CH720148B1 - Building with ventilation unit - Google Patents

Abstract

A building (1) according to the invention comprises several building parts (2), each with at least one sensor (8) for measuring at least one parameter of the air in the building part (2). The building (1) also has at least one ventilation unit (3) for ventilating at least one of the building parts (2). The at least one ventilation unit (3) comprises at least one inside opening arranged on an inside (4) of the building part (2), which is fluidically connected to an outside opening arranged on an outside of the building part, so that air can flow between them. A control unit (9) is connected to the at least one ventilation unit (3) and to the at least one sensor (8) of a building part (2) via a communication network (10), wherein the control unit (9) is designed to receive measured values from the at least one sensor (8) and, based thereon, to transmit control instructions to the at least one ventilation unit (3), so that the parameters of the air in the building part (2) are influenced by ventilating the respective building part (2) with the ventilation unit (3).

Description

[0001] The present invention relates to a building comprising at least one building part and at least one ventilation unit for ventilating the building part.

[0002] The current state of the art includes various approaches to ventilating buildings. The known systems usually do not have sufficient means of monitoring the air condition, especially in real time, or offer only limited control options. If the exact condition of the air in the building is not precisely recorded, this can lead to inadequate ventilation. Pollutants, odors and moisture cannot be effectively removed, which can lead to poor air quality. Another disadvantage concerns energy efficiency. Without precise control, ventilation may run at a constant level even when it is not necessary. This leads to unnecessary energy consumption and higher costs. Another limitation concerns the adaptability of the ventilation. Known ventilation systems often cannot respond flexibly to changes in room conditions. This can lead to suboptimal ventilation, especially when the CO2 concentration increases or the humidity suddenly rises.

[0003] Traditional systems also often use central ventilation systems, but central building ventilation has some disadvantages, in particular the ventilation system is designed for the entire building. This means that some rooms may be under-ventilated while others are over-ventilated. This can lead to uneven air flow and uneven temperature distribution. There are also some disadvantages to installing a central ventilation system. For example, such a system requires a special room that is large enough to accommodate the equipment. In addition, a pipe system is necessary to distribute the air that is centrally exchanged with the environment throughout the building. The maintenance and cleaning of the pipe system also requires regular attention and incurs additional costs. In addition, the pipe system of a central ventilation can affect the design and construction of the building, as it requires corresponding space in the building, for example in the ceilings.

[0004] One object of the invention is to provide a building that has energy-optimized and efficient ventilation. This object is achieved by the building defined in the independent patent claim. Further advantageous embodiments are listed in the dependent claims.

[0005] In contrast to traditional ventilation, in which the air is fed into the building based on fixed presets and guided through a system of pipes to the various areas of the building, the present invention enables precisely controlled ventilation in individual parts of the building. This allows the air flows in each part of the building to be regulated and optimized separately in order to achieve greater energy efficiency and an improved indoor climate. In particular, the use of sensors to measure air quality enables one or more control units to individually control the ventilation in the corresponding part of the building, resulting in more efficient and targeted ventilation.

[0006] A building according to the invention comprises several building parts, each with at least one sensor for measuring at least one parameter of the air in the building part. The building also has at least one ventilation unit for ventilating at least one of the building parts. The at least one ventilation unit comprises at least one inside opening arranged on an inside of the building part, which is fluidically connected to an outside opening arranged on an outside of the building part, so that air can flow between them. A control unit is connected to the at least one ventilation unit and to the at least one sensor of a building part via a communication network, wherein the control unit is designed to receive measured values from the at least one sensor and to transmit control instructions to the at least one ventilation unit based thereon, so that the parameters of the air in the building part are influenced by ventilating the respective building part with the ventilation unit.

[0007] The (decentralized) ventilation units according to the invention can be used in particular in Minergie and passive houses, as they offer a decisive advantage: They enable individual rooms to be ventilated as needed, thus contributing to energy efficiency. Since hardly any heat can be lost in these buildings due to the high level of insulation and airtightness, controlled ventilation is essential to ensure a healthy indoor climate. With decentralized ventilation units, ventilation can be controlled individually in each room without the need for a central ventilation system with air distribution pipes. This not only saves space, but also reduces installation costs and energy consumption.

[0008] A part of a building within the meaning of the present disclosure can be understood as, among other things, a floor, a residential unit (apartment) or a room.

[0009] In one embodiment, the ventilation unit comprises a driven means for the local conveyance of air between the inside opening and the outside opening. The driven means for the local conveyance of air is in particular a fan. This allows the ventilation unit to move the air independently in a certain direction and thus, for example, improve the air quality in the room. By using a driven means, the ventilation unit can be more effective than passive ventilation.

[0010] In a further embodiment, at least one ventilation unit is provided per building part for ventilating the at least one building part and the building is in particular free of connecting ducts to a central air exchange means that centrally ventilates several building parts. The absence of connecting ducts reduces the risk of blockages and other problems and reduces the need for maintenance and cleaning of these ducts. Avoiding connecting ducts saves space and costs when constructing the building and allows residents to individually control the air quality in their rooms.

[0011] In a further embodiment, a building part comprises at least two ventilation units and the control unit is set up to transmit control instructions for counter-rotating operation to the at least two ventilation units of a building part, so that air is conveyed from the outside into the building part by a first ventilation unit and air is conveyed from the building part to its outside by a second ventilation unit. The counter-rotating operation enables a continuous air flow that regulates the air quality in the building more effectively than a simple ventilation unit.

[0012] In a further embodiment, the at least one ventilation unit is integrated into a building element. The building element can in particular be a wall element, a facade element or a window element. By integrating the ventilation unit into the building element, it can be placed discreetly and unobtrusively so that the appearance of the building is not impaired. Furthermore, the ventilation unit can be pre-assembled in the respective part of the building before it is installed in the building. This speeds up the construction of the building because fewer installation steps are required on site.

[0013] In a further embodiment, the communication network comprises a wireless communication network. Wireless communication enables data to be transferred quickly and easily between different components of the system. Furthermore, wireless communication simplifies the installation and maintenance of the system, since no cabling is required. In addition, other components, such as control units, can also be integrated later.

[0014] In a further embodiment, the parameter measured by the sensor is at least one of the following: air temperature, CO2 concentration, humidity, particle concentration, CO concentration or VOC concentration, or a combination of the above. By measuring these parameters, the system can monitor the state of the environment and the air quality in the respective part of the building (in real time) and react accordingly. For example, if the CO2 concentration is high, it can increase the ventilation of the room to ensure the CO2 concentration and a healthy environment.

[0015] In a further embodiment, the building comprises at least one energy generation plant for generating and supplying electrical energy, in particular a photovoltaic system, as well as an electrical energy distribution system for distributing the electrical energy supplied by the electrical energy generation plant to one or more consumers, in particular to the at least one ventilation unit, and a central energy management unit which is connected to the at least one energy generation plant and/or the electrical energy distribution system by means of the communication network for controlling the operation of the at least one energy generation plant and the energy distribution system.

[0016] In a further embodiment, the electrical energy distribution system can be connected to a public power grid, wherein the electrical energy distribution system is set up to receive generation information from the at least one energy generation plant, wherein the generation information in particular comprises electrical power. Furthermore, the electrical energy distribution system is set up to receive consumption information from the one or more consumers, wherein the consumption information in particular comprises electrical power. Furthermore, the central energy management unit is set up to receive generation information and consumption information from the electrical energy distribution system and, based thereon, to control the intake of electrical energy from the public power grid, in particular when the electrical power of the energy generation plant is lower than the electrical power of the consumers. This enables efficient distribution of the electrical energy generated by the energy generation plants to the consumers.

[0017] The central energy management unit can also effectively regulate the consumption of electrical power from the public power grid to ensure that consumers are supplied with sufficient electricity at all times. In this way, the consumption of locally generated electrical energy can be prioritized before energy is drawn from the public power grid. Finally, the integration of generation and consumption information enables better planning and optimization of the power grid.

[0018] In a further embodiment, the building comprises a storage device for storing electrical energy, wherein the storage device in particular comprises at least one battery, and wherein the central energy management unit is set up to control the withdrawal and delivery of electrical energy from/to the storage device. In particular, if the electrical output of the energy generation plant is less than the electrical output of the consumers, the withdrawal of electrical energy from the storage device is controlled; and if the electrical output of the energy generation plant is greater than the electrical output of the consumers, the delivery of electrical energy to the storage device is controlled.

[0019] Aspects of the invention are explained in more detail with reference to the exemplary embodiments shown in the following figures and the associated description. They show: Fig. 1 a schematic cross section of a building 1 according to the invention; Fig. 2 a building part 2 in the form of a facade element 11 comprising a window; and Fig. 3 a schematic cross section of a wall element with a ventilation unit.

[0020] Figure 1 shows a building 1 according to the invention comprising at least one building part 2, each with a ventilation unit 3. The building shown comprises three building parts 2. The building parts 2 each have an inner side 4 and an outer side 6. The ventilation unit 3 is designed to circulate the air in the building part 2 and has an inner opening 5 and an outer opening 7 to enable air exchange between the inside and outside areas. As can be seen in Figure 3, a fan 13 can be provided for the ventilation unit to move the air between the inner opening 5 and the outer opening 7.

[0021] As can be seen in Figure 1, the building parts 2 are each one storey.

[0022] At least one sensor 8 is provided for measuring at least one parameter of the air in the building part. Furthermore, a control unit 9 is provided, which is connected to the ventilation units 3 of at least one building part via a communication network 10. The communication network 10 allows the sensor 8, the control unit 9 and other systems to communicate with each other and exchange data. The sensor 8 is able to measure various parameters in the building part 2, e.g. air temperature, CO2 concentration, air humidity, particle concentration, CO concentration or VOC concentration, or a combination of the above. The control unit 9 is able to control the ventilation unit 3 according to the measured parameters and to influence and/or optimize the air quality in the building part 2.

[0023] Figure 2 shows a facade element 11. In this embodiment, the facade element 11 comprises two ventilation units 3, which are at least partially integrated into the frame of a window in order to regulate the climate in the building part.

[0024] Preferably, as shown in Figure 1, the building 1 has at least one energy generation system 12, such as a photovoltaic system 12, which is able to generate electrical energy and feed it into the energy distribution system 14. The energy distribution system 14 is able to supply the generated electrical energy to one or more consumers 15 in the building 1. A central energy management unit 16 can control and optimize the operation of the energy generation system 12 and the energy distribution system 14. The energy management unit 16 of the building 1 prioritizes the consumption of solar power generated by the energy generation system 12. If the consumption of the building 1 exceeds the power generated by the photovoltaic system 12, the energy management unit 16 obtains the additional power from the public grid, which is accessible via the energy distribution system 14. The energy management unit 16 monitors the energy consumption of building 1 and ensures that solar power is used preferentially to cover the electricity consumption of building 1.

[0025] A storage device 17, such as a battery, can help to store excess energy and retrieve it when needed. Overall, this building 1 offers many opportunities to increase energy efficiency and improve indoor air quality.

LIST OF REFERENCE SIGNS

[0026] 1 building 2 building part 3 ventilation unit 4 inside (building part) 5 inside opening (ventilation unit) 6 outside (building part) 7 outside opening (ventilation unit) 8 sensor 9 control unit 10 communication network 11 facade element 12 energy generation system (photovoltaic system) 13 fan 14 energy distribution system 15 consumer 16 energy management unit 17 storage device (battery)

Claims (9)

1. Building (1) comprising: a. several building parts (2), each with at least one sensor (8) for measuring at least one parameter of the air in the building part (2); b. at least one ventilation unit (3) for ventilating at least one of the building parts (2), wherein the at least one ventilation unit (3) comprises at least one inside opening (5) arranged on an inside (4) of the building (1), which is fluidically connected to an outside opening (7) arranged on an outside (6) of the building (1), so that air can flow between them, and c. a control unit (9) which is connected to the at least one ventilation unit (3) and to the at least one sensor (8) of a building part (2) via a communication network (10), wherein the control unit (9) is designed to i. receive measured values from the at least one sensor (8) and ii. based thereon, to transmit control instructions to the at least one ventilation unit (3) so that the parameters of the air in the building part (2) are influenced by ventilating the respective building part (2) with the ventilation unit (3). 2. Building (1) according to claim 1, wherein the building (1) comprises the following: a. at least one energy generation system (12) for generating and supplying electrical energy, wherein the energy generation system (12) is in particular a photovoltaic system (12); b. an electrical energy distribution system (14) for distributing the electrical energy supplied by the at least one electrical energy generation system (12) to one or more consumers (15), in particular to the at least one ventilation unit (3); and a central energy management unit (16) which is connected to the at least one energy generation system (12) and/or the electrical energy distribution system (14) by means of the communication network (10) for controlling the operation of the at least one energy generation system (12) and the electrical energy distribution system (14); c. wherein the electrical energy distribution system (14) can be connected to a public power grid and d. wherein the electrical energy distribution system (14) is configured to receive generation information from the at least one energy generation plant (12), wherein the generation information in particular comprises electrical power; e. and wherein the electrical energy distribution system (14) is further configured to receive consumption information from the one or more consumers (15), wherein the consumption information in particular comprises electrical power; f. and the central energy management unit (16) is configured to receive generation information and consumption information from the electrical energy distribution system (14) and, based thereon, to control the intake of electrical energy from the public power grid, in particular when the electrical power of the energy generation plant (12) is lower than the electrical power of the consumers (15). 3. Building (1) according to claim 2, wherein the building (1) comprises a storage device (17) for storing electrical energy, wherein the storage device (17) in particular comprises at least one battery (17), and wherein the central energy management unit (16) is set up to control the extraction and delivery of electrical energy from or to the storage device (17), in particular a. when the electrical power of the energy generation system (12) is less than the electrical power of the consumers (15), the extraction of electrical energy from the storage device (17); and b. when the electrical power of the energy generation system (12) is greater than the electrical power of the consumers (15), the delivery of electrical energy to the storage device (17). 4. Building (1) according to one of the preceding claims, wherein the communication network (10) comprises a wireless communication network (10). 5. Building (1) according to one of the preceding claims, wherein the parameter measured by the sensor (8) is at least one of the following: a. air temperature; b. CO2 concentration; c. air humidity; d. particle concentration; e. CO concentration; and f. VOC concentration. 6. Building (1) according to one of the preceding claims, wherein at least one ventilation unit (3) is provided per building part (2) for ventilating the at least one building part (2) and the building (1) is free of connecting ducts to a central air exchange means which centrally ventilates several building parts (2). 7. Building (1) according to one of the preceding claims, wherein the ventilation unit (3) has a driven means (13) for locally conveying air between the inside opening (5) and the outside opening (7), in particular a fan (13). 8. Building (1) according to one of the preceding claims, wherein a building part (2) comprises at least two ventilation units (3) and the control unit (9) is set up to transmit control instructions for counter-rotating operation to the at least two ventilation units (3) of the building part (2), so that air is conveyed from the outside (6) into the building part (2) by a first ventilation unit (3) and air is conveyed from the building part (2) to its outside (6) by a second ventilation unit (3). 9. Building (1) according to one of the preceding claims, wherein the at least one ventilation unit (3) is integrated into a building element, in particular into a wall element, into a facade element (11) or into a window element.