat pump unit solutions, such as those of Stiebel Eltron GMBH & CO KG; Mitsubishi Heavy Industries Ltd.; Rocky Research; Therma-Stor LLC, Technologies Holding Corp.; HYDRO DELTA CORPORATION; DORNIER GMBH whose solutions are disclosed, for example, in patent applications EP 2597379 A2, WO 0036344 A1, DE 202010001244 U1, US 6769481 B2, US 9239174 B2, US 9578867 B2, US 5465588 A, DE 10035563 A1, US 8733118 B2.

Purpose solutions of the heat pump system have favorable parameters in many respects but it is very difficult especially to the actual parameters and the design solutions are to be transported flexibly and included in the system of heating or cooling systems of offtake points with short installation horizon. the transport of the available heat pump system itself, due to the retrofitting of the system at the installation site, presents a risk of damage to the mechanical elements of the system. Alternative technical solutions of compact heat pump blocks such as York, ThermoPools and United Technologies Research Center with the possibility of heating and cooling of downstream media are conceived in a comprehensive system working in symbiosis of individual components, but the dimensional parameters of these systems vary mainly depending on installed capacity. the total transferability is highly dependent on the mode of transport, including the handling equipment required to install the technology.

The disadvantages of the current design of heat pumps are, in particular, their unfit for short-term installation, the possibility of flexible assembly or disassembly and the very limited ability of flexible transport without the potential for damage to the mechanical parts of the heat pump unit system.

SUMMARY OF THE INVENTION

These disadvantages are overcome by a multifunctional mobile container monoblock complex

The heat pump system consists of a basic supporting skeleton divided into, for example, three separate sections linked to a transport platform allowing flexible transport and integration of the system into existing or newly built heating or cooling systems of downstream offtake technology through a complex heat pump system in the technology section and associated pairs of opposing filaments situated in alternative positions of the first and second fume sections, it enables to remove, transform and redistribute the thermal potential of the surrounding environment or to thwart the thermal potential taken from the cooling circuit of the sampling point through the internal processes of a complex heat pump system , wherein the basic support skeleton is formed from corner lifting segments with adjacent outer profiles equipped with installation cut-outs for shielding and regulation technology of air currents with adjoining face plate, continuous anchoring segments of axial fans with centrally situated reinforcement of roof fan segment and anchoring profiles of partial sections. fitted with a group of shaped crossbeams in a defined slope, which is connected to the floor panel A of the second discharge section, the floor section of the supporting section of the technology section is phenomena symmetrically fitted with a group of straight profiles followed by the roof segment and floor plate of the technological section , the basic supporting skeleton is fitted with an additional anchoring profile in the front part of the technological section technology section entrance doors, technology section peripheral passages are further fitted with a removable sheath A anchored through bolts through the heat pump system frame, a removable sheath B and a removable sheath C with an installed group of insulated removable pipe segments of heating medium supply and return pipes and cable conduits which is anchored to the basic supporting skeleton, the technological section is separated from the adjacent second discharge section by a technological partition with a removable piping partition for guiding the refrigerant pipes of the heat pump system to a defined pair of evaporators. The second pairs of flutes alternatively in an inclined position is provided with an angular fill ideally abutting the anchoring profiles of the base support skeleton and a defined pairs of flutes alternatively in an inclined position which is anchored in its lower part to the floor crossbeams through floor panel A through the floor anchoring segment, to which the condensate drain segment is connected from the outside and at the same time the inner walkable sheet with the adjoining removable pipeline of the refrigerant piping of the first discharge section adjoins from the outside.

Further, it is desirable if a metal module partition abutting on a pair of opposing bumps alternately in an inclined position is installed in the interior space between the second and first flue gas section, wherein the metal module partition is provided with a revision passage with an installed door segment in its center. in the vertical position of the first flush section it is anchored in the lower part to the floor panel B with a mounting passage fitted with a revision cover, which is anchored to the shaped floor transverse beams, the pair of opposite flutes is further anchored in its upper part into the external profile by ceiling anchoring segment B , the first outlet section is fitted from the front with a group of removable wall modules anchored to the basic supporting skeleton, with the shielding and control technology installed In the installation cut-outs of the external profile of the ceiling structure of the steam section, it consists of a group of flexible brackets for the upper

-2E 307908 B6 A profile with a guide cable winding and winding wiring that is anchored to partial profiled shield segments and a lower support profile, each profiled shield segment is fitted with a guide roll on the sides adjoining the guide profiles installed in the anchor profiles base skeleton.

It is further desirable that the heat pump system assembly comprises a plurality of, for example, four heat pumps situated within the frame of the technology, connecting the insulated process tank fitted with a defined number of eight inlet and outlet nozzles, inlet and outlet flanges, pressure and flange elements. and temperature sensors and electric heaters, the inlet piping fitted with a circulating pump connected to the outlet nozzles of the insulated process tank faces spatially to the inlet nozzle of the plate capacitor, the heat pumps are further provided with a refrigerant circuit inlet on their rear side pointing through a removable pipeline to connect of defined pair of opposing bumps, where the return line of the refrigerant circuit trajectory through a removable duct to the heat pump.

Furthermore, it is suitable that the transport platform is connected to the multifunctional mobile container monoblock by means of an anchoring mechanism, the transport platform being formed by a basic supporting frame with a group of continuous center stiffeners, supporting profiles with front mounted anchoring mechanism of the multifunctional mobile container monoblock. The front part with the front structure and the pull-in hook installed, with the rear part fitted with a system of two rollers secured by a pin.

The proposed solution has the following advantages:

- a comprehensive built-in technology combining a system of individual heat pump blocks, accessories on one assembly shell and a system of flushing systems implemented into the air-water container construction, a multi-function superior control system with a high optimization capability of the complex system function,

- with high flexibility of transport and removal using commercially available container carriers,

- with the capability of connecting the geothermal source to the building's heating / cooling system in a flash connection - without interfering with or reducing its space.

Clarification of drawings

In the accompanying drawings, FIG. 1 is an overall axonometric view of a multifunctional mobile container monoblock of a complex heat pump system coupled to a transport platform;

Fig. 2 is a perspective view of the internal configuration of the base skeleton with a removable sheathing and floor panels; Fig. 3 is an overall axonometric view of a multifunctional mobile container monoblock of a complex heat pump system;

Fig. 4 is an overall axonometric view of the technological equipment of the multifunctional mobile container monoblock of a complex heat pump system;

Fig. 5 is a view of the internal configuration of the main technological elements of the multifunctional mobile container monoblock;

FIG. 6 is a view of a technological section of a multifunctional mobile container monoblock;

FIG. 7 is an overall perspective view of the transport platform.

DETAILED DESCRIPTION OF THE INVENTION

The multi-functional mobile container monoblock 1 of the complex heat pump system 2 linked to the transport platform 3 is formed by a basic supporting skeleton 4 divided, for example, into three separate sections, where the first discharge section 5 is fitted with a pair of opposite discharges 6 alternatively in vertical position; the second technological section 8 is equipped with a heat pump system 2, the basic support frame 4 is formed by lifting segments 9 from the corners and adjacent outer profiles 10 provided in the area of the ceiling structure of the water discharge sections 5, 7 with installation pipes. cut-outs 11 for the installation of shielding and control technology 12 of the air currents with the adjoining face plate 13, further continuous anchoring segments 14 of axial fans 15 with central reinforcement 16 of roofs The floor section of the parquet sections 5, 7 of the base skeleton 4 is fitted with a plurality of shaped crossbeams 19 at a defined inclination, which is adjoined by the floor section. panel A of the expensive parquet section 7, whereby the floor section of the base support skeleton 4 of the technology section 8 is symmetrically fitted in the ceiling and floor section with a group of straight profiles 21 adjoining the roof segment 22 and the floor plate 23 of the technology section 8. is in the front part of the technology section 8 equipped with an additional anchoring profile 18, which is connected to the entrance door 24 of the technology section 8, the peripheral penetrations of the technology section 8 are further equipped with a removable sheath A 25 anchored by bolts 26 through frame 27 Heat pump system 2 technology, removable sheathing B 28 anchored to the elements of the basic skeleton 4 and removable sheathing C 29 with an installed group of insulated passages 30 removable pipe segments 31 of the heating medium inlet pipe 67 and return pipe 68 and cable conduit anchored to The technological section 8 is separated from the adjacent expensive flue section 7 by a technological baffle 32 with a removable pipe baffle 33 for guiding the refrigerant pipes 34 of the heat pump system 2 to a defined pair of opposite fumes 6. The expensive flue section 7 with a pair of opposite fumes 6 in an inclined position it is provided with an angle filler 35 abutting on the anchoring profiles 18 of the basic supporting skeleton 4 and defined by a pair of opposing disks 6 alternatively in an inclined position, which is in the inclined position. anchored to the floor crossbeams 19 through the floor panel A 20 by means of a floor anchoring segment 36, which is followed by an external condensate drain segment 37 and an inner walkable sheet 38 with a removable piping partition 33 of the refrigerant pipes 34 of the first discharge section. 5, wherein the upper portion of the defined bumps of the pair of opposing bumps 6 is anchored to the outer profile 10 via the ceiling anchoring segment A 39. The expensive bump section 7 and the first bump section 5 are separated from each other in the interior by a metal module partition 40 abutting the pair of opposite bumps 6 In the inclined position, the sheet metal module partition 40 is provided in its center with an inspection passage with the door segment 44 installed.

Alternatively, the pair of opposites 6 in the vertical position of the first puff section 5 is

Anchored in the lower part to the floor panel B 42 with an access passage fitted with a revision cover 43, which is anchored to the shaped floor transverse girders 19, the pair of opposing struts 6 is further anchored in its upper part to the outer profile 10 by ceiling anchoring In the segment B 44, the first flush section 5 is fitted from the front with a group of removable wall modules 45 anchored to the basic support frame 4.

Shielding and control technology 12 installed in the installation cut-outs For the outer profile 10 of the ceiling structure of the flushing sections 5, 7, it consists of a plurality of flexible holders 46 of the upper support profile 47 into which an axle drive 48 is wound. the shielding segments 49 and the lower support profile 50, each profiled shielding segment 49 being provided on the sides with a guide roller 51 adjoining the guide profiles 52 installed in the anchoring profiles 18 of the basic support frame 4.

The heat pump system assembly 2 comprises a plurality of, for example, four heat pumps 53 situated in the technology frame 27, which is anchored to the floor plate 23 and the straight sections 21 of the floor section of the base skeleton 4. The partial heat pumps 53 are provided with an outlet nozzle 54 and an inlet conduit 55 of a plate capacitor 56 connected to an outlet conduit 57 directed to an insulated process tank 58 equipped with a defined number of inlet conduits 55 and outlet conduits 54 and an inlet and return flange 59 of the heating circuit. 60, temperature sensors 61 and electric heating elements 62, which are connected to a control system situated in the switchboard box 63. The inlet piping 64 fitted with a circulation pump 65 connected to the outlets 54 of the insulated process The tank 58 faces spatially towards the inlet socket 55 of the plate capacitor 56.

Furthermore, the inlet and return flanges 59 of the heating circuit of the insulated process tank 58 are synchronously connected to the shut-off valves 66 and the removable piping segments 31 fitted with temperature sensors 61. The partial heat pumps 53 are further provided with a refrigerant circuit inlet 67 on their rear side. for connecting a defined bore to a pair of opposed bores 6, wherein a return line 68 of the coolant circuit extending along an identical trajectory through a removable duct 33 to the heat pump 53 is connected in the region, the heat pump components 53 being installed on the anchor base 69 members 70 into the technology frame 27.

The transport platform 3 coupled to the multifunctional mobile container monoblock 1 by means of the anchoring mechanism 71 is formed by a basic supporting frame 72, which is connected along the entire length by continuous central stiffeners 73, with supporting profiles 74 with an anchoring mechanism installed at the end. The front part of the transport platform 3 is further fitted with a head structure 75 with a pull-on hook 76 and a plurality of reinforcements 77, the rear portion with a system of 78 rolls secured by a pin anchored to the elements of the support profiles 74.

Function

The multi-functional mobile container monoblock 1 enables, through the complex heat pump system 2 situated in the technology section 8 and the associated pairs of opposing discharges 6 situated in the alternative positions of the first discharging section 5 and the second discharging section 7, to remove, transform and further distribute the thermal potential of the environment or environment to thwart the heat potential taken for example from the heating circuit of the offtake point through the internal processes of the complex heat pump system 2. The overall rigidity and configuration of the multifunctional mobile container monoblock 1 is defined by a basic carrier skeleton 4 formed of outer profiles 10 and at the corners of the lift segments 9, which allow direct implementation and fixation on the

The supporting structure of the basic supporting skeleton 4 is fitted with a group of continuous anchoring segments 14 into which, in a defined position relative to the pairs of opposite pits 6, alternatively axial fans 15 are installed in an oblique or vertical position forming the axial fans 15 a symmetrical flow of ambient air through the surfaces of the pair of opposing fins 6, by which the temperature potential of the air flowing into the coolant transferred by the said fin is transmitted. The continuous anchoring segments 14 located in the axis of the ceiling structure of the basic supporting skeleton 4 are externally fitted with a central reinforcement 16, which creates a bearing surface in the area and at the same time the load distribution of the roof fan segments 17 by external influences. The floor section of the bilge sections 5, 7 is fitted with a plurality of shaped floor crossbeams 19, which with the adjacent floor panel A 20 of the expensive bilge section 7 and the adjoining floor panel B 42 of the first flush section 5 creates a defined inclination to the center of the base support frame 4, through which liquid medium is discharged from the space of the flush sections 5, 7, arising in the form of condensation, process states of the technology or precipitation totals, where the expensive flush section 7 is alternatively at an oblique position on the outside of the pair of opposing flutes 6, fitted with condensate drain segment 37 adjoining floor anchoring segment 36 thereby discharging the medium from outside The position of the pair of opposing fumes 6 alternatively in an inclined position is defined by the shape of the floor anchoring segments 36 abutting the bottom of the filaments while being interconnected by a walkway plate 38, thereby forming an installation tunnel for the passing coolant pipe 34, the upper part of the strips is anchored to the outer profile 10 via the ceiling anchoring segment A 39, and at the same time the outer space between the pair of opposing strips 6 alternatively in an inclined position e and the anchoring profiles 18 are filled with an angle filler 35, the array forming an enclosed space directed by a flow of ambient air through defined bumps. The inner space of the first and second discharge sections 5 is separated from each other by a sheet metal module partition 40 with the door segment 44, which allows revision access to the second discharge section 7 while eliminating the interaction of the airflow through axial fans 15 through the section sections. A pair of opposing pits 6 alternatively in a vertical position, the first pumping section 5 is anchored on its underside to the floor panel B 42, wherein the installation and inspection of the joints is performed from the interior of the first pumping section 5 through the inspection opening with adjoining revision cover 43 at the same time the anchors 6 are anchored to the outer profile 10 by the ceiling anchoring segments B 44, the arrangement defining the vertical position of a pair of opposing anchors 6 within the basic support frame 4, the interior of the first anchoring section 5 being enclosed by a plurality of removable wall modules 45 5. The technology section 8 is separated from the expensive discharge section 7 by a technological partition 32 with a removable piping partition 33 installed defining the positions of the technology. and permits hermetic insulation separating the sections. The outer configuration of the technology section 8 is characterized by the possibility of dismantling the sub-area of the cladding in relation to the availability of installed technologies, in particular the removable cladding A 25 situated in the area of the heat pump system 2. the outer configuration of the technology section 8 further comprises a removable sheath B 28 adjacent to the side of the heat pump system 2, an entrance door 24 and a removable sheath C 29 is provided with a plurality of insulated passages 30 at defined positions defining the positions of the removable pipe segments 31 synchronously connected to elements of the insulated process tank 58. The first effluent section 5 and the expensive effluent section 7 are fitted with a system of shielding and control technology 12 installed via flexible holders 46 into the space of the outer profiles 10 provided with installation cut-outs 11;

The area of the ceiling anchoring segment A 39 and the ceiling anchoring segment B 44 is provided with a facing sheet 13, which allows the extended elements of the screening and control technology 12 to be hidden from both safety and functional aspects of technology. The shielding and control technology 12 is formed by an assembly of the upper support profile 47 with an implemented drive 48 that generates the necessary movement transmitted through the winding axis and winding segment anchored to the partial profiled shielding segments 49 and the lower support profile 50 thereby generating desired movements and process. positions of the shielding and control technology 12, said positions allow stepwise switching of the heat pump units 53 in relation to the flow levels of the axial fans 15 of said discharge section. The movement trajectory of the screening and control technology 12 is defined by a pair of guide rollers 51 installed on the sides of each profiled screening segment 49, rolling in the guide profiles 52 installed on the anchoring profiles 18 of the base section skeleton sections 4.

The workspace of the technology section 8 is formed by a group of, for example, four heat pumps 53 anchored in the technology frame 27 via flexible vibration-damping members 70 to adjacent structures formed by internal processes of the heat pump component 53 installed at defined positions on the anchoring base 69 disassembly or replacement of the entire heat pump unit 53. The partial heat pumps 53 are provided at their rear side with a supply line 67 through which low-pressure refrigerant flows into a defined outlet of a pair of opposing outlet tubes 6 where it extracts heat from the environment by utilizing latent heat during evaporation. at low temperatures, the refrigerant passes from the liquid to the gaseous phase. The vapor phase coolant flows back through the return line 68 to the heat pump 53, while the supply and return lines 67, 68 on their trajectory pass through a removable duct 33 which hermetically isolates sub-regions of the individual sections. The collected low temperature energy of the environment is transformed by the heat pump 53 to the high temperature, which is transferred via the plate condenser 56 to the inner circuit of the heating medium, which flows through the outlet pipe 54 into the plate condenser 56. the inlet sleeve 55 of the insulated process tank 58, which accumulates the necessary thermal potential eliminating both the impacts of the offtake of the offtake point and the need for reverse operation of the technology. The insulated process tank 58 is equipped with a pressure sensor 60 and a plurality of temperature sensors 61 connected to a control system located in an adjacent enclosure 63 for monitoring system functions, and the isolated process tank 58 is equipped with a plurality of electric heaters 62 to eliminate possible decreases in medium temperatures during system downtime. The heating medium further flows back through the inner circuit via an inlet pipe 64 with a circulating pump 65 installed, through which the heating medium is circulated between the heat pump 53 and the insulated process tank 58. The heating medium accumulated in the insulated process tank 58 is via the inlet and return flanges 59, shut-off fittings 66 and removable piping segments 31 are connected to an external heating circuit of the supply point, wherein shut-off fittings 66 and removable piping segment 31 allow shutdown of the system with subsequent dismantling of the removable piping segments 31, eliminating overlapping clearance dimensions for transport.

The multi-functional mobile container monoblock 7 coupled to the transport platform 3 allows a flexible relocation of the system by a conventional truck with a defined superstructure allowing the loading and unloading of the transport platform 3 structure by gripping a pull hook 76 installed at a defined position of the front structure 75 with partial reinforcement 77 of the stressed areas. The forehead 75 extends to the base support frame 72 with a plurality of center stiffeners 73 installed to provide the deformation stability of the transport platform 3, inferred by the implementation of the multifunctional mobile container monoblock 1 via an anchoring mechanism 74 installed at the ends of the support profiles 74. rollers, which allow for a process of storage requiring angular stretching of the multifunctional mobile container monoblock 1 with translational movement in the vehicle axis.

-7 GB 307908 B6

Industrial applicability

The solution relates to a multifunctional mobile container monoblock of a complex heat pump system linked to a transport platform allowing flexible transport, which raises beyond comparable applicability in common applications and at the same time an innovative approach in the form of extended alternative energy sources especially in areas where economically adequate rate of investment and potential return on conventional technology. The design solution of the mobile geothermal monoblock with its own heat pump system situated in the technology section and the associated pairs of implemented counterparts situated in alternative positions of the first and second pumping sections has sufficient heating and cooling capacity not only to supply the created background within unexpected events caused by environmental events utility potential and advantages can be applied especially in common situations and planned events with a short-term horizon of local dwelling, which can include various expeditions, cultural and other gatherings situated in makeshift roofing, heating, cooling and water heating accommodation facilities for workers at local workplaces linear structures or similar types of ever-expanding makeshift structures that do not have the technical facilities in worthy to install technology.

PATENT CLAIMS

Claims (4)

Multifunctional mobile container monoblock of a complex heat pump system linked to a transport platform, characterized in that it consists of a basic supporting skeleton (4) divided into separate sections, wherein the first discharge section (5) is fitted with a pair of opposing discharge pipes (6), the second discharge section (7) is fitted with a pair of opposing discharges (6) and the third technological section (8) is fitted with a heat pump system (2), the basic supporting skeleton (4) being formed from the upper situated lifting segments (9) and profiles (10) provided in the area of the ceiling structure of the flue sections (5), (7) by installation cut-outs (11) for the installation of shielding and control technology (12) of air currents with adjoining face sheet (13); axial fans (15) with central reinforcement (16) of the roof fan segment The boundaries of the sub-sections (5), (7), (8) are mutually defined by means of anchoring profiles (18), wherein the floor part of the flue sections (5), (7) of the basic support frame (4) is fitted a plurality of shaped crossbeams (19) adjoining the floor member A (20) of the second discharge section (7), wherein the floor portion of the base support skeleton (4) of the technology section (8) is symmetrically fitted in the ceiling and floor area the straight sections (21), which are connected to the roof segment (22) and the floor plate (23) of the technology section (8) and the basic support frame (4) is fitted with an additional anchoring profile (18) in the front part of the technology section (8), connected to the entrance door (24) of the technology section (8), the peripheral penetrations of the technology section (8) are further equipped with a removable sheathing A (25) anchored by means of clamps (26) through the frame (27) of the heat pump system (2) technology, a removable sheath B (28) anchored to the base skeleton elements (4), and a removable sheath C (29) with a plurality of insulated passages (30) (31) a heating medium supply pipe (67) and a return line (68) and a cable conduit which is anchored to the basic supporting skeleton (4), the technology section (8) being separated from the adjacent second discharge section (7) by a technological partition (32) with a removable pipeline partition (33) for conducting refrigerant The conduit (34) of the heat pump system (2) to the pair of opposing bumps (6) is provided, wherein the second discharge section (7) with the pair of opposing bumps (6) is provided with an angle filler (35) abutting the anchoring profiles (18). a base skeleton (4) and a pair of opposing stems (6), anchored in its lower part to the floor crossbeams (19) through the floor panel A (20) by means of a floor anchoring segment (36) to which further from the outside adjoins the condensate drain segment (37) and, at the same time, the inner walkable sheet (38) with the adjoining removable piping partition (33) of the refrigerant piping (34) of the first discharge section (5), an outer profile (10) by means of a ceiling anchoring segment A (39), the expensive discharge section (7) and the first discharge section The metal section (5) is separated from one another in the inner space by a metal module partition (40) abutting a pair of opposing bumps (6), the metal module partition (40) being provided with a revision passage with a door segment (41) installed in its center. the opposite bumps (6) of the first bead section (5) is anchored in the lower part to the floor panel B (42) with a mounting penetration fitted with a revision cover (43) which is anchored to the shaped floor cross beams (19); 6) is further anchored in its upper part to the outer profile (10) by means of ceiling anchoring segment B (44), the first outlet section (5) is fitted from the front with a group of removable wall modules (45) anchored to the basic supporting skeleton (4) wherein the shielding and control technology (12) installed in the installation cut-outs ( 11) The outer profile (10) of the ceiling structure of the parquet sections (5), (7) is formed by a plurality of flexible holders (46) of the upper support profile (47), in which the drive (48) is installed. anchored to the partial profiled screen segments (49) and the lower support profile (50), each profiled screen segment (49) being provided with a guide roller (51) adjoining the guide profiles (52) installed in the anchoring profiles (18) of the basic support a skeleton (4), wherein the assembly of the heat pump system (2) comprises a plurality of heat pumps (53) situated in a technology frame (27) anchored to the floor plate (23) and straight profiles (21) 4), where the partial heat pumps (53) are provided on their rear side with an outlet socket (54) and an inlet socket (55) of a plate capacitor (56), to which the outlet pipe (57) facing the insulated process tank (58) is equipped with inlet sleeves (55) and outlet sleeves (54) and heating circuit inlet and return flanges (59), the insulated process tank (58) is further equipped with pressure sensor technology elements (60), temperature sensors (61), and electric heating elements (62), which are connected to a control system situated in the switch cabinet (63), the inlet pipe (64) fitted with a circulation pump (65) adjoining the outlet nozzles (54) the insulated process tanks (58) are directed spatially to the inlet nozzle (55) of the plate capacitor (56), wherein the inlet and return flanges (59) of the insulated process tank (58) heating circuit further synchronously connect to shut-off valves (66) and removable piping segments ( 31) fitted with temperature sensors (61), while the partial heat pumps (53) are further provided with a coolant circuit supply line (67) extending through the removable piping partition (33) to connect the blast supply line of a pair of opposing bumps (6), with a coolant return line (68) extending along an identical trajectory through the removable line partition (33). to said heat pump (53), the heat pump components (53) being mounted on an anchor (69) mounted via resilient members (70) into the technology frame (27), wherein the transport platform (3) coupled to a multifunctional mobile container monoblock (1) by means of an anchoring mechanism (71) it is formed by a basic supporting frame (72), which is connected along the whole length by continuous central stiffeners (73), with supporting profiles (74) with an anchoring mechanism installed at the end (71) multifunctional mobile container The front part of the transport platform (3) is further equipped with a front structure (75) with an installed pulling hook (76) and The rear part is provided with a roll system (78) secured by a pin which is anchored to the elements of the support profiles (74). 2. Multifunctional mobile container monoblock of a complex system of heat pumps s 5 by binding to the transport platform according to claim 1, characterized in that the first discharge section (5) is fitted with a pair of opposing disks (6) in a vertical position. Multifunctional mobile container monoblock of a complex heat pump system coupled to a transport platform according to claim 1, characterized in that the second discharge section 10 (7) is fitted with a pair of opposing discharges (6) in an inclined position. Multifunctional mobile container monoblock of a complex heat pump system linked to a transport platform according to claim 1, characterized in that the heat pump system assembly (2) consists of a group of four heat pumps (53).