DE19711047A1 - Supplying heat and electricity from rotating mechanical movement according to specific demand - Google Patents

Abstract

The method involves the simultaneous and separate generation of heat and electric power produced by the rotation of a drive machine (1) according to its speed of rotation. Process and waste heat are included in the heat supply from drive machine providing the rotary movement. For a period heat can be produced in excess and stored in a heat store until required by the level of demand. Using measurement, control and automatic control equipment the supply of heat and electric power is matched to demand

Description

The invention relates to a method for needs-based Presentation of heat and electrical energy from a mechanical Rotary motion. Heat and electrical energy are separated Generated assemblies, these assemblies via coupling links the mechanical rotary movement that drives them from the drive machine received. The coupling links also have Separation functions, so that in the first case the generation of heat and electrical energy at the same time in a certain ratio due to the dimensions of the engine and Electric generator is set. In the second case in addition to the electrical energy by switching on one Energy converter additional heat, depending on the speed of the prime mover generated. The needs-based Presentation of electrical energy and heat is controlled of these two cases with the help of a tax and Control algorithm of a measurement, control and regulation system rendered. The invention further relates to a device to generate heat from a rotary motion.

The state of the art in the preferred application Combined heat and power plants (CHP) is characterized in that the nominal speed of the drive motor after the number of poles of the used electrical generator (generally about 1500 / min or 3000 / min) and the required electrical energy levy is determined. This is due to the operation of the drive motor then deliverable heat output potential arises inevitably. The system data created in this way are thus fixed specified and can only be "varied" by simply switch the CHP on and off.

The CHP systems are added according to the state of the art Improve the variability of heat generation so-called "tip kettles" that bridge the gap between the Heat presentation of the CHP and the one above close actual heat requirements.

The type of plant just described according to the state of the art owns in the first case for the CHP module in the Energy performance for fixed and electrical energy Plant sizes (always in a fixed relationship to one another!), And in the second case only a certain variability in the (heat) Energy performance by adding top boilers and Heat storage.

An adjustment of energy generation to that of the Consumers of certain energy requirements take place here by simply switching the system components ON and OFF CHP module and top boiler. Only the top boiler with his control system allows one after switching on sufficiently precise adaptation to a specific heat requirement situation.  

The task is a process and Devices for example for CHP systems with the aim to develop that greater variability in the Energy performance of heat and electrical energy in connection with a more precise adjustment of the performance for both Shaping energy to the specific energy requirement situation to reach.

The object is achieved in that the energy performance, for example in the preferred one Area of application for combined heat and power plants, under utilization the performance potential of the (CHP) drive machine via its entire speed range. According to the current status The technology uses the speed according to the number of poles Electrical generators and the required electrical energy levy determined and kept constant, the deliverable performance potential tial of heat then inevitably arises. So they are ent existing system data and can only "Varies" by simply switching the system on and off will.

For example, if there is only a partial supply of electrical energy, so it is possible the excess torque reserve at the Nominal speed via a corresponding drive train to a Device mentioned in claim 5, here as an energy converter referred to redirect. In this style of driving Energy converter the task of excess performance tial convert the engine into heat, which then one Heat storage or heat consumption system is supplied. This mode of operation is referred to below as "mode of operation 1" net.

The energy supply of heat from the drive machine is sufficient and that of electrical energy from the electrical generator without that Using the "driving style 1" just described, so in following from the "control strategy 0" ("normal" CHP control strategy) spoken.

If the required heat is required by "Driving style 0" or not covered by "driving style 1", the generation can of heat by increasing the speed of the of the Drive machine brought up to the energy converter Rotational movement increases and the requirement from the heat consumption system can be adapted as required. This Driving style is referred to below as "driving style 2".

The use of the above-mentioned driving styles is supported by the Claim 4 specified measuring, control and regulation system in Depends on the need for heat and electrical energy performed.

In Fig. 1, the "block structure of the plant with energy converter" is specified, which enables the modes of operation "0", "1", and "2" just described.

The mechanical rotary movement originating from the drive machine ( 1 ) is transmitted to a transfer case ( 11 ) via the drive train ( 18 ) with an intermediate clutch ( 2 ). From this transfer case ( 11 ), the rotary movement is guided via the drive train ( 19 ) to the electrical generator ( 4 ) for the generation of electrical energy. The electrical energy generated is passed on via the line system ( 16 ) to the inverter ( 8 ) for conversion into the 50 Hz AC voltage that is usually required by the consumers. The AC voltage generated by the inverter ( 8 ) is then delivered to the consumer (s) via the line system ( 12 ).

The use of an inverter ( 8 ) specified here requires the use of a direct current electric generator which, in contrast to synchronous or asynchronous alternating current generators, does not require such exact speed control for the generator and thus for the drive machine. However, it is also conceivable to use these generators with the corresponding synchronization device.

Furthermore, the rotary motion resulting from the drive machine ( 1 ) is guided via the transfer case ( 11 ) to the drive train ( 20 ), via the clutch ( 3 ) and the drive train ( 7 ) to the energy converter ( 5 ).

The transmission ratio for the rotary movement from the drive machine ( 1 ) via the transfer case ( 11 ) towards the energy converter ( 5 ) should be 1: 1 if possible. The reduction ratios for the rotary movement from the drive machine ( 1 ) in the direction of the electric generator ( 4 ) should be designed in as many stages as possible. With this multi-stage reduction, it is then also possible to implement "driving style 2". These multi-stage reduction ratios must be freely controllable by the measuring, control and regulating device ( 10 ).

Basically, the drive trains described can also realize via hydraulic systems, which also have the advantage a constant controllability but also have the Disadvantage of poor efficiency. Also Mixed forms of hydraulic and mechanical drives strands are conceivable.

The mechanical rotary movement generates eddy currents in the heat exchanger body ( 33 ) located in the energy converter ( 5 ), the effect of which is to produce heat in it. The heat is then transferred via a preferably liquid heat transfer medium via the line system ( 13 ) to the heat storage and heat exchange system ( 6 ). The heat storage and heat exchange system ( 6 ) also receives the heat generated by the drive machine ( 1 ) via the line system ( 14 ). The heat generated by the overall system is delivered to the consumer via the line system ( 15 ).

Furthermore, there is the possibility of using the part of unused electrical energy to generate heat in the heat exchange and heat storage system. For this purpose, the excess electrical energy is fed via the line system ( 12 ), ( 16 ) and the switching device ( 9 ) to the heating resistor body ( 21 ) in the heat exchange and heat storage system ( 6 ).

The measuring, control and regulating system ( 10 ) with the data and control line system ( 17 ) processes the information converted and received by all components of the system into electrical signals and, in accordance with the control and regulation algorithm stored in it, gives the information converted into electrical signals Control and regulation information back to the components of the system. The control and regulation algorithm realizes and controls the generation of heat and electrical energy depending on the demand registered by the consumers. It may also be the case that the driving modes "1" and "2" for generating heat are used proactively. This heat is stored in the heat storage and heat exchange system ( 6 ) to meet upcoming heat demand peaks.

The device described in claim 5, here referred to as an energy converter (5) is shown in its preferred embodiment in Fig. 2-0, Fig. 2-1 and Fig. 2-2. Due to the driving rotary movement, the circular disk ( 26 ), which is provided with permanent magnets ( 25 ) on the edge of the disk ( 26 ) and is rotatably mounted in the center, is caused to rotate. The permanent magnets ( 25 ) cause the greatest magnetic induction if they face one of the outer yoke struts ( 27 ) directly during the rotation of the disc ( 26 ) and only separated by a minimal air gap.

With the same polar orientation of the permanent magnets ( 25 ), the magnetic flux starting from the permanent magnets ( 25 ) via the disc ( 26 ), its rotatable mounting ( 24 ), the inner yoke strut ( 32 ) with a subsequent minimal possible air gap transition with subsequent passage through the heat exchanger body ( 33 ), with another subsequent minimal possible air gap and the subsequent outer yoke strut ( 27 ) back to the opposite pole of the permanent magnet ( 25 ) just considered.

For unequal polar alignment of the permanent magnets (25) with the same possible number of permanent magnets (25) for both groups polarity conduction is the magnetic flux in principle only through the outer Jochstreben (27) with the omission of the inner Jochstrebe (32).

The permanent magnets ( 25 ) cause the minimum possible magnetic induction by the heat exchange body ( 33 ) if they are obviously in the geometric center between two outer yoke struts ( 27 ) during the rotation of the disk ( 26 ). You then have the largest air gaps to the outer yoke struts ( 27 ).

The number of permanent magnets ( 25 ) does not necessarily have to exactly match the number of outer yoke struts ( 27 ), which in particular then has an effect on the smooth running of the energy converter ( 5 ).

With the situation of the changing magnetic flux through the heat exchange body ( 33 ) just explained, eddy currents arise in it according to the law of induction, which are fully converted into heat in their effect.

The application of the above operating modes "0", "1" and "2", as well as the preferred shown in FIG. 1 "block structure of the system with energy converters" by taking advantage of the claims 1 to 5 Fig. 3 shows.

In Fig. 3, with the help of the dotted and dash-dotted lines, the typical heat and electrical energy requirements of a housing estate are assumed for a course of the day from 0 to midnight. In the period from approx. 4 a.m. to 9.30 a.m., the satisfaction of the electrical energy requirement by driving style "0" has priority. The peak heat demand pending during this period is satisfied by the forward-looking generation of heat and its storage in the heat storage system in the period from 0 to about 5 o'clock. In the period from approx. 3 p.m. to midnight, the priority satisfaction of electrical energy through driving style "0" has priority. The heat demand peak also occurring in this period is satisfied, as just described, partly in the previous night hours and in the period from approx. 10 a.m. to 3 p.m. by the forward-looking generation of heat and its storage in the heat storage system.

The advantages of the method and the device according to Claims 1 to 5 result in particular in the preferred Application in the CHP area an exact adjustment of the Presentation of heat and electrical energy to a concrete one Heat and electrical energy requirement situation.

The planning processes for a plant in concrete application case are simplified because there are only values for the Electrical energy and heat supply with information for the Storage capacity of the heat storage to be used systems necessary.

The control of the energy presentation is via the measurement, Control and regulation system made. With the help of this MSR-Systems is, for example, according to the rules of "FUZZY- Logic "or with elements of" artificial Intelligence "the energy supply of heat and electrical energy in connection with an optimal use of primary energy carries out. The saving in primary energy use leads to Reduction of ongoing operating costs and to protect the Environment.

In the CHP area, it is by application of claim 1 up to 5 possible very compact plants in one they tight enclosing system housing. This has the Advantage that a smaller space requirement for the system is needed. Furthermore result from the compact installation of the system in a system housing and by eliminating the otherwise necessary "top boiler and its Exhaust system "far lower assembly costs. The system will this means it can be installed and put into operation faster.  

The use of the energy converter usually makes one smaller drive machine required, so that this Investment costs for the entire system are also reduced will.

Claims (5)

1. A method for the needs-based presentation of heat and electrical energy from a mechanical rotary movement, characterized in that electrical energy and heat are generated simultaneously and separately by the rotary movement of the drive machine and in dependence on its speed. 2. The method according to claim 1, characterized in that Process heat and waste heat from the rotary motion Drive machine is included in the heat presentation. 3. The method according to claim 1 and 2, characterized in that Heat is generated before a period of increased heat demand and then the heat up to the demand in one Storage system. 4. The method according to claim 1 to 3, characterized in that the performance by a measuring, control and regulating device of heat and electrical energy is adapted to the needs. 5. Apparatus for carrying out the method according to claim 1 to 4, characterized by a rotary adapter introduced via a connection adapter ( 23 ) onto the rotary circular disk ( 26 ) driven by it with a centrally arranged rotatable bearing ( 24 ) consisting of magnetically conductive material and with permanent magnets ( 25 ) attached to the disc edge for generating a magnetic flux in connection with induction of eddy currents in a heat exchange body ( 33 ) as a result, one or more inner yoke struts ( 32 ) with a receptacle at one end for the rotatable mounting ( 24 ) of the circular rotating disk (26) not to touch for conducting the magnetic flux to the heat exchange body (33) and with the property of the heat exchange body (33) directly, one or more outer Jochstreben (27) for directing the magnetic flux from the on the edge of the disk ( 26 ) attached permanent magnets ( 25 ) of the rotating kr out with the property not to touch eisrunden disc (26) to the heat exchange body (33) the permanent magnets (25) and the heat exchange body (33) directly to a heat exchange body (33) from elektrischleitfähigem material for converting the voltage induced in it electrical power into heat, a heat transfer medium ( 35 ) surrounding the heat exchange body ( 33 ) for transferring the heat generated in the heat exchange body ( 33 ).