CH718626A1 - NFC-enabled HVAC field device and HVAC system. - Google Patents

Abstract

The invention relates to an HVAC field device (200) which comprises a plurality of HVAC device blocks (201, 202). The HVAC field device (200) comprises: a) a base HVAC device block (201) comprising: a base housing (203); an electric motor (205) configured to drive a driven element and/or a sensor to measure an operating parameter of an HVAC system; a base control module (207) connected to the electric motor (205) and/or the sensor; a base near field communication NFC circuit (208) connected to the base control module (207); and b) a first add-on HVAC equipment block (202) comprising: an add-on housing (204) and a first add-on NFC antenna (210), wherein the base HVAC equipment block (201) and the first add-on HVAC equipment block (202) are mechanically connected, and wherein the first add-on NFC antenna (210) is electrically connected to the base HVAC equipment block (201).

Description

field of invention

The present invention relates to HVAC field devices for heating, ventilation and air conditioning, and in particular to HVAC devices and systems which have means of near-field communication NFC.

Background of the Invention

[0002] HVAC systems include a plurality of consumers, which are distributed in branches or line sections and which are supplied with a liquid or gaseous medium (fluid). In order to achieve a desired distribution of the fluid to the consumer, leveling, regulating or balancing units, for example adjustable actuated control and regulating elements such as valves and flaps, are provided, with the flow rate being adjusted by special consumers using openings of different sizes or valve and flap settings becomes. Mechanical control of the actuated parts is provided by HVAC actuators such as motorized HVAC actuators connected to the actuated part. In the field of heating, ventilation, and air conditioning (HVAC), actuators typically include an electric motor connected (via gears and/or other mechanical coupling) to the actuated part. HVAC actuators are electrically controlled by HVAC control devices, in particular by an electronic circuit of the same. In addition, various sensors are used to measure environmental parameters such as humidity, temperature or air quality. For example, an air quality sensor can be a sensor for determining a proportion of carbon dioxide or certain pollutants in the air flow, in particular fine dust particles. Additionally, HVAC sensors can be used to determine operating parameters of various elements of an HVAC system, such as a set position of a driven element and the operating state of an HVAC actuator. Other important types of sensors are sensors for measuring a flow rate of a fluid and pressure sensors.

In such HVAC configurations, the regulating and balancing units must also have individual parameter settings. Certain individual parameters of regulation and balancing units of an HVAC system must be provided for immediately during the installation of the regulation and balancing unit. Individual parameters of the regulating and compensating units can thus be set, for example by turning the position of a potentiometer with a screwdriver or by connecting and operating a service tool via a service socket.

[0004] Certain control functions of HVAC systems can be performed from a remote server, where the remote server includes a computer program such as a building management system (BMS) for controlling, regulating, and monitoring the mechanical and electrical services of a building. Certain functions, in particular the commissioning and/or configuration of HVAC systems, can also be carried out via portable devices such as a universal mobile computing device (e.g. a smartphone) or an application-specific configuration tool.

U.S. Patent No. 7898147 shows an electronically configurable actuator. The actuator includes an electrically controllable mechanical transducer, a wireless interface for receiving data related to the operation of the actuator and at least one external device thereof, a settings data module for storing the data, a wired interface for data-based management of external devices, and a control module for Control of the mechanical converter according to the data. The wireless interface is set up for the transmission of radio-based, optical or acoustic signals, for example in accordance with a standard such as Bluetooth, IrDA, IEEE 802.11 (WLAN), etc., or in accordance with a mobile communication technology. Data can be prepared on a portable computer, personal digital assistant (PDA) or mobile phone and sent to the actuator via the wireless interface.

Recently, Near Field Communication (NFC) technology has been used to enable wireless configuration of HVAC field devices. U.S. Patent No. 10261530 discloses a driver (shown in Figure 1 of the present application) for an HVAC system having an actuator for a control element of the HVAC system. The drive also includes: a passive NFC transponder, which is set up to send a uniform identification (identifier) to a mobile service device before a power supply for the drive is switched on, and to receive one or more drive parameters from the mobile service device and to store, and a control module that is set up to control the actuator taking into account the one or more stored drive parameters after a power supply for the drive has been switched on.

[0007] Due to the increasing complexity of HVAC devices and their increasingly challenging positioning and accessibility in HVAC systems, there is a need for new and improved short-range communication-capable HVAC devices.

Summary of the Invention

It is an object of embodiments of the present disclosure to provide an HVAC field device and system that at least partially solves the disadvantages of known HVAC field devices and systems. In particular, an object of embodiments disclosed herein is to provide an HVAC device and system with improved functionality and accessibility.

According to the present disclosure, these objects are achieved by the features of the independent claims. Furthermore, further advantageous embodiments are evident from the dependent claims and the description.

The above object is achieved according to the present disclosure by an HVAC field device comprising a plurality of HVAC device blocks. The HVAC field device comprises: a) a base HVAC device block comprising: a base housing; an electric motor configured to drive a driven element and/or a sensor to measure an operating parameter of an HVAC system; a base control module connected to the electric motor and/or the sensor; a base near field communication NFC circuit connected to the base control module; and b) a first add-on HVAC equipment block comprising: an add-on housing and a first add-on NFC antenna, wherein the base HVAC equipment block and the first add-on HVAC equipment block are mechanically connected, and wherein the first add-on NFC antenna is electrically connected to the base HVAC device block.

According to embodiments of the present disclosure, the electric motor can be arranged inside the base housing or it can be arranged outside of the base housing. In embodiments, the sensor of the base HVAC equipment block is configured to measure a parameter of the HVAC system, in particular an environmental parameter such as temperature, humidity, volatile organic compounds (VOC), particulate matter (PM), and/or CO2 content of an HVAC -System controlled environment. Alternatively or additionally, the sensor of the basic HVAC device block is provided to measure operating parameters of various components of the HVAC system, such as a setting position of the driven element and/or the operating state of the HVAC field device, and/or other parameters of the HVAC system, such as To measure flow rate or differential pressure at local points of a fluid in a fluid delivery system.

In one embodiment, the electrical connection between the first add-on NFC antenna and the base HVAC equipment block is a direct connection, i. H. without intermediate devices. The direct connection can be, for example, an analog electrical connection that transmits an antenna signal to be sent.

In another embodiment, the electrical connection between the first add-on NFC antenna and the base HVAC equipment block is an indirect connection, i. H. via other electrical components such as NFC circuits or microcontrollers and/or via one or more add-on HVAC blocks. In one embodiment, the indirect connection may include a digital signal path between NFC circuitry and a control module.

In one embodiment, the base HVAC equipment block further includes a base NFC antenna electrically connected to the base NFC circuitry.

In one embodiment, the base HVAC equipment block and the first add-on HVAC equipment block are directly connected via an electromechanical interface.

In one embodiment, the base HVAC equipment block has a first type connection interface and the first add-on HVAC equipment block has a first type connection interface and a second type connection interface, the first type connection interfaces and the Connection interface(s) of the second type are configured so that they can be mechanically connected to one another. In this embodiment, the base HVAC equipment block and the first add-on HVAC equipment block are stacked such that the first type connection interface is mechanically connected to the second type connection interface of the adjacent HVAC equipment block.

In one embodiment, the first add-on HVAC equipment block is removably or fixedly attached to the base HVAC equipment block. Preferably, the housings of the HVAC blocks are attached to each other such that the HVAC blocks are attached to each other by their housings.

In one embodiment, the first add-on HVAC equipment block is positioned on top of or to the side of the base HVAC equipment block. In another embodiment, the base HVAC equipment block and the first add-on HVAC equipment block are connected via an additional HVAC block.

In one embodiment, the first add-on NFC antenna is directly connected to the base NFC circuitry, wherein the base NFC circuitry can also be integrated into the base control circuitry and/or the base control module. In one embodiment, the connection is made via an antenna-side radio frequency (RF) link, preferably at a frequency of 13.56 MHz.

In one embodiment, the first add-on HVAC equipment block includes a first add-on NFC circuit coupled to the first add-on NFC antenna.

In one embodiment, the first add-on HVAC equipment block includes a first add-on control module coupled to the first add-on NFC circuit. In another embodiment, the first add-on control module is connected to the base control module.

In one embodiment, the first add-on NFC antenna is configured to interact with an NFC antenna of an external service device when within a communication range of the external service device, thereby enabling data exchange between the HVAC field device and the external service device.

In one embodiment, the HVAC field device is configured to draw power from the external service device via the first add-on NFC antenna and/or the base NFC antenna.

In one embodiment, the basic NFC circuit and/or the first add-on NFC circuit comprises a memory, the memory preferably comprising a non-volatile memory. The HVAC field device non-volatile memory is used to store HVAC field device configuration data required to operate actuator or sensor programs. The presence of non-volatile memory in the base NFC circuit and/or in the first add-on NFC circuit advantageously enables the size of a non-volatile memory in the control module (such as an ASIC or microcontroller) to be reduced or the non-volatile memory in the control module to be omitted entirely.

In one embodiment, the field HVAC device further comprises a second add-on HVAC unit block, the second add-on HVAC unit block between the base HVAC unit block and the first add-on HVAC unit block or on top of the first add-on HVAC unit -Device block is positioned. In yet another embodiment, the second add-on HVAC equipment block includes a second add-on NFC antenna electrically connected to the base HVAC equipment block and/or the first add-on HVAC equipment block.

In one embodiment, the second add-on HVAC block serves as a mechanical and/or electrical interface between the base HVAC block and the first add-on HVAC block.

In one embodiment, the first add-on HVAC equipment block includes a cover. The cover may be an integral part of the add-on HVAC block housing or a separate item configured for mechanical connection to the housing. In yet another embodiment, the device comprises a human-machine interaction device, and the first add-on NFC antenna is preferably arranged underneath the human-machine interaction device. In one embodiment, the human-machine interaction device is integrated into the cover.

In one embodiment, the first add-on NFC antenna includes at least two NFC antennas, preferably positioned on two opposite sides of the HVAC device.

In one embodiment, the base NFC antenna is arranged such that access to it via the service device to establish a communication is not possible or access to the base NFC antenna is blocked by the first add-on HVAC device block becomes. In another embodiment, the communication range of the first add-on antenna and/or the base NFC antenna is 0 to 0.1 m, in still another embodiment 0 to 4 cm, and in another embodiment 0 to 1 cm. These values are exemplary only and should not be considered essential.

Another object of the present invention is to provide an HVAC system comprising an HVAC field device according to the invention. The proposed HVAC system includes a driven element, such as a valve and/or a flap, drivingly connected to the electric motor of the basic HVAC device block of the HVAC field device.

Another object of the present invention is to provide a method for improving NFC communication between an HVAC field device and a service device, the method comprising the step of: adding an add-on HVAC device block that has an NFC antenna comprises, to a base HVAC device block of the HVAC field device. In one embodiment, the add-on block includes the add-on NFC antenna connected to an add-on NFC circuit. In another embodiment, where the add-on NFC antenna is connected to the add-on NFC circuitry, the base NFC antenna is disabled for operation.

Another object of the present invention is to provide a method for configuring an HVAC field device, the method comprising the steps of: a) wireless transmission of configuration information from a service device to a first add-on HVAC device block via the first add- on NFC antenna, b) mechanically and electrically connecting the first add-on HVAC equipment block to a base HVAC equipment block, and c) configuring the HVAC field device based on the received configuration information. Alternatively, if the base HVAC block comprises a base NFC antenna, step a) may be as follows: wirelessly transmitting configuration information from a service device to a base HVAC device via the base NFC antenna.

Brief description of the drawings

The disclosure described herein will be understood more fully from the following detailed description and the accompanying drawings, which should not be taken as limiting the disclosure set forth in the appended claims. The drawings show: FIG. 1: shows a schematic representation of an HVAC device with a passive NFC transponder, which is arranged in the effective range of an active NFC module of a mobile service device, from the prior art; Figure 2A shows a schematic representation of a base HVAC block and an add-on HVAC block; Figures 2B and 2C show a schematic representation of an HVAC device according to embodiments of the invention, which comprises a base HVAC block and an add-on HVAC block; Figures 3A and 3B: show a schematic representation of an HVAC device according to an embodiment of the invention, which comprises two NFC antennas; FIG. 4 shows a schematic representation of an HVAC device according to an embodiment of the invention, which communicates with a mobile service device. Figure 5 shows a schematic representation of an HVAC device according to an embodiment of the invention, comprising a base HVAC block and an add-on HVAC block with a first add-on control module and a first add-on NFC circuit; FIGS. 6 and 7 show a schematic representation of an HVAC device according to embodiments of the invention, which comprises a second add-on module; Figures 8A and 8B show a schematic representation of an HVAC device according to the embodiment of the invention, which includes a cover; Figure 9 shows a schematic representation of an HVAC device according to an embodiment of the invention, which comprises a human-machine interaction device; FIG. 10 shows a schematic representation of an HVAC device according to an embodiment of the invention, which comprises a plurality of NFC antennas; Figure 11 shows a schematic representation of an HVAC device according to the embodiment of the invention, which includes printed circuit boards (PCB) and flexprint antenna; FIG. 12 shows a schematic representation of an HVAC system according to an embodiment of the invention; Figure 13 shows a schematic representation of an HVAC device according to an embodiment of the invention, which includes memory modules which communicate with the mobile service device; FIG. 14 shows a schematic representation of steps of a method for configuring an HVAC device according to an embodiment of the invention.

Detailed description

Reference will now be made in detail to specific embodiments, examples of which are illustrated in the accompanying drawings, in which some but not all features are illustrated. Embodiments disclosed herein may be embodied in many different forms and are not intended to be limiting of the embodiments set forth herein; rather, these embodiments are provided to satisfy the legal requirements applicable to this disclosure. As far as possible, the same components or parts are denoted by the same reference numbers.

[0035] Field devices include devices of an HVAC system that are located within the controlled environment or that are mechanically connected to the controlled environment, for example via the fluid handling system. Field devices implement one or more electrical and/or mechanical functions and include in particular, but not exclusively, actuators, sensors or a combination thereof.

[0036] Near Field Communication NFC is the technology used for communication between two devices in short range, typically over a distance of 0 to 10 cm. Typical applications include contactless payment systems as a replacement for credit cards. NFC is commonly used for exchanging small files with limited transfer speeds. NFC components such as NFC circuits are usually equipped with non-volatile memory in the kb range. In general, an NFC circuit in conjunction with an NFC antenna allows data to be exchanged with another NFC circuit. NFC uses the 13.56 MHz frequency spectrum and is mainly defined by the ISO 18000-3 and ISO 13157 and ISO 15693 standards. NFC components such as circuitry, antennas, and readers are commercially available, and NFC readers are built into most smartphones.

Figure 1 is a schematic representation of an example from the prior art showing the use of NFC technology for HVAC systems. An HVAC drive 1 has a passive NFC transponder 14 which is arranged within the effective range of an active NFC module 24 of a mobile service device 2 . The mobile service device 2 includes the control module 25, which is configured to control an active NFC module 24 of the mobile service device 2, and a user interface 26, which is set up to display ID identifiers and drive parameters. The HVAC drive 1 includes a control module 15 configured to control a communication module 13 , a sensor interface 12 and a sensor 17 , the passive NFC transponder 14 and an actuator 11 . The active NFC module 24 of the mobile service device 2 cooperates with the NFC transponder 14 of the drive 1 via the operative connection 21 in order to read the uniform ID identifier 16 of the drive 1 and to read and write drive parameters.

In Figure 1, the HVAC drive 1 includes a fluid port 18 which is connected to a water pipe or air duct. The fluid connector 18 may be attached to the housing of the HVAC drive 1 such that the housing and the fluid connector 18 together form a unit (shown with the dashed line); the fluid connector 18 includes a regulating element 19, such as a valve, with which the flow rate of the fluid is regulated. The control element 19 is connected to the actuator 11 of the drive 1 . The actuator 11 is housed in the housing of the drive 1 . The actuator 11 includes a motor with which a mechanical force is generated in order to move the control element 19 arranged in the fluid connection 18 into a required position.

Figure 2A shows a highly illustrated cross section of the building blocks of the HVAC field device 200 in accordance with the present disclosure. According to the embodiment shown in Figure 2A, the HVAC field device 200 comprises a basic HVAC device block 201 and a first add-on HVAC device block 202. Figure 2B shows the HVAC field device 200 in assembled form, with the basic HVAC device block 201 and the first add-on HVAC equipment block 202 are mechanically connected via mechanical or electromechanical interfaces 212 and 213 .

In one embodiment, the base HVAC equipment block 201 includes a first type connection interface 212. The first add-on HVAC equipment block 202 may have a first type connection interface and a second type connection interface 213, the first type connection interfaces and the second type connection interface(s) are configured to be mechanically connected to each other. In this embodiment, the base HVAC equipment block 201 and the first add-on HVAC equipment block 202 are stacked on top of each other such that, as shown in Figure 2B, the first type connection interface is mechanically connected to the second type connection interface of the adjacent add-on HVAC equipment block 202 is connected. In one embodiment, the base HVAC equipment block 201 and the first add-on HVAC equipment block 202 are electrically connectable. In particular, the interfaces of the base HVAC equipment block 201 and the first add-on HVAC equipment block 202 can be designed in such a way that they enable a mechanical and electrical connection.

According to an embodiment of the invention, the base HVAC equipment block 201 comprises: a base housing 203; an electric motor 205 and/or a sensor; a base control module 207 connected to the electric motor 205 and/or the sensors. The base HVAC equipment block 201 further comprises a base near field communication NFC circuit 208 which is connected to the base control module 207, for example via an electrical connection 211a, which preferably comprises an I2C connection (Inter-Integrated Circuit). Link 211a is configured to transfer data and/or power between base NFC circuitry 208 and base control module 207 . The base NFC circuitry is configured for connection to an NFC antenna via an electrical connection 211b. In one embodiment, the base control module 207 and the base NFC circuitry 208 may be integrated on a single electronic circuit board.

Depending on the particular embodiment, the control module 207 of the base HVAC equipment block 201 is connected to either the electric motor 205 and/or the sensors. When connected to the electric motor 205, the control module 207 is configured to drive the electric motor 205 to implement one or more HVAC control functions. When connected to the sensor, the control module 208 is configured to receive and/or process signals representative of an operating parameter(s) of the HVAC system, such as temperature and/or humidity, or signals representative of operating parameters of various components of the HVAC system.

In the embodiment illustrated in Figures 2A and 2B, the add-on HVAC equipment block 202 includes: an add-on housing 204 and a first add-on NFC antenna 210, which is preferably positioned inside the housing 204. The base HVAC equipment block 201 and the first add-on HVAC equipment block 202 are mechanically connected via respective housings 203 and 204 . The first add-on NFC antenna 210 is electrically connected to the base HVAC device block 201 . The electrical connection between the base HVAC equipment block 201 and the first add-on HVAC equipment block 202 is represented by electrical wires 211b and 211c, which connection establishes the electrical connection between the first add-on antenna 210 and the base NFC circuitry 208 . In one embodiment, the electrical connection between the HVAC blocks is achieved through a direct connection via electromechanical interfaces 212,213.

The first add-on HVAC block 202 may be detachably or fixedly attached to the base HVAC block 201. The connection between the HVAC equipment blocks can be achieved using different adhesives and/or fasteners. According to embodiments of the present disclosure, the fastening means can be, for example, latches, snap connections, screw or bolt connections for mechanically connecting the adjacent HVAC device blocks. Alternatively or additionally, the HVAC device blocks can be welded together after the connection has been made, in particular by ultrasonic welding or laser welding. According to the special requirements of the HVAC field device 200, a sealant can be provided at the connection interfaces in order to connect the HVAC device blocks to one another in a sealed manner against moisture, dust or other sources of contamination.

In the embodiment of Figure 2B, the first add-on HVAC equipment block 202 is positioned on top of the base HVAC equipment block 201. Alternatively, the first add-on HVAC equipment block 202 may be positioned to the side of the base HVAC equipment block 201 . In addition, the base HVAC equipment block 201 and the first add-on HVAC equipment block 202 may be connected via an additional HVAC block or an additional mechanical interface.

In one embodiment, as shown in Figure 2B, the first add-on NFC antenna 210 is connected to the base NFC circuitry 208. In this embodiment, the electrical connection is between the first add-on NFC antenna 210 and the base HVAC equipment block 201 a direct electrical connection. In this manner, the first add-on NFC antenna 210 is operatively connected to the base NFC circuitry 208 and can provide power sourced via inductive coupling to an external active NFC reader such as a cellular phone. The base control module 207 and the first NFC control circuit 208 can advantageously be integrated in an electronic circuit. In one embodiment, the base control module 207 is an application specific integrated circuit (ASIC), specifically it may be the ASIC that includes an engine controller.

In one embodiment, as shown in Figure 2C, the base HVAC block 201 includes a sensor 305 positioned outside of the housing 203 and connected to the base control module 207. In another embodiment, the sensor 305 can be placed inside the housing be integrated or at least part of the sensor 305 can be integrated inside the housing 203 . For example, the first element of the sensor can be positioned inside an air duct and can direct the air into the housing 203 where the air is sensed by the second part of the sensor. In another embodiment, the base HVAC block 201 may include a plurality of sensors for measuring operating parameters.

The sensor 305 of the base HVAC equipment block 201 is configured to measure a parameter of the HVAC system, in particular an environmental parameter such as temperature, humidity, volatile organic compounds (VOC), particulate matter (PM) and/or CO2 content an environment controlled by the HVAC system. Alternatively or additionally, the sensor 305 is provided to the base HVAC device block 201 to sense operating parameters of various components of the HVAC system, such as a driven element set position and/or the operating state of the HVAC field device, and/or other parameters of the HVAC system , such as flow rate or differential pressure at local points of a fluid in a fluid delivery system.

[0049] The HVAC device 200 is configured to receive power from the external supply and/or may include an internal power supply such as a battery supply. The HVAC device 200 may also include temporary energy storage such as a battery and/or a capacitor. The HVAC device 200 can also operate, at least to some extent, using the power drawn by the first add-on NFC antenna 210 .

Figures 3A and 3B show a schematic representation of the HVAC device 200, which has an additional NFC antenna in the base HVAC block 201. In particular, the base HVAC device block 201 includes a base NFC antenna 209 which is preferably positioned inside the housing 203 . The base NFC antenna 209 and the first add-on NFC antenna 210 are configured for connection to the base NFC circuitry 208, for example via a radio frequency link 211. The NFC antennas 209,210 can be located inside the housings 203,204 of the HVAC -Device blocks 201,202 may be positioned or may be positioned on top of the housings or may be integrated inside the housing.

The antennas 209 and 210 can take various forms. The NFC antenna forms an inductive loop configured to inductively couple NFC circuitry to an external device such as a cell phone. In one embodiment, the NFC antenna can have an inductive winding and a capacitor for frequency tuning. The capacitor can be positioned closer to the inductive winding, positioned closer to the NFC circuitry, or shared with a second NFC antenna.

In one embodiment, the NFC antennas 209 and 210 are printed circuit board (PCB) antennas, which is particularly advantageous for saving space in a device. Some possible realizations include antennas in rectangular shape with dimensions like 54x27 mm<2>, 36x24 mm<2> or 24x18 mm<2>. These measures are mere examples and not limiting. Other dimensions and shapes of NFC antennas are equally applicable. Advantageously, PCB antennas can also be integrated into a circuit board that carries other electronic components of the HVAC field device 200, thereby reducing the overall component count and thereby lowering costs.

The first add-on NFC antenna 210 can be positioned outside of the housing 204 of the HVAC field device 200 . In this embodiment, the antenna is electrically connected to the housing 204, for example via a cable.

The positioning of the antennas 209 and 210 can take different arrangements. In one embodiment they are positioned parallel to each other at a distance of 20 to 30 mm. Preferably, there should be no significant shielding between two antennas, as shielding can significantly reduce the performance of the add-on NFC antenna 210. If a metal object is positioned between antennas 209 and 210, it must be constructed or modifiable in such a way that induction of eddy currents is significantly restricted. In addition, a good capacitance match between two antennas is essential for the overall performance of the antennas. Ultimately, the communication range of the add-on NFC antenna can be improved by up to 50% by using a ferrite foil below the add-on NFC antenna and above the base NFC antenna. By following these guidelines, the performance of the first add-on NFC antenna can be similar to that of the base NFC antenna without the need to modify the base HVAC device block.

In the embodiments where both the base HVAC antenna 210 and the add-on NFC antenna are present, it is important that tuning capacitances are properly chosen to ensure that the resonant frequency of a base HVAC Antenna 209 and the resonance frequency of both antennas are kept in parallel in a narrow range around the NFC frequency (e.g. 13.56 MHz). The tuning capacity of the single antenna is preferably chosen to achieve a resonant frequency around the NFC frequency (e.g. 13.56 MHz) when only the base HVAC antenna 210 is connected, while the tuning capacity of the add-on HVAC antenna 209 is selected so that when connected in parallel with the base NFC antenna 210, the resonant frequency of both antennas is unchanged at around the NFC frequency (e.g. 13.56 MHz).

Figure 4 shows a communication between the HVAC field device 200 and an external service device 220. The external service device 220 includes an active NFC module 221. The external service device 220 can transmit a signal via an operational connection 222. The mobile service device includes a user interface with a touch screen, a display with a keyboard, etc. The user interface is configured to display ID tags and drive parameters and to receive values for drive parameters. In one embodiment, the mobile service device 200 comprises a suitably programmed mobile phone, smartphone, etc., which has an active NFC module 221, which draws its energy from a battery of the corresponding device. The transmitted signal may include configuration data to be used to configure the HVAC field device 200 .

The external service device 220 can write and/or read information from/to the HVAC device 200 via the first add-on NFC antenna 210 . This possibility advantageously allows the following functions to be carried out: identification of the actuator/sensor using NFC-ID; configure the actuator/sensor; transmit commands for actuation/operation; Reading operating data, statistical data and diagnostic data; starting functional tests; Upgrading firmware of the actuator/sensor.

The drive parameters that can be exchanged between the service device 220 and the HVAC field device 200 can refer to one or more of the following readable and/or writable parameters: communication address for the HVAC device, such as an MP bus address etc.; installation location, such as room, etc.; response sensitivity and return hysteresis; type of feedback signal; positioning range within the mechanical limits; term in relation to the workspace; angle of rotation, direction of rotation; stroke, direction of stroke; working torque in relation to the maximum possible torque; work actuation force in relation to the maximum actuation force, emergency position; Time delay to reach emergency position after power failure; counters for determining the number of voltage interruptions; Specification of behavior in the event of failure of the communication module or the communication link; definition of a behavior when switching on a power supply; Definition of behavior when actuating drive buttons.

Additional parameters that may be exchanged between the service device 220 and the HVAC field device 200 include read-only parameters such as: voltage source (e.g., 24VDC, 24VAC, 230VAC), number of voltage failures, total operating time, energy storage/supercapacitor state , bus type (e.g. MP-Bus, BACnet MSTP or Modbus), bus address and baud rate of the bus.

Other special parameters relating to the actuators can be a position of a drive part (read-only parameters) and read-write parameters such as runtime and valve settings: valve size and type, control signal (normal, inverted), control type (open -To, 3-point, 0.5V-10V, 2-10V, 4-20mA) and feedback signal (normal, inverted).

Other special parameters related to the sensors can be: read-only parameters such as calibration data, calibration date, output voltage, measured values and statistical data; and read-write parameters such as display settings, alarm and warning levels and sources, alarm and warning activation, output signal type (5V-10V, 2-10V, 4-20mA), evaluation range, selection of the output signal (e.g. dew point or relative humidity) and in the case of several sensors: selection of analogue output signals.

The base NFC antenna 209 and the first add-on NFC antenna 210 are configured to communicate with the external service device 220 when they are within a communication range of the external service device 220. In the embodiment shown in Figure 4, only the first add-on NFC antenna 210 is within a communication range of the external service device 220. The exemplary communication range of the first add-on NFC antenna is up to 4 cm, and in a special case up to to 1 cm. In this embodiment, the base NFC antenna 209 is physically shielded by the add-on HVAC block 202 and is inaccessible to the service device 220 .

In this embodiment, the communication range of the HVAC device 200 is advantageously extended via an add-on NFC communication range of the add-on NFC antenna 210, and the HVAC device 200 is also despite the shielding of the base NFC antenna 209 NFC-enabled thanks to add-on HVAC block 202.

The signal from the service device 220 is received by the HVAC field device 200, and in particular by the first add-on NFC antenna 210. In one embodiment, the first add-on NFC antenna 210 is connected to a memory in which the signaling information is stored. The memory is preferably non-volatile memory and may preferably be integrated into the base NFC circuitry 208 . This operation can be performed without powering the HVAC device 200 since the add-on NFC antenna 210 and associated NFC circuitry 208 and 216, respectively, can draw power from the active NFC module 221 of the service device 220. After powering up the HVAC field device 200, the received signal may be transmitted to the base NFC circuitry 208 and/or the base control module 207 for further processing of the received signal. The received signal may include information on the configuration parameters of the HVAC device 200 . The data stored in the memory of the NFC circuit can be read with the service device 200 while supplying power to the NFC circuit. This data includes configuration and monitoring data.

FIG. 5 shows a highly illustrated cross-section of an embodiment of the HVAC field device 200 according to another embodiment of the present disclosure. In this embodiment, the first add-on HVAC equipment block 202 includes a first add-on control module 215 and a first add-on NFC circuit 216. The first add-on NFC antenna 210 is coupled to the first add-on NFC circuit 216 and/or connected to the first attachment control module 215 . The base control module 207 and the first add-on control module 215 may be connected via the electrical interface 214 between the base HVAC equipment block 201 and the first add-on HVAC equipment block 202 . In this illustrated embodiment of Figure 5, the electrical connection between the first add-on NFC antenna 210 and the base HVAC equipment block 201 is an indirect electrical connection. In one embodiment, the first attachment control module 215 is a microcontroller. In this way, the indirect electrical connection between the first add-on antenna 210 and the base control module is established. The more complex structure of the first add-on HVAC device block compared to the embodiment of FIG. The additional computing power of the first add-on control module 215 also enables the first add-on NFC circuit 216 to be controlled. The additional memory in the first add-on NFC circuit 216 can be used to store more configuration parameters. The memory size of the first add-on NFC circuit 216 may be selected to exceed the memory size of the base NFC circuit 208 .

According to embodiments disclosed herein, the add-on HVAC device block 202 may include one or more of the following: - a processing device such as a microcontroller or an application specific integrated circuit ASIC for providing computing power to the HVAC field device 200; - a controller device that implements HVAC control and regulation functions, such as proportional P, proportional-integral PI, proportional-integral-derivative PID, integral I, and/or neural network-based control; - a communication device, which comprises a wired interface and/or a radio communication device, for providing communication functionalities to the HVAC field device 200. The communication device can in particular comprise one or more of the following: - a wired communication interface (such as an Ethernet interface, in particular power over Ethernet, a BUS interface, in particular MP-Bus or Modbus); - a wide area network communication circuit (such as GSM, LTE, 3G, 4G or 5G mobile communication circuit); - a low-energy wide area network (such as Narrowband Internet of Things NB-loT, Long Range LoRa/ LoRaWAN, SigFox, or Long Term Evolution Category M1 LTECatM1); - a local area network communication circuit (such as wireless LAN); - a short-distance wireless communication circuit (such as Bluetooth, Bluetooth Low Energy BLE, Thread and/or Zigbee); and/or - a short-range wireless communication circuit (such as Radio Frequency Identification RFID). - an energy storage device comprising a capacitive storage device and/or an electrochemical storage device; - a sensor device comprising one or more sensors for measuring a parameter of an HVAC system and/or an environmental parameter (such as temperature, humidity, etc.); - an HVAC interface device comprising a mechanical interface to a door and/or a pipe of an HVAC system; - a position feedback device of the driven element; - an electrical power supply device for providing external electrical power to the HVAC field device, such as universal power supply devices (24VAC to 250VAC/24VDC-125VDC) or power supply devices for special supply voltages; - a monitoring/service device to perform special service and data logging function(s); and/or - a display device.

The add-on HVAC device block 201 according to the embodiments disclosed here can be divided into several stages (levels): A Tier 1 add-on HVAC equipment block includes an application-specific integrated circuit ASIC that is specifically configured for basic actuator functions, such as opening and closing a valve or damper. Further, Level 1 HVAC equipment blocks include a communication bus that allows seamless integration into Level 2 equipment block(s); A level 2 HVAC equipment block comprises a µC (microcontroller) that is (pre)configured for an application-specific extension of the functionality of the basic HVAC equipment block 201, such as for the execution of a program code of at least specific HVAC application, such as a variable Volumetric flow control (VAV) based on data signals from a sensor for measuring an air volume. In addition, Level 2 HVAC device blocks support various network protocols such as ModBus, BACnet or Ethernet; A Level 3 HVAC equipment block includes a µC (microcontroller) that is fully configurable for advanced HVAC functions and/or similar functionality to the Level 2 HVAC equipment blocks.

FIG. 6 shows a highly illustrated cross-section of an embodiment of the HVAC field device 200 according to another embodiment of the present disclosure. In this embodiment, the HVAC field device 200 further includes a second add-on HVAC equipment block 301 positioned on top of the first add-on HVAC equipment block 202 . The second add-on HVAC equipment block 301 includes a housing 302 and the second add-on NFC antenna 303. The second add-on NFC antenna 303 may be connected to the first add-on HVAC equipment block 202 via an electrical connection 217. The embodiment illustrated in FIG. 7 shows an embodiment in which the second add-on HVAC block 303 is positioned between the base HVAC block 201 and the first add-on HVAC block 202 . In this embodiment, the second add-on HVAC block 303 serves only as an electromechanical interface between the base HVAC block 201 and the first add-on HVAC block 202.

FIG. 8A shows a highly illustrated cross-section of an embodiment of the HVAC field device 200 according to another embodiment of the present disclosure. In this embodiment, the HVAC field device 200 includes a cover 218 . The cover 218 may be positioned on top of the field HVAC unit 202 or may be an integral part of the HVAC unit block 202 as illustrated in Figure 8B. The first add-on NFC antenna 210 is preferably positioned within the cover 218 or may be positioned below the cover 218 .

[0070] FIG. 9 shows a further embodiment of the HVAC field device 200 which comprises a human-machine interaction device 223 . The human-machine interaction device can preferably comprise a keyboard or a touch screen. Preferably, the first add-on NFC antenna 210 is positioned substantially below the human-machine interaction device 223 . In another preferred embodiment, human-machine interaction device 223 is part of cover 218.

In the embodiment illustrated in FIG. 10, the first add-on NFC antenna 210 comprises at least two NFC antennas 219a, 219b, which are preferably positioned on different sides of the first add-on HVAC block 202. Depending on the environmental conditions at the installation site, the HVAC device 200 is sometimes not freely accessible from all sides. The antennas 219a, 219b are mounted on or in the housing of the unit 200 such that at least one of the two antennas remains freely accessible after the HVAC unit 200 is assembled and installed in the building. For example, if the HVAC device 200 is located in a corner formed by a ceiling and a wall, one of the antennas 219a, 219b is easily accessible and the operative connection between the active NFC module of the mobile service device 220 and the HVAC Device 200 can be manufactured. This configuration generally ensures that at least one of the antennas 219a, 219b is accessible after the HVAC field device 200 is installed. In another embodiment it is possible to install three or more antennas.

Figure 11 shows another embodiment of the HVAC field device 200, wherein the base control module 207 and the first add-on control module 215 each include printed circuit boards (PCB). In this embodiment, both the basic NFC circuit 208 and the first add-on NFC circuit 216 are integrated on respective printed circuit boards and connected via an electrical connection 405 . The first add-on NFC antenna 209 is a flexprint antenna positioned on the cover of the add-on HVAC equipment block 202, while the base NFC antenna 210 is integrated on the circuit board.

The HVAC field device 200 as described can be integrated into an HVAC system 500 according to FIG. Device blocks 201 of the HVAC field device 200 drivingly connected driven element 206, such as a valve and / or a flap includes.

[0074] FIG. 13 shows a highly illustrated cross-section of an embodiment of the HVAC field device 200 according to another embodiment of the present disclosure, wherein the HVAC field device 200 is configured using the service device 220 . The base control module 207 includes a RAM memory 233, and the add-on control module 216 includes a RAM memory 231. The base NFC circuit 208 includes the electrically erasable and programmable read-only memory (EEPROM) 232, while the first add-on NFC circuit 215 includes the EEPROM memory 230. The configuration information sent by the service device 220 may be received by the antenna 210 and stored in the EEPROM memory 230 before the HVAC field device 200 is powered.

The method for configuring an HVAC field device 200 is shown in Figure 14 and includes the following steps: S1: wireless transmission of configuration information from a service device 220 to a first add-on HVAC device block 201 via a first add-on NFC antenna 210; S2: mechanically and electrically connecting a first add-on HVAC equipment block 202 to a base HVAC equipment block 201; and S3: configure the HVAC field device 200 based on the received configuration information.

Alternatively, if the base HVAC block includes a base NFC antenna 209, step S1 may be as follows: S1: wirelessly transmit configuration information from a service device to a base HVAC device via the base NFC antenna .

Legend of the reference numbers

[0077] HVAC[A1] drive 1 mobile service device 2 actuator 11 sensor interface 12 communication module 13 passive NFC transponder 14 control module 15 uniform ID identifier 16 sensor 17 fluid connection 18 control element 19 operational connection 21 NFC module 24 control module 25 user interface 26 HVAC Field device 200 Basic HVAC equipment block 201 First add-on HVAC equipment block 202 Basic housing 203 Add-on housing 204 Electric motor/sensor 205 Driven element[A2] 206 Basic control module 207 Basic near-field communication NFC circuit 208 Basic NFC antenna 209 First Add-on NFC antenna 210 Electrical connection 211a, 211b, 211c, 211 Electromechanical interface 212 Electromechanical interface 213 Electrical connection 214 First add-on control module 215 First add-on NFC circuit 216 Electrical connection 217 Cover 218 NFC antenna 219a, 219b Service unit 220 Active NFC module 221 signal 222 human-machine interaction device 223 RAM memory 231,233 EEPROM -Memory 230,233 Second Attachment HVAC Unit Block 301 Second Add-on Housing 302 Second Add-on NFC Antenna 303 Sensor 305 Electrical Connection 404,405 HVAC System 500

Claims (29)

A HVAC field device (200) comprising a plurality of HVAC device blocks (201,202), the device comprising: a) a base HVAC equipment block (201) comprising: a base case (203); an electric motor (205) configured to drive a driven element (206) and/or a sensor (305) for measuring an operating parameter of an HVAC system; a base control module (207) connected to the electric motor (205) and/or the sensor (305); a base near field communication NFC circuit (208) connected to the base control module (207); and b) a first add-on HVAC unit block (202) comprising: an add-on chassis (204); and a first add-on NFC antenna (210), wherein the base HVAC equipment block (201) and the first add-on HVAC equipment block (202) are mechanically connected (212,213), and wherein the first add-on NFC antenna (210) is electrically connected to the base HVAC equipment block (201). The HVAC field device (200) of claim 1, wherein the base HVAC device block (201) further comprises a base NFC antenna (209) electrically connected to the base NFC circuit (208). The HVAC field device (200) of claim 1 or claim 2, wherein the base HVAC device block (201) and the first add-on HVAC device block (202) are directly connected via an electromechanical interface (212,213). 4. HVAC field device (200) according to any one of the preceding claims, wherein the first add-on HVAC block (202) is releasably attached or fixedly attached to the base HVAC block (201). 5. HVAC field device (200) according to any one of the preceding claims, wherein the first add-on HVAC equipment block (202) is positioned on top of or on the side of the base HVAC equipment block (201). 6. HVAC field device (200) according to any one of the preceding claims, wherein the base HVAC device block (201) and the first add-on HVAC device block (202) are connected via at least one additional HVAC block (301). 7. HVAC field device (200) according to any one of the preceding claims, wherein the first add-on NFC antenna (210) is directly connected to the base NFC circuitry (208). The HVAC field device (200) according to any one of claims 1 to 6, wherein the first add-on HVAC device block (202) has a first add-on NFC circuit (216) connected to the first add-on NFC antenna (210). includes. The field HVAC device (200) of claim 8, wherein the first add-on HVAC equipment block (202) includes a first add-on control module (215) connected to the first add-on NFC circuit (216). 10. HVAC field device (200) according to claim 9, wherein the first add-on control module (215) is connected to the base control module (207). 11. HVAC field device (200) according to any one of the preceding claims, wherein the first add-on NFC antenna (210) is configured to interact with an NFC antenna of an external service device (220) when within a Communication range of the external service device (220) is located, whereby data exchange between the HVAC field device and the external service device is made possible. 12. HVAC field device (200) according to any one of claims 2 to 11, characterized in that the HVAC field device for obtaining power from the external service device (220) via the first add-on NFC antenna (210) and / or the base NFC antenna (209) is configured. The HVAC field device (200) of claim 8, wherein the base NFC antenna (209) is disabled for operation. 14. HVAC field device (200) according to any one of claims 8 to 13, wherein the base NFC circuit (208) and / or the first add-on NFC circuit (216) comprises a memory (230,232). 15. HVAC field device (200) according to any one of the preceding claims, further comprising a second add-on HVAC device block (301), wherein the second add-on HVAC device block (301) between the base HVAC device block (201) and the first add-on HVAC equipment block (202) or positioned on top of the first add-on HVAC equipment block (202). 16. HVAC field device (200) according to claim 15, wherein the second add-on HVAC device block (301) with the base HVAC device block (201) and / or the first add-on HVAC device block (202) electrically connected second Includes add-on NFC antenna (303). The HVAC field device (200) of claim 16, wherein the second add-on NFC antenna (303) is electrically connected to the base control module (207) and/or the base NFC circuit (208). 18. HVAC field device (200) according to one of claims 15 to 17, wherein the second add-on HVAC block (303) is the electromechanical interface between the base HVAC block (201) and the first add-on HVAC block (202 ) is. 19. HVAC field device (200) according to any one of the preceding claims, wherein the first add-on HVAC device block (202) further comprises a cover (218). 20. HVAC field device (200) according to claim 19, wherein the first add-on NFC antenna (210) is positioned below the cover (218) inside the add-on housing. 21. HVAC field device (200) according to any one of the preceding claims, wherein the device further comprises a human-machine interaction device (223), and wherein the first add-on NFC antenna (210) below the human-machine interaction device ( 221) or is positioned inside or attached to the man-machine interaction device (221). 22. HVAC field device (200) according to any one of the preceding claims, wherein the first add-on NFC antenna (210) comprises at least two NFC antennas (219a, 219b) positioned on different sides of the HVAC field device (220). The HVAC field device (200) of any one of claims 2 to 22, wherein the base NFC antenna (209) is positioned so that it cannot be accessed via a service device (220) to establish communication, or wherein access to the base NFC antenna is blocked by the first add-on HVAC device block (202). 24. HVAC field device (200) according to any one of claims 2 to 23, wherein the communication range of the first add-on antenna (209) and/or base NFC antenna (210) is 0 to 4 cm. 25. HVAC field device (200) according to one of the preceding claims, wherein the base HVAC device block (201) has a connection interface of a first type (212) and the first add-on HVAC device block has a connection interface of the first type (212) and a second type connection interface (213), wherein the first type connection interface and the second type connection interface(s) are configured to be mechanically connectable to each other, and wherein the base HVAC equipment block (201) and the first add-on HVAC equipment block (202) are stacked such that the first type connection interface is mechanically connected to the second type connection interface of the adjacent HVAC equipment block. An HVAC system (500) comprising: an HVAC field device (200) according to any one of claims 1 to 25; and a driven part (206), such as a valve and/or a flap, which is drivingly connected to the electric motor (205) of the basic HVAC device block (201) of the HVAC field device (200). 27. A method for improving wireless communication between an HVAC field device (200) comprising a base HVAC block and a service device (220), the method comprising the step of adding an add-on HVAC device block (201), having an NFC antenna (210), to a base HVAC device block (201) of the HVAC field device (200). The method of claim 27, wherein the HVAC field device (200) is the device of any one of claims 1 to 25. 29. A method for configuring an HVAC field device (200) according to any one of claims 1 to 25, the method comprising the steps of: - Wireless transmission of configuration information from a service device (220) to a first attachment HVAC device block (201) via a first NFC antenna (210); - mechanically and electrically connecting a first add-on HVAC equipment block (202) to a base HVAC equipment block (201); and - configuring the HVAC field device (200) based on the received configuration information.