EP3035281A1 - Energy efficiency analysis of a technical installation comprising simulation and consumption - Google Patents

Abstract

In order to further improve a computer-implemented method for monitoring and analyzing an energy-efficient operation of a technical installation in such a way that it can be detected in a simple, flexible and reliable manner whether the technical installation works energy-efficiently, it is proposed to include actual values of a technical parameter by simulation to compare determined setpoint values of the technical parameter of the technical system, to determine a difference value and to display or save the difference value on a display unit of the technical system.

Description

The invention relates to a computer-implemented method for monitoring and analyzing an energy-efficient operation of a technical installation, in particular a building technology and / or production engineering system. Furthermore, the invention relates to an arrangement for monitoring and analyzing energy-efficient operation of a technical system, in particular a building services and / or production engineering system. Furthermore, the invention relates to a computer program product with a computer-readable storage medium and a computer-readable storage medium, on which a program is stored, which allows a computer, after being loaded into the memory, to carry out a method for monitoring and analyzing energy-efficient operation of the technical installation.

In the context of the present invention, a technical installation is understood in particular to be building services systems and production systems. The term "technical building system" in the present context means any installation of a building, which falls in particular in one of the areas of air conditioning, refrigeration, lighting and / or heating technology, both on the producer and on the consumer side. That is, the subject technical system is preferably designed to control the amount of air, temperature, humidity, lighting and / or air quality in a building or a room of a building, for cooling or for heating. In general, such building services systems are also subsumed under the term "technical building equipment".

The term "production-technical plant" is understood here to mean all plants for the production of material goods. Preferably, the present inventive method is to be used in such production-technical systems in which compressed air is also generated as an intermediate step in the production process, since experience has shown that the corresponding control processes are not designed for high energy efficiency. In particular, in the case of present invention to such production facilities that include energy-generating and / or energy-consuming facilities.

Due to the worldwide dwindling or more expensive resources in many areas, it is required to improve the energy efficiency of technical systems, that is, to operate the corresponding technical system in such a way that it achieves the desired result with the least possible energy or resource expenditure.

State of the art

In the DE 10 2009 038 351 A1 a method for the automatic detection and representation of the operation of building services and / or production equipment is described in terms of their energy efficiency. For this purpose, measurements are carried out over a predefined total period, the measured values determined are stored and compared with fixed comparison values. The comparison results are displayed in a display. This allows conclusions to be drawn about the operation of the system with regard to energy efficiency.

DESCRIPTION OF THE INVENTION: Problem, Solution, Advantages

The invention has for its object to design a method for monitoring and analysis of energy-efficient operation of a technical system as flexible as possible, with it can be easily recognized whether the technical system works energy efficient. Furthermore, it is the object of the present invention to further improve the method such that the cause of a non-energy-efficient operation of the technical system can be determined in a simple manner.

1. a) Ermitteln eines Ist-Wertes eines technischen Parameters der Anlage mittels eines technischen Mittels für die Erfassung des Ist-Wertes. Der Ist-Wert wird dabei zu einem vorgegebenen Zeitpunkt während eines Betriebs der Anlage ermittelt; und
2. b) Durchführen einer Simulation der Anlage mittels einer Recheneinheit zur Ermittlung eines Soll-Wertes des technischen Parameters zu dem vorgegebenen Zeitpunkt, wobei der Soll-Wert dem in Schritt a) ermittelten Ist-Wert zugeordnet ist, das heißt einen Vergleichswert bzw. Soll-Wert darstellt, welcher zum vorgegebenen Zeitpunkt der Ermittlung des Ist-Wertes als Ist-Wert erwartet wird; und
3. c) Ermitteln eines Differenzwertes zwischen Soll-Wert und Ist-Wert mittels der Recheneinheit. Hierfür wird der in Schritt a) ermittelte Ist-Wert des technischen Parameters mit dem in Schritt b) durch Simulation ermittelten Soll-Wert des technischen Parameters verglichen und die Differenz gebildet; und
4. d) Anzeigen des Differenzwertes des in Schritt c) ermittelten Differenzwertes auf einer Anzeigeneinheit und/oder Speichern des Differenzwertes auf einer Speichereinheit.

According to the invention, a computer-implemented method for monitoring and analyzing an energy-efficient operation of a technical system, in particular a building-technical and / or production-technical system, is proposed for this purpose, wherein the computer-implemented method has at least the following steps:

1. a) determining an actual value of a technical parameter of the plant by means of a technical means for the detection of the actual value. The actual value is determined at a given time during operation of the system; and
2. b) performing a simulation of the system by means of a computing unit for determining a desired value of the technical parameter at the predetermined time, wherein the desired value is assigned to the determined in step a) actual value, that is, a comparison value or setpoint value represents, which is expected at the given time of the determination of the actual value as the actual value; and
3. c) determining a difference value between the desired value and the actual value by means of the arithmetic unit. For this purpose, the actual value of the technical parameter determined in step a) is compared with the setpoint value of the technical parameter determined by simulation in step b) and the difference is formed; and
4. d) displaying the difference value of the difference value determined in step c) on a display unit and / or storing the difference value on a memory unit.

The abovementioned steps a) and b) of the process according to the invention can be carried out in any suitable sequence one after the other or else simultaneously, ie in parallel. The steps c) and d) according to the invention are carried out successively and after the steps a) and b).

Preferably, a technical system from the field of air conditioning, refrigeration, lighting, and / or heating technology is provided as a building technical system. Furthermore, a power-generating plant is preferably provided as a production-technical system.

Preferably, it is provided that the technical parameter correlates with a power consumption of the technical installation, so that when determining values, ie actual values and desired values, of the technical parameter over a period of time, the energy consumption (target energy consumption and actual energy consumption) can be determined. Thus, it is preferably provided that the technical parameter is in direct or at least indirect connection with the energy consumption of the technical system.

The actual value of the technical parameter can be determined by detecting, for example, sensing, measuring and / or calculating. For this purpose, a technical means for determining the actual value of the technical parameter is provided. The technical means can be designed, for example, as a sensor device, in particular as a current measuring device.

In steps a) and b), an actual value and a desired value are determined by the same parameter.

When carrying out the simulation in step c), computation steps are performed on the arithmetic unit based on a computational model, in particular a simulation model, of the plant, it being possible to provide variable input parameters for carrying out the computation steps. The arithmetic unit can be designed as a computer unit with a processor and a memory. The calculation model or simulation model of the plant is represented by functions and / or parameters of the technical plant. The calculation model or simulation model can be stored in the memory of the computing unit and / or specified from the outside of the computer unit. The processor can determine the desired value based on the stored and / or predefined computer model or simulation model and store it in the memory assigned to the predetermined time. Thus, it is preferably provided that the simulation in step c) is carried out based on a predetermined simulation model or calculation model for the technical installation. The calculation model or simulation model contains technical data on the structure and structure of the technical system. For example, the technical data can specify a plant-technical interconnection of individual components of the technical system. By simulation or by performing computational steps based on a computational model and variable input parameters, the target value is determined as a later comparison value. The desired value maps the expected or desired value for an actual value at the given time. This desired value or expected value for an actual value is compared in step d) with the actually determined actual value.

By displaying the determined difference value between desired value and actual value, a continuous or constant monitoring of the operation of the technical system with respect to its energy efficiency can be made possible. In each case, the currently determined difference value can be displayed at the given time, until a new difference value has been determined at a subsequent predetermined time. Furthermore, difference values from successive times could be strung together on a display. By storing the difference value, the operation of the technical installation can be analyzed with regard to its energy efficiency by means of a calculation method or manually at any desired time. This makes it possible to change and optimize the setting of the technical system based on the deviation from nominal value to actual value. During the change and optimization of a setting of the technical system can be simultaneously monitored with the inventive method, to what extent the change affects the operation of the system, or whether the energy efficiency of the operation of the technical system could be improved.

In particular, by providing a simulation or by providing calculation steps based on a calculation model or simulation model of the installation, a particularly flexible, safe and simple method for monitoring and analyzing energy-efficient operation of the technical installation can be provided. Due to the provision of a simulation for determining the target values for the comparison with the actual values, a fixed specification and any subsequent manual adjustment of comparison values is not required. Furthermore, the desired values can be generated or regenerated at any suitable time. It is therefore not necessary to keep comparison values permanently stored. Furthermore, it can be ensured that comparison values always correspond to the current state. The comparison values or setpoint values can be recalculated or calculated at any time after adaptation of the calculation model or simulation model of the installation, and in particular based on the variable input parameters for the simulation.

The technical parameter is preferably an electrical current, an electrical voltage, an electrical work, an electrical power, a temperature, a mass flow, a state, a rotational speed, a humidity, a pressure or an illuminance. In particular, an electric current, a Electrical voltage and electrical power are parameters correlating and directly related to energy consumption, and thus are particularly preferably provided as technical parameters.

Furthermore, it is preferably provided that in step a) a plurality of actual values of the technical parameter are determined at predetermined different times over a predetermined total period. In step b), a plurality of desired values of the technical parameter associated with the actual values are determined at these predetermined different times over the entire period. In step c), a plurality of actual values are respectively compared with the assigned desired values for determining the difference values. Thus, it is preferably provided that steps a) to d) of the method according to the invention are carried out over a predetermined total period, for example one minute, one hour, one day, one week, one month or one year. In this case, actual values and target values can be continuously determined and compared with each other. Furthermore, actual values and setpoint values could be determined and compared with one another at regular predetermined intervals. In the simulation in step b), target values for the predefined times are determined for which actual values are determined or determined in step a). The actual values can be compared and / or stored with the target values online, ie directly at or after determination of the values, and compared with each other at a later time. Not all actual values with all setpoint values have to be compared with each other. Preferably, it is provided that values are regularly or continuously compared with one another at predetermined time intervals.

The actual values and desired values determined over the entire period are preferably displayed on the display unit in addition to the difference values. In this case, the course of the actual values or desired values over time, that is, for example, in a 2-dimensional coordinate system can be displayed. For example, the value for target values and actual values could be displayed on a y-axis and time on the x-axis. Particularly preferably, the individual successive measuring points of the actual values are connected to one another and thus the interspaces are interpolated, so that statements about times between the actual measurements or the predetermined times for the determination of the Actual values can be made. Such interpolation is also particularly preferably provided for the desired values.

Furthermore, it is preferably provided that the actual values and desired values determined over the entire period are stored on the memory unit. In this way, a later display or display of the actual values and desired values determined over the entire period of time can be made possible and an analysis of the results can be provided at any desired time.

It is also preferably provided that a display category is determined based on the difference value determined in step c) between the actual value and the setpoint value. In this case, one of a plurality of predetermined display categories is assigned to the difference value. Each display category is assigned to a predetermined value range for a difference between the actual value and the target value. Particularly preferably, at least three display categories are provided. By assigning display categories, the user or viewer can more easily and quickly recognize whether a difference value is in the acceptable, critical or possibly very critical area. For example, display categories could be represented by different colors, different patterns, or different sizes.

Furthermore, it is preferably provided that a plurality of difference values are assigned to display categories over the predetermined total period. The actual values and setpoint values determined over the entire period at different predetermined times are compared and at least several display categories are determined and displayed over time. For example, the display categories over time, that is, for example, along a time axis of a coordinate system, in addition to the difference values and / or target values and / or actual values could be displayed. Alternatively, the display categories could be displayed instead of these values. For example, the display categories over time could be represented by areas below or between curves of different colors, patterns, or sizes. In this case, a characteristic curve could represent the setpoint values and a characteristic curve the actual values. Alternatively, the display categories could be displayed separately in a separate diagram as appropriate.

Based on the actual values determined in step a) over the entire period, an actual energy consumption of the technical system is preferably determined. Actual energy consumption means the actual energy consumption of the technical installation, which was determined by measuring or determining the actual values over the entire period. Based on the target values determined in step b) over the entire period, a target energy consumption of the technical system is determined. Under a target energy consumption of the technical system is the energy consumption of the technical system to understand, which is expected based on the calculation steps or the simulation in step b). Preferably, not only the actual values or desired values determined in steps a) and b) are compared with one another, but also the actual energy consumption determined over time is compared with the determined desired energy consumption. Thus, preferably not only a comparison is carried out at different times, but also a consumption over a predetermined period of time is determined and simulated and compared with each other.

This makes it possible to make statements about individual points in time, for example peaks, but also to determine whether and how far the energy consumption varies from the expected energy consumption of the technical installation. For example, in steps a) and b) actual and nominal values for the power of the technical system can be measured. The measured current values correspond directly with the performance of the technical system, whereby the energy consumption over time can be determined from this. By comparing an actual energy consumption with a target energy consumption can be quickly and easily surveyed or recognized whether large or relevant deviations occur on average, whereupon a closer analysis of the individual times, for example, at the points of the peaks performed can be.

The actual energy consumption and target energy consumption can be represented, for example, as area under the respective characteristic curves, that is to say the characteristic curve with the actual values and the characteristic curve with the nominal values. The differential energy consumption, ie the difference between actual energy consumption and target energy consumption, thus corresponds to the area between the two characteristics. Thus, the actual energy consumption, the target energy consumption as well as the differential energy consumption be calculated and displayed in a simple manner by integral formation of the individual characteristics.

Preferably, it is provided that the simulation of the system in step b) is carried out based on at least one input parameter, particularly preferably on at least one variable input parameter, the input parameter having information on climate-related data and in particular a temperature, a humidity, a pressure or a Number of people is. Furthermore, it is preferred that the input parameter comprises or consists of standard data, in particular the DIN standard, ISO standard and / or EN standard. The input parameter is thus an initial value which is used as a basis for the simulation or the calculation steps to be carried out in step b).

Particularly preferably, the input parameter is a variable parameter which is given to the simulation. A variable input parameter is a parameter that changes over time or a parameter that can change over time. Particularly preferably, it is provided that the input parameter is an outside temperature and / or air humidity and / or air pressure of the outside environment and / or a number of persons in a building and / or code which determine the load, for example by the machines installed in the building, in the building or in the building reflected in the room. Particularly preferably, it is provided that the simulation of the system based on at least two, most preferably at least three input parameters is performed.

Preferably, the input parameter (s) may be based on historical data. In this case, for example, determined and / or typical values can be used in the past. For example, typical or past determined outdoor temperature values, possibly in function of time of day and / or season, could serve as input parameters for the simulation.

Alternatively or additionally, input parameters based on current or actually determined and / or measured values could be used for the simulation in step b). For example, the simulation in step b) could be performed in parallel to the actual determination of the actual values in step a) where actual output values, for example values for the outside temperature at the given time, are determined and serve as input parameters for the simulation. As a result, the actual environmental conditions can be specified precisely, in particular to make the analysis of weak points easier and more efficient. This also makes an online comparison or comparison of instantaneous values possible. This can be of great advantage, in particular when designing or adjusting the system.

Furthermore, it could be advantageously provided that after a predetermined period of time, for example one hour, one day, one week, one month or one year, measured and / or determined values, for example temperature values, are used for the simulation in step b) become. For example, at the end of a day, a simulation could be performed based on the climate data or other parameters determined that day (for example, number of people occupying a building that day) and then comparing the simulation results to the actual actual values.

Advantageously, a simulation could also be carried out on the basis of otherwise predetermined input parameters even before determining the actual value in step a). In this case, particularly preferably, the simulation can also be carried out before the construction of the technical installation and / or a building in which the technical installation is to be used, and thus the technical installation and / or the building can be made more energy-efficient. For this purpose, input parameters based on historical data and / or standard data are particularly suitable.

Preferably, in step a) actual values for a plurality of, that is to say at least two, different technical parameters are determined. Furthermore, in step b), preferably setpoint values are determined for a plurality of, that is to say at least two, different technical parameters. Particularly preferably, actual values or desired values are determined for at least three, and very particularly preferably at least four technical parameters.

For example, a technical parameter might represent an amperage and another technical parameter an indoor temperature in the room or building. at In this example, actual values and setpoint values at predetermined times for both the current intensity and the internal temperature in the room or building would be determined and compared with each other. The current strength of the technical system correlates with the energy consumption, which can thus be determined over time and can be compared with the corresponding desired values. By simultaneously determining and displaying the internal temperature in the room or building, for example, in a heating system or air conditioning not only the energy consumption can be considered alone, but be set in relation to the achieved indoor temperature. In this way, for example, it can be determined to what extent the actual energy consumption deviates from the expected target value and whether the desired setpoint temperature has even been reached.

The invention further provides an arrangement for monitoring and analyzing energy-efficient operation of a technical system, in particular a building-technical and / or production-technical system. The arrangement is designed for carrying out a method according to one of claims 1 to 12.

Preferably, the arrangement for this purpose has a technical means for detecting actual values of one or more technical parameters. Furthermore, it is preferably provided that the arrangement has an arithmetic unit for carrying out the simulation in step b) and for comparing the actual values with the desired values in step c). The arrangement also preferably has a display unit for displaying the actual values and / or the desired values and / or the difference values and / or the display categories, as well as a memory unit for storing the actual values and / or the desired values and / or the difference values and / or the display categories.

In this case, the determined values for the technical parameters and / or the values intended for display (actual values, setpoint values, difference values and / or display categories) can also be transmitted to a locally remote display device. For example, the display can be provided on a mobile device, in particular a portable computer, a tablet or a smartphone. According to the invention there is further provided a computer program product comprising a computer-readable storage medium having stored thereon a program which, after being loaded into the memory, allows a computer to perform a method according to any one of claims 1 to 11. Also according to the invention a computer-readable storage medium is provided for this purpose.

Brief description of the drawings

Fig. 1:

eine Anzeige der Ist-Werte, Soll-Werte und Differenzwerte in Kennliniendarstellung, und

Fig. 2:

ein Ablaufdiagramm für ein computerimplementiertes Verfahren zur Überwachung und Analyse eines energieeffizienten Betriebs einer technischen Anlage.

They show schematically:

Fig. 1:

an indication of the actual values, nominal values and difference values in characteristic curve representation, and

Fig. 2:

a flow chart for a computer-implemented method for monitoring and analyzing an energy-efficient operation of a technical system.

Preferred embodiments of the invention

In FIG. 1 a display is shown, wherein by way of example four predetermined times t1, t2, t3, t4 are shown. The determined actual values 10 and desired values 11 are shown as characteristic curves over the time t. In the example, target values 11 and actual values for the technical parameter amperage were determined.

In the in FIG. 1 As shown, the determined actual values 10 move before the predetermined time t1 and up to the time t2 in a relatively small distance and a substantially constant distance to the desired values 11. At the time t2 the determined actual values 10 essentially correspond to the expected target values 11. Between the times t2 and t4, the determined actual values 10 deviate more strongly from the expected target values 11. In particular, the largest difference value 16 was determined at time t3. Based on the desired value characteristic curve, the current should substantially decrease between the predetermined times t2 and t4 and only slightly continue at one level at time t4. By contrast, the ascertained actual values increase by 10% actual current between the predetermined times t2 and t3 on and fall only from the time t3 continuously.

As in FIG. 1 4, the difference values 16 can be graphically represented at predetermined times between the actual values 10 and the target values 11. The actual energy consumption and target energy consumption (in FIG. 1 not explicitly marked) corresponds to the area, which by the
Each characteristic is included, or the area below the respective characteristic.

In FIG. 2 3, a flow diagram of a computer-implemented method for monitoring and analyzing energy-efficient operation of a technical installation 200 is shown.

At the in FIG. 2 In the example shown, the actual values 10 of a technical parameter are determined in step 101 by means of a technical means 12 for detecting the actual values 10, and in parallel thereto in step 102 by means of a computing unit 13 (in FIG FIG. 2 not shown) and based on an input parameter 17 of the setpoint value 11 of the technical parameter determined. In step 103, the determined actual value 10 is compared with the determined target value 11 and a difference value 16 is formed. In step 104, the determined difference value 16 is displayed.

The in FIG. 2 The sequence of a computer-implemented method shown by way of example can be repeated continuously or at predetermined time intervals over a predetermined total period.

LIST OF REFERENCE NUMBERS

100

Arrangement for monitoring and analysis

200

investment

t1, t2, t3, t4

predetermined time

10

Actual value of a technical parameter

11

Setpoint of a technical parameter

12

technical means for recording an actual value

13

computer unit

14

display unit

15

storage unit

16

difference value

17

input parameters

101

Determining an actual value of a technical parameter

102

Determining a setpoint of a technical parameter

103

Compare actual value with setpoint

104

Display of the difference value

Claims (15)

Computer-implemented method for monitoring and analyzing an energy-efficient operation of a building services and / or production plant (200), comprising the following steps: a) determining an actual value (10) of a technical parameter of the installation (200) by means of a technical means (12) for detecting the actual value (10) at a predetermined time (t1, t2, t3, t4) during operation of the installation ( 200); and b) Performing a simulation of the system (200) by means of a computing unit (13) for determining a nominal value (11) of the technical parameter associated with the actual value (10) at the predetermined time; and c) determining a difference value (16) between desired value (11) and actual value (10) by means of the arithmetic unit (13) by comparing the actual value (10) of the technical parameter determined in step a) with the nominal value determined by simulation in step b) (10) 11) of the technical parameter; and d) displaying the difference value (16) on a display unit (14) and / or storing the difference value (16) on a memory unit (15). Method according to claim 1,
characterized,
that the technical parameter is an electrical current strength, electrical voltage, electrical work, an electric power, a temperature, a mass flow, a condition that a rotational speed, a humidity, a pressure or a illuminance. Method according to claim 1 or 2,
characterized,
that in step a) a plurality of actual values (10) of the technical parameter are calculated at predetermined different times over a predetermined period as a whole, and that in step b) associated with a plurality of the actual values (10) reference values (11) of the technical parameter to the predetermined different times over the total period are determined, wherein for determining the difference values (16) in step c) a plurality of actual values (10) are each compared with the associated setpoints (11). Method according to claim 3,
characterized,
that the determined throughout the period of actual values (10) and target values (11) are displayed on the display unit (14). Method according to claim 3 or 4,
characterized,
that the determined throughout the period of actual values (10) and target values (11) are stored on the storage unit (15). Method according to one of the preceding claims,
characterized,
that determined based on the in step c) difference value (16) between the actual value (a display category is determined 10) and setpoint (11), wherein the difference value (16) is assigned to a plurality of predetermined display categories a, each display category a predetermined range of values for a Difference between actual value (10) and setpoint (11) is assigned. Method according to one of claims 3 to 6,
characterized,
that determined based on the in step c) difference value (16) between the actual value (a display category is determined 10) and setpoint (11), wherein the difference value (16) is assigned to a plurality of predetermined display categories a, each display category a predetermined range of values for a Difference between actual value (10) and setpoint (11) is assigned, wherein over the predetermined total period a plurality of difference values (16) display categories are assigned. Method according to one of claims 3 to 7,
characterized,
in that, based on the actual values (10) determined over the entire period in step a), an actual energy consumption of the installation (200) is determined, based on the setpoint values (11) determined over the entire period in step b), a target energy consumption of the installation (200) is determined, wherein the actual energy consumption is compared with the target energy consumption. Method according to one of the preceding claims,
characterized,
in that the simulation of the installation (200) in step b) is carried out based on at least one input parameter (17), wherein the input parameter (17) is a temperature, a humidity, a pressure or a number of persons. Method according to one of the preceding claims,
characterized,
in that the simulation of the installation (200) in step b) is carried out based on at least one input parameter (17), wherein the input parameter (17) is based on historical data and / or on currently measured values. Method according to one of the preceding claims,
characterized,
that in step a) actual values (10) for a plurality of different technical parameters are determined, and in step b) setpoint values (11) for a plurality of different technical parameters are determined. Arrangement (100) for monitoring and analyzing energy-efficient operation of a building services and / or production plant (200),
characterized,
in that the arrangement (100) is designed to carry out a method according to one of the preceding claims. Arrangement according to claim 12,
characterized,
that the arrangement (100), a technical means (12) for detecting actual values (10) of one or more technical parameters, a computer unit (13) for carrying out the simulation in step b) and, for comparison of the actual values (10) with the reference values (11), and a display unit (14) for displaying the actual values (10) and / or the setpoint values (11) and / or the difference values (16) and / or the display categories, and a memory unit (15) for storing the actual values ( 10) and / or the setpoint values (11) and / or the difference values (16) and / or the display categories. A computer program product comprising a computer-readable storage medium having stored thereon a program that allows a computer, after being loaded into the memory, to perform a method according to any one of claims 1 to 12. Computer-readable storage medium on which a program is stored,
enabling a computer, after being loaded into memory, to perform a method according to any one of claims 1 to 11.

Images