It is noted that citation or identification of any document in this application is not an admission that such document is available as prior art to the present invention.
The present disclosure relates to a water heater comprising a heat pump device and a method for controlling a heat pump device in a water heater.
Air/water heat pumps for providing energy to heat up tank-type water heater are well known. Air/water heat pumps use ambient air as a heat source. Such water heaters utilize temperature sensors and temperature controls to detect the current tap water temperature for comparison with a set temperature. If the hot water temperature inside the water tank of the water heater declines below an activation temperature that is less than the set temperature, the heat pump is set into operation to heat up the water until the water temperature equals the set temperature again. Hence, the operation of the heat pump is controlled by the temperature controller.
The heating capacity of a heat pump device depends on the temperature of a heat source and diminishes if the temperature of the heat source decreases. Consequently, it takes more time to heat up the water in the water tank to the set temperature. If the recovery time of the water tank is increased there is a risk of user dissatisfaction because of a reduced comfort on the users end of the water heater. Therefore, many water heaters are provided with an additional electrical heat element to accelerate the heat up process of the water in this type of situation. A disadvantage of the electrical heat element is that it needs more electrical energy to heat up the water in the water tank compared to the heat pump device.
Therefore, there is an approach for providing a water heater with a heat pump that is capable of meeting the comfort expectations of the user in all heat source conditions without necessarily needing an additional electrical heating element.
Throughout the following specification a distinction is made between the terms “temperature” and “temperature value”. The term “temperature” is associated with the physical temperature of a medium, in particular the temperatures of water and air. The SI unit of temperature is Kelvin (K). In practice the most frequently unit is degree Celsius (° C.) in Europe and degree Fahrenheit (° F.) in the US. The term “temperature value” is associated with an output signal of the temperature sensor device measuring a temperature of a medium, such as a temperature sensor output a 2V DC signal when measuring the water temperature of 60° C. Likewise the term “temperature value” is used for the input into a temperature controller—for example, setting a set temperature value.
According to a first aspect of the present disclosure a water heater is suggested. The water heater comprises a heat pump device and a water tank containing water. The heat pump device comprises a heat exchanger, which is in thermal contact to the water in the water tank, and a temperature controller unit to control the water temperature by switching the heat pump device on and off. The temperature controller is connected to a temperature sensor detecting the temperature of the water inside the water tank and distributing a corresponding water temperature value to the temperature controller. The temperature controller compares a set temperature value with the detected temperature value. The set temperature corresponds to a water temperature desired by the user. It might be a fixed temperature or it might change dynamically as a function of time. The temperature controller is arranged for switching the heat pump device on, if the water temperature drop lower than a activation temperature, which is smaller than the set temperature, and switches the heat pump off if the water temperature exceeds the set temperature. The water heater further comprises a heat source temperature sensor detecting the temperature of a heat source providing thermal heat to the heat pump device. The source temperature sensor measures a source temperature and provides a reservoir temperature value to the temperature controller. The temperature controller updates the activation temperature in response to the measured source temperature. The suggested water heater provides an improved accuracy of the temperature controller taking a reduced cycling rate into account in order to provide a long life expectancy of the heat pump device as it will be explained in greater detail further below.
According to an embodiment the source temperature sensor is configured to measure temperatures of ambient air. The ambient air surrounds the heat pump device and serves as a heat source in particular for air/water heat pumps. Therefore, it provides operational advantages to track the ambient air temperature because it influences the heating performance of the heat pump device. The temperature of the ambient air can be used to modify the control parameters of the heat pump device, in particular to modify the activation temperature.
In an advantageous embodiment of the water heater the adapted activation temperature remains a predefined temperature difference below the set temperature. The temperature difference between the activation temperature and the set temperature avoids that the heat pump device is cycling during operation. This is because if the cycling rate is to much a result is s reduced life expectancy.
It has been found useful if the water heater comprises a user interface receiving a user input with regard to the set temperature value and providing the set temperature value to the temperature controller. The user interface can be a temperature set point device, for example.
According to a second aspect the present disclosure suggests a method for controlling a heat pump device in a water heater comprising a water tank and a temperature controller controlling the operation of the heat pump device. The method comprises
In a particularly advantageous embodiment the method further comprises increasing the activation temperature if the heat source temperature decreases.
The embodiments of the suggested method provide an improved accuracy of the temperature controller and limiting the cycle rate taking the life expectancy of the heat pump device into account.
Further advantages of the present disclosure will become apparent when reading the detailed description accompanied by the drawing.
Exemplary embodiments of the present disclosure are illustrated in the drawings and are explained in more detail in the following description. In the figures similar or same elements are referring with the same or similar reference signs.
It is to be understood that the figures and descriptions of the present invention have been simplified to illustrate elements that are relevant for a clear understanding of the present invention, while eliminating, for purposes of clarity, many other elements which are conventional in this art. Those of ordinary skill in the art will recognize that other elements are desirable for implementing the present invention. However, because such elements are well known in the art, and because they do not facilitate a better understanding of the present invention, a discussion of such elements is not provided herein.
The present invention will now be described in detail on the basis of exemplary embodiments.
The water heater 1 further comprises a temperature sensor 14 measuring the temperature of the ambient air serving as a heat source for the air/water heat pump device 2. It is noted that the present disclosure is not limited to air/water heat pumps but equally applicable to geothermal and hydrothermal heat pumps as well. Therefore, the temperature sensor 14 is referred to a source temperature sensor 14 because it measures the temperature of the heat source. An electrical connection 16 connects the source temperature sensor 14 with the temperature controller 12.
Temperature controller 12 controls a relay 17, which is electrically connected by a line 18 with a temperature controller 12. If the temperature of the tap water 6 in the water tank 3 drop more than a predefined temperature difference below the set temperature, the relay 17 set the heat pump device 2 into operation in order to heat up the tap water 6 in the water tank 3 until the water temperature exceeds again to the set temperature. The relay 17 is only an example for any other suitable control element like semiconductor triac switches to control the operation of the heat pump device 2.
It is noted that the heat pump device 2 is not activated immediately once the temperature in the water tank 3 drop below the set temperature. The heat pump is activated once the water temperature in the water tank 3 is less than the predetermined activation temperature. This arrangement avoids a unwanted cycling rate of the heat pump device 2. The temperature difference between the set temperature and the activation temperature effectively creates a switching hysteresis having a positive impact on the life expectancy of the heat pump device 2 on the one hand. On the other hand the switching hysteresis influences the precision of the temperature controller as it will be explained with reference to
The temperature control accuracy in the example shown in
For a predetermined set temperature Tset and a adjusted heating power depending on the viability of the heat source for the heat pump device 2 the selection of the activation temperature determines the duration of the heating phase and the accuracy of the temperature control. In particular, if the activation temperature is approaching the set temperature the heating phase becomes shorter and the temperature control accuracy increases. As it can be taken from a comparison of
The present disclosure suggests exploiting the interdependency of the switch-on temperature, the heating phase and the temperature control accuracy for solving the problem of extended heating phases of a water heater utilizing an air/water heat pump for heating up water that has been discussed in the introduction.
Specifically, the embodiment shown in
Finally, it is noted that the present invention is not limited to water heaters displaying a linear or essentially linear increase or decrease of the water temperature during heating up and cooling down of the temperature as shown in
While this invention has been described in conjunction with the specific embodiments outlined above, it is evident that many alternatives, modifications, and variations will be apparent to those skilled in the art. Accordingly, the preferred embodiments of the invention as set forth above are intended to be illustrative, not limiting. Various changes may be made without departing from the spirit and scope of the inventions as defined in the following claims.
1 water heater
2 heat pump device
3 water tank
4 tap water, drinking water
6 insulation layer
7 fan
8 condenser
9 temperature sensor
11 electrical connection
12 temperature controller
13 temperature set point device
14 source temperature sensor
16 electrical connection
T water temperature
Tset set temperature
T1, T2 activation temperature
Tm1, Tm2 average temperature
S1-S7 method steps