BG66192B1 - Solar energy application for hot water residential supply and air heating in a modular medical unit (operation theatre) in extreme situations - Google Patents

Abstract

The invention shall find application in the construction of temporary medical modules (operation theatres) in extreme situations with facilities for longer maintenance of constant temperatures in thehot water vessels, as well as for air heating due to the hothouse effect formed at the angular installation spaces. The water collectors (18) have collector coil (28) and are connected from below with a lower horizontal tube (29), and in its upper end û to an upper horizontal tube (27), one of the ends of which is connected to a vertical tube with lower circulation pump (5). The latter is furtherconnected to a lower horizontal accumulation tube (36), connected to accumulation coils (2), connected to an upper horizontal accumulation tube (37), connected to the upper circulation pump (1), and it, on its turn, - to the other end of the lower tube (29). Coils (2) are fitted in first hot water vessels (4) the walls of which are resting to second vessels (3) for rain water, and a blast fan (32) is fitted in the heat-insulation wall (11) to the first angular installation space (8) at a level over the suspended ceiling (38). On the same level, but at the second angular installation space (12), in the other perpendicular heat insulation wall (11) an exhaust fan (33) is found, connected by means of a short duct (39) with the environment.

Description

Field of application

The invention relates to an energy-autonomous modular medical unit and will find application in the construction of modular medical units (operating rooms) in extreme situations.

BACKGROUND OF THE INVENTION

There is a known system for the air-conditioning and power supply of buildings, using renewable energy sources, which uses a photovoltaic solar collector, which provides electricity to the electricity system from batteries and consumers, and at the same time heats a water collector connected by a pipe system and a circulating pump from non-freezing heat exchanger, hot water accumulator and hot water consumers / 1 /.

There is also a technical solution where the heating of the heat carrier (antifreeze) is carried out in a solar collector, and the heat is transferred through a heat exchanger into a hot water accumulator and from it to consumers. The circulation of the heat carrier in the circuit for the conversion of solar energy into heat is effected by a pump / 2 /.

In known solutions:

- hot water storage batteries do not provide for a longer maintaining of a constant temperature in them;

- there is no increased volume for heating the air by forming angular insulation spaces leading to enhanced greenhouse effect.

SUMMARY OF THE INVENTION

It is an object of the invention to provide an energy-autonomous modular medical unit whose hot water batteries are to be stored in rainwater-filled vessels to provide a longer temperature constant therein; the block should be of increased total useful volume for heating the air by forming angular insulation spaces leading to enhanced greenhouse effect.

An energy-autonomous modular medical unit with a known system for the air-conditioning and power supply of buildings, using renewable energy sources, using a photovoltaic solar collector, providing electricity to a power system from a battery and consumers, and at the same time heating a water collector and connected via a water collector system in a circulating circuit of a non-freezing heat exchanger, hot water battery and hot water consumers.

Also known is the heating of the heat carrier (antifreeze), carried out in a solar collector, and the heat is transmitted through a heat exchanger to a hot water accumulator, and from it to consumers, the circulation of the heat carrier in the circuit for the conversion of solar energy into heat. pump.

The piping system is made of rechargeable coils located in the first hot water tanks whose walls are adjacent to the second rain water vessels. The uppermost part of the first vessels through a pipe is connected to the faucets of the washbasins located next to the energy radiating wall in the operating room.

The operating room is located between thermal insulation walls, in front of which is formed the first angular installation space, the second angular installation space, which angular spaces are connected with the spaces of the exit from the operating room to the patient hospital and the exit of the intensive care unit and the entrance to the preoperative room the anesthetic. An injection fan is located in the thermal insulation wall next to the first corner installation space at a level above the suspended ceiling. At the same level, but at the second angular installation space in the other perpendicular thermal insulation wall there is a suction fan connected via a short channel to the environment, with the spaces of exits and entrances formed behind transparent walls.

The accumulator coils are once connected to a lower horizontal accumulator tube fitted with a lower circulation pump, and a second time to an upper horizontal

66192 Bl accumulator tube connected to the upper circulation pump connected to the other end of the lower tube.

The lower circulation pump via a vertical pipe is connected to one end of an upper horizontal pipe, serving collector coils that are still connected to a lower horizontal pipe, and the coils are connected to the water collectors.

In the first corner installation space there is an electric battery connected to photovoltaic batteries located on the horizontal part of the roof.

Advantages of the invention are:

- hot water storage tanks housed in rainwater-filled vessels ensure that they are maintained at a constant temperature for a longer period;

- the total useful volume for the heating of the air has been increased by the formation of bulk insulation spaces leading to an enhanced greenhouse effect.

Explanation of the annexed figures

An exemplary embodiment of the invention is shown in the accompanying drawings, wherein:

Figure 1 is a plan view of the modular operating unit;

FIG. 2 is a section through AA of FIG. 1; 3 is a sectional view on BB of FIG. 1; figure 4 - plan of the roof.

An exemplary solution of the invention An exemplary solution of the invention is shown in the accompanying figures 1-4.

According to FIG. 1, access to operating room 15 is via the ramps 17. From operating room 15, there is one exit 17th to the patient hospital and a second exit 7 leading to the intensive care unit. Entrance 14 provides access to the preoperative and anesthesia room 40. Exits 7,17-a and entrance 14 are connected through doors by two angular installation spaces 8 and 12. An electric accumulator is located in the corner space 8. Highly in the heat-insulating wall 11 is a blower fan 32 supplying warm air to the enclosed space. above the suspended ceiling 38. Above the second angular installation space 12 there is a short pipe duct 39, which exhausts the exhaust air from the operating room 15 via the suction fan 33. A heat insulating curtain 6 separates the lower circulation pump 5 from the installation space formed in front of it. The washbasins are suspended from the energy-emitting wall 34, resting against the rainwater vessels 3. In these vessels 3 there are other vessels for hot water 4. In the vessels 4 there are accumulator coils 2 connected in a tubular system A with the lower circulation pump 5 and with the upper circulation pump 1. The transparent walls 10 are suspended on supporting angular columns 16 and on columns 9 and the inner thermal insulation walls 11 are suspended on other columns 13. Excess rainwater from the vessels 3 is removed by overflow 24. Access to the roof is via an external staircase 23.

According to FIG. 2, the accumulator coils 2 are located in the hot water tank 4 and are connected to a lower horizontal storage tube 36 and an upper horizontal storage tube 37. The water collectors 18 are arranged on a horizontal roof plate 30. Rainwater flows to the vessels 3 along the sloping roof Plate 20. Photovoltaic batteries 25 provide electricity for artificial lighting and other photovoltaic batteries 19 for propulsion of circulation pumps 1 and 5. The discharge fan 32 supplies heated air from the installation. In the space above the suspended ceiling 38 of the operating room 15. Under the operating room 15, a second floor 21 is formed for the location of the technical and medical infrastructure. The floor 21 is located on a ballast bed 22.

According to FIG. 3, the water collectors 18 are disposed on a horizontal roof plate 30 and are provided with a collector coil 28. They are connected below by a lower horizontal pipe 29 and at its upper end by an upper horizontal pipe 27. One end of the upper pipe 27 is connected to a vertical lower circulation pump 5. The lower circulation pump 5 is also connected to a lower horizontal accumulator pipe 36 connected to the accumulator coils 2 connected to an upper horizontal accumulator pipe 37 which is connected to the upper circulation pump 1. This pump 1 is tied with

66192 Bl the other end of the lower pipe 29. The accumulator coils 2 are located in first hot water vessels 4 whose walls are adjacent to second rain water vessels 3. The uppermost part of the water of the first vessels 4 through a pipe is connected to the faucets of the washbasins located next to the power radiating wall 34 in the operating room 15. The ramps 17 are protected by visors 31.

According to FIG. 4, the upper circulation pump 1 and the water collectors 18 are located on the roof plate 30. The lower circulation pump 5 is located at the level of the operating room 15. The photovoltaic batteries 25, which provide electricity for artificial lighting, are located on horizontal roof plates above the exits 7 and 17, and the other photovoltaic batteries 19 to drive the circulation pumps 1 and 5 are located on a horizontal floor plate above the patient inlet.

Application (use) of the invention

The invention will find application in the construction of temporary operating rooms, used in extreme situations.

Operation of the domestic hot water supply system

Rainwater in receptacles 3 is collected by flowing it down the inclined plate 20, removing excess water from overflow 24. This rainwater serves to maintain a more uniform temperature of hot water in receptacles 4. Domestic water in warm containers water 4 is from the water supply network come from another water source. This water is heated by the heat carrier - water with antifreeze passing through the battery coils 2. These coils 2 are connected in series with a pipe network and two circulation pumps 1 and 5, which transfer the heat carrier to the collector coil 18, where they are heated by the sun's rays. The warm water from the top of the vessels 4 goes down the pipe to the faucets of the sinks for domestic consumption. At night, the containers 3 are covered with thermal insulation screens.

Operation of the electric lighting system

The photovoltaic batteries 25 located on the horizontal part of the roof transform the solar energy into electrical energy, which is accumulated in the electric accumulator 26, located in the first corner installation space 8. The electricity is used primarily for artificial lighting in the operating room.

Air heating system operation

The warm air from the first corner installation space 8 is fed into the space above the suspended ceiling 38 by operation of the discharge fan 32 in operation room 15. With the suction fan 33, the exhaust air from operating room 15 is later discharged into the environment.

The energy-emitting wall 34, as it is directly restrained to the vessels 3, takes away some of the heat stored therein and supplies it for indirect heating to the operating room 15.

Claims (3)

Claims 1. Energy-autonomous modular medical unit with a known system for the air-conditioning and power supply of buildings through renewable energy sources, using a photovoltaic solar collector, providing electricity to the electric power system from a battery and consumers, and at the same time heating a water collector and connected through a water collector system pump in the circulation circuit of a non-freezing heat exchanger, hot water storage tank and hot water consumers, as well as some heating of the heat carrier, and in the solar collector, and the heat is transmitted through a heat exchanger into a hot water accumulator and from it to consumers, the circulation of the heat carrier in the solar energy to heat conversion circuit is effected by a pump, characterized in that the pipe system (A) has accumulator coils (2) located in first hot water vessels (4) whose walls are adjacent to second rain water vessels (3), with the uppermost part of the first vessels (4) through a pipe being connected to the faucets of the washbasins located next to the power beam Item wall (34) in the operating room (15), the operating room (15) is disposed between the heat-insulating walls (11), with which 66192 Bl is a first angular installation space (8), a second angular installation space (12), which angular spaces (8,12) are connected to the exits from the operating room (15) to the patient hospital (17-a) and with an outlet (7) for the intensive care unit and with an inlet (14) for the preoperative and anesthetic (40), a discharge fan (38) is located in the thermal insulation wall (11) up to the first corner installation space (8) above the suspended ceiling (38). 32), and at the same level, but at the second corner installation space in d a perpendicular thermal insulation wall (11) is arranged a suction fan (33) connected via a short channel (39) to the environment, the spaces of the exits (7, 17-a) and the inlets (14) being formed behind transparent walls (10) . An energy-autonomous modular medical unit according to claim 1, characterized in that the accumulator coils (2) are once connected to a lower horizontal accumulator tube (36) equipped with a lower circulation pump (5) and secondly to an upper horizontal accumulator tube (37) connected to the upper circulation pump (1) connected to the other end of the lower tube (29), the lower circulation pump (5) being connected to one end of the upper horizontal tube (27) by a vertical tube servicing collector coils (28) which o will be connected to the lower horizontal pipe (27) and the coils (28) will be connected to the water collectors (18). 3. An energy-autonomous modular medical unit according to claim 1, characterized in that in the first corner installation space (8) there is an electric accumulator (26) connected to photovoltaic batteries (25) located on the horizontal part of the roof. Attachment: 4 figures