NL2029558B1 - Ventilation assembly of a ventilation unit and a control unit with several pre-set increasing usage levels temperature versus speed modulation curves. - Google Patents

Abstract

The invention relates to a ventilation assembly for passing a forced air flow past a heating/cooling device, such as a radiator or convector, in order to increase its heat exchange with ambient air, comprising: - a ventilation unit (10), a temperature sensor, and a control unit (1). The control unit includes several preset increasing usage levels temperature versus speed modulation curves, where each preset usage level temperature versus speed modulation curve follows its own preset progression along which a temperature-dependent speed for the fans is adjusted in such a way that at a higher resp. lower temperature of the heating/cooling device measured by the temperature sensor in accordance with its own pre-set course a higher resp. lower speed for the fans is adjusted, and where controls are provided for manual selection by a user of one of the pre-set incremental usage levels temperature versus speed modulation curves. +Fig.

Description

P35368NLOO/RR

Title: Ventilation assembly of a ventilation unit and a control unit with several pre-set ascending usage levels temperature versus speed modulation curves.

DISCIPLINE

The invention relates to a ventilation assembly for passing a forced air flow past a heating/cooling device, such as a radiator or convector, in order to increase the heat exchange thereof with ambient air.

STATE OF THE ART

In the pursuit of using energy for heating spaces/houses as efficiently as possible, it is already known, when controlling a heat source for space heating, to also measure the outside temperature, ambient room temperature and/or, indirectly, a heat loss from a space, as parameters to control a combustion boiler and/or heat pump as efficiently as possible. For example, the flow rate and temperature of a pumped medium can be adjusted, as well as a controlled heating at a calculated heating time. Thermostats for this are also becoming smarter and are, for example, geared to a heat demand, in order to contribute to efficient use of energy.

This complexity does mean that a user can exercise less and less direct influence on influencing factors such as the output temperature of the heat source and flow rate. It is still possible to adjust settings, but extensive descriptions in combination with complexity and infrequent settings will mean that the user is increasingly limited to specifying a desired room temperature and switch-on periods.

It is already known in all kinds of embodiments to fit a ventilation unit to a radiator or convector. Switching on its fans will forcefully increase the flow of convection air along/through the heat exchange surface of the radiator or convector. This allows more heat to be exchanged, compared to a maximum convection based on the physical principle that cold air descends by gravity, displacing the warm air, which is then pushed upwards (convection).

Dutch patent publication NL-2015238 discloses an example of such a ventilation unit. It comprises a control device that regulates a speed of its fans on the basis of a comparison of two temperatures, namely temperature of water from a return pipe of a radiator against temperature of the environment in which the radiator is located. To this end, two temperature sensors must be installed on the return line and in the space to be heated. A booster button is provided with which the control device can be temporarily overruled to allow the fans to run at maximum for a certain period of time.

However, the control technology is not simple in all of this, and with two temperature sensors and the cooperating control device for modulating control of rotational speeds of the fans and the tuning therein, is complex and expensive.

In addition, determining a specific location for the room temperature sensor in order to achieve a good reflection of the room temperature will not be an easy choice for the average user. The chance that due to specific local conditions at this location for the room temperature sensor, such as opening doors, walking past, air currents in the room, both warmer and cooler or even draught, the measured room temperature value does not always indicate an average temperature, which could pose a problem and which could negatively influence correct management.

In addition, the ambient temperature is taken into account as a control factor, just as a modulating thermostat already does, and it is known that several independent controls with the same source factor can quickly influence each other negatively.

With this modulating function, adjusted to the ambient temperature and return water temperature, this will not contribute to the feeling of the users that they can exert more influence on their comfort demand. Since there is a desire to exert more influence on the parameters, an extensive and detailed description will mean that few of us will bother to follow this route.

British patent publication GB2337811 discloses another example of such a ventilation unit. The control device of this is such that on the basis of temperatures measured by a temperature sensor on a radiator, fans are switched on and off at preset constant rotation speeds. Although the control device thereof is considerably simpler, and there can be no question of two interfering modulating systems, the user-friendliness of this also leaves much to be desired.

The fans, rotating at preset constant speeds, move air and, in addition to motor frictional contact, all make noise. This noise from the fans can sometimes be perceived as disturbing by users and is of decisive importance to users as to whether or not such ventilation units mounted on radiators are accepted in rooms. The positions, the number of ventilation units installed, as well as specific spatial conditions and positions of people and furniture in the room also have an influence, to the extent that people experience this as disturbing or not.

In addition to the ventilation noise caused as a limit, perceptible moving air is also an element of possible irritation. Although the forced air flow through the ventilation unit will most likely be warmer than the ambient air that is originally drawn in from under the radiator, it will - certainly with radiators that are less high or have a lower heat exchange capacity - due to the relatively high speed can quickly be experienced as (too) cooling compared to one's own body temperature.

Experience shows that these two elements are important in the perception of comfort and are considered more important in relation to matters such as efficiency or energy efficiency that are not immediately tangible, which may or may not be achieved with the ventilation unit in combination with a user-friendly or hardly influenceable total system of thermostat settings and heat source control.

BRIEF DESCRIPTION OF THE INVENTION

The object of the present invention is to at least partially obviate the above-mentioned drawbacks or to provide a usable alternative. In particular, the object of the invention is to provide a user-friendly ventilation assembly with which the wishes and requirements of users in the field of comfort and silence can be met even better without detracting from the main objective of increasing heat exchange by means of generating a forced air flow along a heating/cooling device on which a ventilation unit of such a ventilation assembly is mounted.

This object is achieved by a ventilation assembly for conducting a forced air flow past a heating/cooling device, such as a radiator or convector, in order to increase the heat exchange thereof with ambient air according to claim 1. The ventilation assembly herein comprises: - a ventilation unit with: e a housing frame; e one or more speed-adjustable fans provided in the housing frame; e one or more coupling elements adapted for fixing the housing frame to the heating/cooling element; and - a temperature sensor adapted to measure a temperature of the heating/cooling device; and - a control unit for controlling the rotational speeds of the fans in dependence on a temperature of the heating/cooling device measured by the temperature sensor.

According to the inventive idea of the invention, it is provided that the control unit then comprises several preset increasing levels of use temperature versus speed modulation curves. Each preset operating level temperature-versus-speed modulation curve follows its own preset progression along which a temperature-dependent speed for the fans is adjusted in such a way that, in accordance with its own preset progression, at a higher resp. lower temperature of the heating/cooling device measured by the temperature sensor, a higher resp. lower speed for the fans is adjusted. Operating means are herein provided for manual selection by a user of one of the pre-set ascending usage levels of temperature versus speed modulation curves.

The present invention thus advantageously relates to a control integrated in the control unit, whereby a user can make a choice for one of the various pre-set curves, in which a voltage to be supplied to the fans and a speed related thereto for the fans are set. coupled to a changing temperature of the heating/cooling device measured by the sensor. The heating/cooling device, such as a radiator or convector of a central heating installation, concerns a heat exchanger with a heat exchange surface, which is in particular in flow communication with a heating source, such as a central heating installation, for supplying and discharging and through it pumping a heated or just cooled liquid heating medium, such as water.

This control is extremely user-friendly, and a user can easily and quickly change personal preferences in terms of sound and airflow. The directly observable effects of this make the use of the ventilation assembly pleasant and understandable for the user. This is a welcome personal setting, compared to the complicated relationship between thermostat and modulating heat source described above, and also compared to NL-2015238, where the efficiency of the use of energy seems more important than the choices of the user. . In accordance with the present invention, it has now really become possible to set personal choices in a simple and rapid manner and thus also be able to determine the feeling of comfort based on emotional factors such as whether or not the generated ventilation noise is experienced as too disturbing and whether or not the forced air flow is not perceived as too cooling.

The ventilation unit, the temperature sensor and the control unit can be integrated in a common housing, but are preferably designed as separate units that are connected to each other via wiring and/or wirelessly. This embodiment with separate units very advantageously makes it possible to position them in different places on or fix them to the heating/cooling device. These different positions can then be specifically determined by the user, so that the user can also make comfort choices with this. At the choice of the user, the ventilation unit and/or the temperature sensor and/or the control unit of the ventilation assembly can be positioned, for instance, below, above, at the inflow of the heating medium into and/or at the outflow of the heating medium. the heating/cooling device.

The temperature sensor is preferably provided on, on or in a housing of the control unit. The temperature of the heating/cooling device is preferably measured by means of contact conduction between mounting magnets of the housing of the control unit and a metal wall part of the heating/cooling device. Behind these Control Unit mounting magnets, an electrical temperature sensor can then make contact with the Control Unit mounting magnets. An alternative way of recording the temperature is to position the temperature sensor in the air stream so that the temperature of the air stream reaches the sensor and reacts accordingly. This can be done, for example, by placing the temperature sensor, whether or not together with the control unit itself if the temperature sensor has been processed, on, on or in the housing of the control unit, on the heating/cooling device.

This makes it possible to influence when, depending on a flow through the heating/cooling device with heating medium, the temperature change is always measured at a slightly earlier or later stage, and the fan speed corresponding thereto is adjusted on the basis of the preset curve. For example, when the temperature sensor is mounted, whether or not together with the control unit, close to the inflow side of the heating medium in the heating/cooling device and/or at the top of the heating/cooling device, the fans will be switched on earlier, compared to a mounting of the temperature sensor, whether or not together with the control unit, on the underside of the heating/cooling device and/or closer to the outflow side of the heating medium in the heating/cooling device, when the heating medium first reaches an upper part of the heating /cooling element has flowed through and has warmed up. When mounting the temperature sensor, whether or not together with its control unit, on the underside of the heating/cooling element, the part of the heating/cooling element positioned above it will often already have flowed through and been heated up with the heating medium, so that at that moment more heat can be exchanged due to a larger delta T between the air forced past by the ventilation unit and the heating/cooling device.

Thanks to the invention, a user can increase the efficiency of the heat transfer of his heating/cooling device, also at a relatively low temperature of the heating medium flowing through it, so that he can still heat his house sufficiently. The ventilation unit of the assembly will then always be able to come into operation quickly and continue to respond quickly to measured temperature changes. This is in contrast to, for example, the ventilation unit of NL-2015238, which will often come into operation (too) late as a result of measuring the temperature of the return pipe, namely if the radiator has long since started to heat up while the return temperature is still too high. is low compared to the ambient temperature, as a result of which the fans are not yet modulatingly activated by the control unit.

In addition, the starting point of the invention is that an intended comfort in terms of heat, sound and perceived air flows can be determined quickly and easily by the user as desired and depending on the circumstances, such as, for example, whether silence is more desirable at certain times. This may mean that the heat exchange may be sub-optimal at such a time, but the feeling of comfort is. With the simple operation of a button, it is always possible to switch directly from maximum feeling of comfort to maximum efficiency.

In a preferred embodiment, the multiple preset incremental use-level temperature versus speed modulation curves may each have its own preset maximum final speed value that is set when the temperature sensor measures a preset maximum temperature of the heating/cooling device. These own preset maximum end values for the rotational speeds are then preferably always higher at a higher level of use. This immediately increases the ease of use for the user, because it means that the user knows that setting a lower usage level will go hand in hand with a quieter ventilation unit or lower volume, forced by the user, when the final value for the chosen modulation curve is reached. felt airflow.

In particular, a voltage passed to the fans for reaching the pre-set maximum end value for the speed of a lowest of the operating levels is at least 50% lower than a voltage passed to the fans for reaching the maximum preset maximum end value for the speed of a highest of the operating levels. This advantageously allows for a sufficiently large difference in user experience in terms of comfort for each of the levels of use to be selected.

In a preferred embodiment, the multiple preset incremental use level temperature versus speed modulation curves may each follow an exponential leveling preset progression, tracking a reduced increase in speed relative to an increase in the temperature of the heating/cooling system measured by the temperature sensor. cooling element. In particular, the multiple preset incremental usage level temperature versus speed modulation curves can then each follow a different degree of exponentially leveling preset progression. In practice it has been found that such flattening curve courses fit in well with the comfort intended by users versus the efficiency increase to be achieved with a slowly rising temperature of the heating/cooling device.

According to a preferred embodiment, the control unit can indicate with a light the then selected preset operating level temperature versus speed modulation curve, and with a user depressing an operating means, such as the use of a push button, causes the light to jump to the next preset. usage level temperature-versus-speed modulation curve, with which the own pre-set course will be followed along which the speed for the fans of the ventilation unit is always adjusted relative to the temperature of the heating/cooling device measured by the temperature sensor.

In a variant of providing a push button for setting a discrete usage level modulation curve, provision can also be made for the preset increasing usage levels of temperature versus speed modulation curves to be steplessly adjustable, for instance because the operating means for this comprise a manually adjustable potentiometer.

According to a further preferred embodiment, a selection option can also be provided to allow the fans to run continuously at a preset voltage/speed, which can for instance be cooling in the summer.

In a further preferred embodiment, 3, 4 or 5 preset ascending operating levels of temperature versus speed modulation curves can be provided in the control unit, with which the coupling is established between measured temperature and changing voltage/speed of the fans. This limited number of discrete curves that can be set can still be easily overseen by a user, and each can be given an appropriate indication that corresponds to its own line of the curve that is followed, with which the coupling temperature and voltage/speed are set for that curve. fixed, for example by the aforementioned reduced lake increase.

These curves can then respond advantageously to a supplied bandwidth of temperature of the heating/cooling device on the basis of the heat source, such as for instance a combustion boiler or heat pump.

Another preferred embodiment is where the initial temperature at which the fans start running is set differently for each of the curves. This makes it easy to respond to, for example, low-temperature heating such as convectors in combination with a heat pump.

This is consistent with the method in which the heat source supplies the heating/cooling device with a medium, such as water, whereby the heating/cooling device does not suddenly reach temperature, but warms up slowly. The air flow, which increases in accordance with the course of the set curve, is advantageously geared to this, so that the right amount of air is forced for the user, so that both the demand for the increasing heat exchange can be met, but also the user's wish that the airflow and noise must be kept at an acceptable level.

The current invention thus perfectly meets the need of users for an understandable simple control with great ease of use. No complicated user manuals, but, for example, a simple push button that indicates the selected curve and makes it jump, whereby the selected position is indicated with a light. The choice is implemented immediately, so that the user immediately receives confirmation by means of the light button and can still make a different choice, whereby the user can determine the maximum sound and airflow associated with that set curve according to his/her wishes.

The unambiguous and simple use and the use of exclusively analog components make the control of the control unit of the ventilation assembly advantageously cost-efficient, so that the payback time for the user is also positively influenced.

Further preferred embodiments of the invention are defined in the dependent subclaims.

The invention also relates to a method according to claim 15.

DESCRIPTION OF THE DRAWINGS

The invention will be explained below by means of a non-limiting example with reference to the accompanying drawings.

Figure 1.

This is a graph that indicates the various example preset increasing usage levels temperature versus speed modulation curves of the control unit of the ventilation assembly, where the X-axis indicates the measured temperature by the temperature sensor and the Y-axis indicates the increasing voltage supplied to fans of a ventilation unit of the ventilation assembly. This voltage thus determines the control of the fans of the ventilation unit, wherein an increase in voltage means an increase in the rotational speed of the fans and thus the forced airflow volume to be generated.

In this drawing, a switch-on moment for each of the user levels to be set is provided with modulation curves of around 25 degrees Celsius and the curves in the graph represent the changing voltage at a changing measured temperature.

Figure 2.

The control unit (1) is indicated here, whereby it is visible where mounting magnets (2) are positioned as coupling elements of the control unit (1).

A temperature sensor is placed behind these mounting magnets (2) as part of the electrical control unit (1). The control unit (1) is supplied with electrical voltage by means of connectors (3, 8) and provides the electrical connection to the fans via a connector (3, 9).

Figure 3.

A display is shown on the control unit (1), consisting of push buttons (5) and light points (4), indicating the various operating levels of temperature versus speed modulation curves.

Visually, at the push buttons (5) it is made visible what the difference is between the usage levels temperature versus speed modulation curves.

Figure 4 .

This shows the ventilation assembly of the control unit (1) and the ventilation unit (10). The control unit (1) is supplied with electrical power by means of a power cable (8). A similar power cable (9) is led from the control unit (1) - with a usually adjusted electrical voltage signal - to the ventilation unit (10).

The ventilation unit (10) can be mounted on a heating/cooling element, such as a radiator or convector, or other type of heat exchanger (not shown), for instance on the underside thereof. The control unit (1) can be mounted on or placed on the same heating/cooling device, such as a radiator or convector, or other type of heat exchanger (not shown), for example at the top thereof. The placement of the control unit (1) containing the temperature sensor at the top means that a rising temperature with incoming hot water will be measured more quickly.

In addition, this has the advantage that a user can see the display on the control unit (1) well and can easily reach the control buttons, while the ventilation unit (10) can do its job optimally at the bottom of the radiator, convector or of such.

In addition to the embodiments shown and described, many variants are possible. For example, the gradients of the preset incremental usage levels temperature versus speed modulation curves can be changed, as well as their start and end values. It is also possible to provide a different number of modulation curves to be set by a user.

It is to be understood that these various adaptations and modifications of the presently preferred embodiments are possible without departing from the scope of the invention, and that such adaptations and modifications are covered by the appended claims.

Claims (15)

CONCLUSIONS CLAIMS 1. Ventilation assembly for passing a forced air flow past a heating/cooling device, such as a radiator or convector, to increase its heat exchange with ambient air, comprising: - a ventilation unit with: e a housing frame; e one or more speed-adjustable fans provided in the housing frame; e one or more coupling elements adapted for fixing the housing frame to the heating/cooling element; and - a temperature sensor adapted to measure a temperature of the heating/cooling device; - a control unit for regulating the speeds of the fans in dependence on a temperature of the heating/cooling device measured by the temperature sensor, characterized in that the control unit comprises a plurality of pre-set increasing levels of use, temperature versus speed modulation curves, where each preset usage level temperature-versus-speed modulation curve follows its own preset progression along which a temperature-dependent speed for the fans is adjusted in such a way that at a higher resp. lower temperature of the heating/cooling device measured by the temperature sensor in accordance with its own pre-set course a higher resp. lower speed for the fans is adjusted, and where controls are provided for manual selection by a user of one of the pre-set incremental usage levels temperature versus speed modulation curves. 2. Ventilation assembly according to claim 1, wherein the multiple preset ascending usage levels temperature versus speed modulation curves each have their own preset maximum end value for the speed that is adjusted when the temperature sensor measures a preset maximum temperature of the heating/cooling system. cooling device, whereby the own pre-set maximum final value for the speed is always higher at a higher level of use. A ventilation assembly according to claim 2, wherein a voltage passed to the fans for reaching the pre-set maximum final value for the speed of a lowest of the usage levels is at least 50% lower than a voltage passed to the fans to reach the pre-set maximum end value for the speed of a higher of the operating levels. 4 Ventilation assembly according to one of the preceding claims, in which the multiple pre-set increasing usage levels temperature-versus-speed modulation curves, each have its own pre-set minimum initial value for the speed that is adjusted when the temperature sensor measures a pre-set minimum temperature of the heating/cooling device, whereby the own pre-set minimum final value for the speed is always higher at a higher level of use. A ventilation assembly according to claim 4, wherein a voltage passed to the fans for reaching the preset minimum initial speed value of a lowest of the usage levels is at least 10% lower than a voltage passed to the fans to reach the preset minimum initial speed value of a higher of the operating levels. A ventilation assembly according to any one of the preceding claims, wherein the plurality of preset ramping usage levels temperature versus speed modulation curves each follow an exponentially leveling preset progression, tracking a reduced over-increase in speed relative to an increase in engine speed. the temperature sensor measured the temperature of the heating/cooling element. The ventilation assembly of claim 6, wherein the plurality of preset incremental usage levels temperature versus speed modulation curves each follow a different degree of exponentially leveling preset progression. 8. Ventilation assembly according to one of the preceding claims 1-7, in which at least 3, in particular 5, preset increasing usage levels of temperature versus speed modulation curves are provided. 9. Ventilation assembly as claimed in any of the foregoing claims, wherein the operating means for selecting one of the preset increasing use levels temperature versus speed modulation curves comprise a push button. 10. Ventilation assembly as claimed in any of the foregoing claims 1-7, wherein the preset increasing usage levels temperature versus speed modulation curves are infinitely adjustable. 11. Ventilation assembly as claimed in claim 10, wherein the operating means for stepless adjustment comprise a manually adjustable potentiometer. 12. Ventilation assembly as claimed in any of the foregoing claims, wherein the operating means further comprise an on/off switch for a user to set a maximum speed for the fans independently of a temperature of the heating/cooling device measured by the temperature sensor. . 13. Ventilation assembly as claimed in any of the foregoing claims, wherein the temperature sensor in the control unit is provided for measuring a temperature of that part of a convection surface of the heating/cooling device where the control unit is positioned on the heating/cooling device. and/or attached to the heating/cooling device. 14. Ventilation assembly according to one of the preceding claims, in which the preset increasing usage levels temperature versus speed modulation curves are selected on the basis of increasing maximum noise level to be produced by the fans and/or on the basis of increasing maximum by the fans along the heating system. /cooling device flow rate of forced airflow and/or on the basis of increasing maximum increase of heat exchange of the heating/cooling device with ambient air. 15. Method for using a ventilation assembly as claimed in any of the foregoing claims, comprising the steps of: - attaching the housing frame of the ventilation unit to a heating/cooling device, such as a radiator or convector, - placing it on or attaching to a heating/cooling device, such as a radiator or convector, of the control unit; - manual selection by a user of one of the preset operating levels of temperature versus speed modulation curves; - measuring a temperature of the heating/cooling device; - regulating the rotational speeds of the fans in dependence on the measured temperature of the heating/cooling device, whereby, depending on the usage level selected by the user, the control unit follows its own preset course along which a temperature-dependent rotational speed for the fans is set such that at a higher resp. lower temperature of the heating/cooling device measured by the temperature sensor in accordance with its own pre-set course a higher resp. lower speed for the fans is adjusted; and - causing the fans to carry a forced air flow past the heating/cooling device at the set speed to increase the heat exchange thereof with ambient air.