Energy chassis and energy exchange device

Abstract

Systems, methods and devices for utilizing an energy chassis device designed to sense, collect, store and distribute energy from where it is available using devices that harvest or convert energy to locations requiring energy such as but not limited to HVAC (heating, ventilation and cooling) systems. The systems, methods and devices can also be used with a next generation geothermal heat exchanger that achieves higher energy harvesting efficiency and provides greater functionality than current geothermal exchangers.

Claims

1. A method of designing a geothermal heating and cooling system to heat or cool a building, comprising: selecting at least one geothermal heat exchanger source; selecting at least one geothermal heat exchanger sink; predicting a thermal energy demand of the building for a selected time period; predicting a thermal energy loss and gain of the at least one geothermal heat exchanger source and the at least one geothermal heat exchanger sink over the selected time period to meet the predicted thermal energy demand; determining a cost of installing and operating the at least one geothermal heat exchanger source and the at least one geothermal heat exchanger sink based upon the predicted thermal energy loss and gain; running, using a controller, a simulation of a heating and cooling system that includes the at least one geothermal heat exchanger source and the at least one geothermal heat exchanger sink; optimizing, using the controller, a type, interconnectivity, or size of the at least one geothermal heat exchanger source or the at least one geothermal heat exchanger sink based upon the determined cost and the simulation; and generating, using the controller, a geothermal heating and cooling system design that includes the optimized at least one geothermal heat exchanger source and the optimized at least one geothermal heat exchanger sink.

2. The method of claim 1, wherein predicting a thermal energy demand or predicting a thermal energy loss comprises predicting expected load.

3. The method of claim 1, wherein predicting a thermal energy demand or predicting a thermal energy loss comprises predicting occupancy of the building, a usage schedule of the building, a weather forecast, or outdoor air quality.

4. The method of claim 1, wherein predicting a thermal energy demand or predicting a thermal energy loss comprises considering insulation and conduction properties of the building.

5. The method of claim 1, wherein determining a cost of installing and operating comprises considering electrical rate data.

6. The method of claim 1, wherein the building is an existing building.

7. The method of claim 1, wherein the building is designed and not constructed, and wherein determining the cost comprises determining a cost of operating existing equipment, building material costs, and building construction costs.

8. The method of claim 1, further comprising considering at least one design limitation when optimizing.

9. The method of claim 8, wherein the at least one design limitation includes land usage, ground conditions, or ground water.

10. The method of claim 1, further comprising predicting an energy efficiency of use of the at least one geothermal heat exchanger source and the at least one heat exchanger sink over the selected time period, and wherein optimizing further comprises optimizing based upon the predicted efficiency.

11. The method of claim 10, wherein optimizing based upon the predicted efficiency comprises optimizing such that an energy efficiency ratio of the at least one geothermal heat exchanger source and the at least one geothermal heat exchanger sink is between 75 and 100.

12. The method of claim 1, wherein the simulation includes an envelope of the building, fume hood controls, or lighting configuration.

13. The method of claim 1, wherein the simulation includes various wall constructions, window placement, roof insulations, or lighting configurations.

14. The method of claim 1, further comprising predicting CO.sub.2 emission of the heating and cooling system when using the at least one geothermal heat exchanger source and the at least one heat exchanger sink over the selected time period, and wherein optimizing further comprises optimizing based upon the predicted CO.sub.2 emission.

15. The method of claim 1, further comprising predicting a building energy footprint when using the at least one geothermal heat exchanger source and the at least one heat exchanger sink over the selected time period, and wherein optimizing further comprises optimizing based upon the predicted building energy footprint.

16. The method of claim 1, further comprising predicting a building electrical usage when using the at least one geothermal heat exchanger source and the at least one heat exchanger sink over the selected time period, and wherein optimizing further comprises optimizing based upon the predicted building electrical usage.

17. The method of claim 1, wherein determining a cost of operating comprises estimating maintenance costs and energy costs.

18. The method of claim 1, further comprising obtaining building information including the size of building, and wherein predicting a thermal energy demand of the building for a selected time period comprises predicting based upon building information.

19. A method of designing a geothermal heating and cooling system to heat or cool a building, comprising: selecting at least one geothermal heat exchanger source; selecting at least one geothermal heat exchanger sink; predicting a thermal energy demand of the building for a selected time period; predicting a thermal energy loss and gain for of the at least one geothermal heat exchanger source and the at least one geothermal heat exchanger sink over the selected time period to meet the predicted thermal energy demand; determining a cost of installing and operating the at least one geothermal heat exchanger source and the at least one geothermal heat exchanger sink based upon the predicted thermal energy loss and gain; predicting, using a controller, an energy efficiency of use of the at least one geothermal heat exchanger source and the at least one geothermal heat exchanger sink over the selected time period; optimizing, using the controller, a type, interconnectivity, or size of the at least one geothermal heat exchanger source or the at least one geothermal heat exchanger sink based upon the determined cost and the predicted efficiency; and generating, using the controller, a geothermal heating and cooling system design that includes the optimized at least one geothermal heat exchanger source and the optimized at least one geothermal heat exchanger sink.

20. The method of claim 19, wherein predicting a thermal energy demand or predicting a thermal energy loss comprises predicting expected load.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 shows a schematic of the energy chassis system with a computer for controlling heating and cooling operations in a commercial building.

(2) FIG. 2 shows a schematic of the energy exchange unit with computer (i.e. the system that manages the sensing, independent routing, selecting of energy sources and uses including the computer, software, circulating pumps and variable speed drives, interconnecting piping, electrical connections, inverters, switches, fuses, wiring, sensors and control devices and the like, to manage and operate the system) for a commercial building according to a preferred embodiment of the present invention.

(3) FIG. 3 is a schematic block diagram of the energy system management computer interfaces and databases according to a preferred embodiment of the present invention.

(4) FIG. 4 is a block diagram of an intelligent independent fluid selection showing the energy exchange unit interfaced with sources/sinks and system loads.

(5) FIG. 5 is a block diagram of hybrid energy harvesting and thermal storage management according to the present invention.

(6) FIG. 6 is a schematic diagram showing multiple different independent geothermal loops.

(7) FIG. 7 is a block diagram showing the system load data according to an embodiment of the present invention.

(8) FIG. 8 shows a variety of user inputs and set points by zones.

(9) FIG. 9 shows a variety of collective data for different types of sources and sinks.

(10) FIG. 10 shows an example of different system data and equipment specifications.

(11) FIG. 11 shows energy management computer data types and different optimization target parameters.

(12) FIG. 12 shows building and system controls and examples of design method, engineering and software data.

(13) FIG. 13 is a schematic block diagram showing examples of system load signals.

(14) FIG. 14 is a schematic block diagram showing an example of an optimized control method.

(15) FIG. 15 is a process flow diagram showing process optimization.

(16) FIG. 16 is a process flow diagram showing optimization of sources and sinks.

(17) FIG. 17 shows examples of data used to design an energy chassis device and energy exchange device according to a preferred embodiment of the present invention.

(18) FIG. 18 is a process flow diagram showing an example of design optimization according to a preferred embodiment of the present invention.

DETAILED DESCRIPTION

(19) Before explaining the disclosed embodiments of the present invention in detail it is to be understood that the invention is not limited in its application to the details of the particular arrangements shown since the invention is capable of other embodiments. Also, the terminology used herein is for the purpose of description and not of limitation.

(20) The following is a list of reference numerals used in the description and the drawings to identify components:

(21) TABLE-US-00001 1 hot fluid return 2 hot fluid source 3 energy chassis 4 cold fluid return 5 cold fluid source 6 temp. indicator and sensor 7 flow meter 8 three-way control valve 9 isolation valve 10 variable volume circulation pump 11 fluid-to-fluid refrigeration-based heat pump 12 supply from warm side of energy exchange device 13 return connection to warm side of energy exchange device 14 computer-based control system 15 supply connection from cool side of energy exchange device 16 return connection to cool side of energy exchange device 17 variable volume circulation pump 20 geothermal earth heat exchanger return 21 geothermal earth heat exchanger supply 22 Vertical closed loop geothermal heat exchange 27 exchanger computer 23 horizontal, Slinky closed loop geothermal heat exchanger 29 heat exchanger 31 energy sys management computer 32 real-time load/demand 33 historical tracking of loads 34 user inputs to load predictions 35 internet/LAN interface 36 building and system sensors 37 building and systems controls 38 database, history, real-time and predicted 39 database, system updates 41 energy exchange unit 42 contoller 43 fluid control valves 44 fluid mixer 46 thermal storage unit

(22) The following is a list of definitions for terminology is used throughout the detailed description and appended claims.

(23) Coolth: The noun form of cool; opposite of warmth.

(24) Energy Demand: User driven requirements to change building set points for temperature, humidity, air quality, and electricity.

(25) Energy Sink aka Sink: An environment capable of absorbing energy from an object with which it is in thermal contact. A sink can be used for depositing, or dissipating heat. A sink can under certain conditions become a reservoir for the storage of heat or coolth energy that can then be extracted for use upon demand.

(26) Break even date: number of years until apparatus is paid off, via energy savings, tax incentives, and the like Coolth energy is sometimes used as a linguistic convenience to describe cooling as a form of energy like heat (this is common usage, but not technically correct because cool is the absence of thermal energy).

(27) Energy Chassis Device: The complete central heating, cooling and energy management system that includes the computer, software, refrigerant-based heat transfer device such as a heat pump, circulating pumps and variable speed drives, interconnecting piping, sensors and control devices, plus the electrical connections, inverters, switches, fuses and wiring and the like required to manage and control the electrical and HVAC system.

(28) Energy Exchange Device: The system that manages the sensing, independent routing, selecting of energy sources and uses including the computer, software, circulating pumps and variable speed drives, interconnecting piping, electrical connections, inverters, switches, fuses, wiring, sensors and control devices and the like to manage and operate the system.

(29) Energy Source: A device, or material from which energy can be extracted. That energy can be of any type including coolth, heat energy, or electrical.

(30) Equipment Specifications: response time, BTUor/TON capability, differential accuracy, efficiency, controllability, flow rate, energy flow rate, power usage, residual generation, cooling mechanisms and effectiveness and the like.

(31) Hybrid sources/sinks: The combination of multiple types of sources/sinks in the same system, e.g. a vertical bore geothermal field in the same system as a slinky loop horizontal geothermal bore filed, or a cooling tower combined with a solar thermal panel combined with a closed loop vertical bore field, and the like.

(32) HVAC: Heating, ventilation, and air-conditioning.

(33) Internet/LAN: Access to the internet that can be wired or wireless.

(34) Independent connections: Fluids from each source or to each sink in the system can be used independently, or mixed but are not required to be mixed as current art does.

(35) Load: Work (i.e. heating, cooling, lighting, the operation of plug in devices) that is to be done. Building load refers to the amount of energy required for the building to maintain temperature, humidity, air quality, or the energy required to meet electrical device (i.e. plug load) demands.

(36) Modular: Can be scaled up or down in size by adding or replacing units, combined with others, and can be transported.

(37) Operating cost: energy cost, maintenance cost, part replacement cost, service cost, and the like.

(38) Optimized: Optimal based on one or more optimization characteristics.

(39) Optimization target parameters include: initial cost, operating cost, lifecycle cost, break even date, energy usage, environmental impact, thermal comfort, indoor air quality and the like.

(40) Optimal system performance: when user weighted parameters are determined and the energy system is subsequently, successfully operated to those parameters with the least margin of standard error.

(41) Optimal selection: matching user weighted parameters with the least margin of standard error.

(42) Performance characteristics: Energy capacity, energy decay and gain, energy dissipation rate, efficiency, environmental impact and the like for each of the different energy types. Prefabricated: Manufactured in an offsite facility as a pre integrated, transportable, installable, unit.

(43) System data: Equipment identification and specification, piping specifications, radiant specifications, duct specifications, and the like.

(44) Thermal storage: A material, device, substance for the use of storing heat or coolth energy, e.g. geothermal, phase change, building fabric, and the like.

(45) User inputs: include desired temperature, desired humidity, predicted or planned occupancy, equipment operation schedule, ventilation and the like, for one or more heating and cooling zone.

(46) The present invention relates to systems, methods, and devices used to sense and collect local sources of naturally renewable energy, to store energy and to redistribute energy to efficiently meet building needs by using a fully integrated, factory assembled device. This device uses equipment that harvests or converts energy, stores energy and moves that energy to locations requiring energy. The device can also include optional equipment including a next generation geothermal heat exchanger that achieves higher energy harvesting efficiency and provides greater functionality than current geothermal exchangers.

(47) While the invention is described for heating and cooling of an interior space, the energy chassis device can be used to provide electrical power. For example, the energy chassis device can be connected with a variety of electrical sources such as an electrical grid, a solar photovoltaic electricity generator, a wind powered electricity generator and the like. In this example, the software would track and predict electrical usage and the cost of providing electrical from each of the sources, then determine which electrical source to use to best meet the various electrical loads.

(48) FIG. 1 is a schematic diagram of a preferred embodiment of the energy chassis system with a computer controller for controlling heating and cooling operations in a commercial building. As shown, the energy chassis device enclosure 3 includes a hot fluid return 1 connection from the heating loads, a hot fluid supply 2 connection to the heating loads, a cold fluid return 4 from the loads and a cold fluid supply 5 to the cooling loads with a temperature sensor and indicator 6 for monitoring the temperature of the hot and cold inputs and outputs and produce a corresponding temperature signal that is fed into the computer controller 14. The energy chassis device enclosure also includes a supply connection 12 from warm side of energy exchange device and a return connection 13 to warm side of energy exchange device. Similarly, the cold side includes a supply connection 15 from cold side of energy exchange device and a return connection 16 to warm side of energy exchange device.

(49) Each of the hot fluid supply 2 and the cold fluid supply 5 lines also include a flow meter 7 to monitor the flow of fluid out of the energy chassis device and a variable volume circulation pump 17 to provide hot or cold fluid directly to the loads without refrigeration system operation and allows the computer controller 14 to monitor and control the fluid into and out of the energy chassis device enclosure 3. Each hot fluid return 1 and cold fluid return 4 includes an isolation valve 8, 11. A three-way control valve 8 is provided for selectively controlling fluid into and out of each individual fluid-to-fluid refrigeration-based heat pump 11. The system can be configured to have a different quantity and size of the heat pumps 11 depending on the building that is being heated and cooled. The fluid line between the three-way control valves 8 and the heat pump 11 includes temperature sensors 6, isolation valves 9 and a variable volume circulation pump 10 in the input line between isolation valves 9 on each of the hot and the cold sides of the heat pump 11.

(50) FIG. 2 shows a schematic of the energy exchange unit system with a computer controller 27 for a commercial building. The energy exchange unit is the system component of the energy chassis device. The embodiment shown in FIG. 2 illustrates the energy exchange connected to geothermal loops. This is one possible configuration and should not be used to limit the scope of the invention as claimed.

(51) The hot and cold input 2, 5 and output lines 1, 4 of the geothermal energy exchange unit shown in FIG. 2 are similar to the configuration shown in FIG. 1 including temperature sensors 6 and variable circulation pumps 8 to and from the heat exchanger 29 and between the heat exchanger 29 and the vertical closed loop geothermal heat exchanger 32 and horizontal, Slinky closed loop geothermal heat exchanger 33.

(52) The energy exchange device is a standalone component of the energy chassis device that provides energy transfer, switching, and mixing capability to allow multiple sources of energy to be utilized simultaneously. In a preferred embodiment, the energy chassis device includes the energy exchange device as well as the heat pumps, pumps, valves piping and the like normal to a heat pump heating and cooling system. In order to improve the synergy of the system, the energy exchange determines and utilizes the most cost-effective real time and predictive combination of sources required to meet the load demand. The energy exchange then mixes and delivers the energy from the selected sources for use, possibly by multiple devices. This energy exchange device can be used to both acquire needed energy, or to manage the storage of excess energy.

(53) The co-inventors' studies of buildings being built today to ASHRAE 90.1-2007 Standard show that with the use of the energy chassis device according to the present invention, as the central component of a total building, can reduce building energy consumption by approximately 35 to approximately 50% with little, or no increase in construction cost. To achieve this level of energy savings requires that the energy chassis be a standardized product in lieu of the traditional approach which attempts to create a unique, one-of-a-kind field-constructed system within each construction project.

(54) There is a precedent for this strategy. A similar approach to creating a standardized product that embodied the technical solution for air conditioning and reduced the complexity of designing and installing air conditioning is credited to Mr. Willis Carrier who founded Carrier Corp. the largest manufacturer of air conditioning equipment. His efforts to make standardized air conditioners that could be mass marketed are generally seen as making air conditioning both reliable and affordable. This was achieved in part because he eliminated the need for a custom design and on-site assembly increased reliability. With this strategy he succeeded in building the Carrier Corporation. The energy chassis device of the present invention is designed to be manufactured in a process that includes techniques to reduce manufacturing costs and increase quality as compared to solutions that are integrated solely on the construction site.

(55) The energy chassis device consists of several primary components which may include refrigerant-based fluid-to-fluid heat pumps or chillers connected to an energy transportation system composed of PEX tubing embedded in concrete, or similar water transport devices and/or hollow core concrete that can use forced air to transport energy designed to be compatible with radiant heating and cooling and thermal storage. Plural different energy harvesting devices can be used, some existing and some not yet perfected or imagined, with software models that predict the performance of the plural different devices under a range of circumstances and provide the data required to optimize the entire system.

(56) FIG. 3 is schematic block diagram of the energy system management computer interfaces and databases according to a preferred embodiment of the present invention. As shown, the energy system management computer is interfaced with real time load/demand data 32, historical load tracking data 33, user inputs for a user to input load predictions 34 (FIG. 8) for each zone, a data base 38 for storing history, real time, and predictive data, failure or alarm notice output to system, installer, user, and/or owner and a memory to store data related to system updates, patches, add on packages 39. The energy system management computer also includes an interface with the building sensors 36 and controls 37 and an Internet/LAN interface for receiving real-time information such as weather forecast, and electrical rate structure 35.

(57) The energy chassis device computer controller includes data bases with parametric optimization models that can be executed to determine the components, component characteristics, and size that will optimize for user determined parameters for the system design. This step reduces the custom engineering required to configure the system properly for different buildings and environmental situations. The energy chassis device also includes plate and frame heat exchangers or similar for direct heat transfer without using a refrigeration system, circulating pumps with variable frequency drives, control valves and sensors as shown in FIG. 1.

(58) FIG. 4 is a block diagram of an intelligent independent fluid selection system showing energy exchange unit 41 with a computer-based controller 42 interfaced with sources and sinks A, B and C, with fluid mixers 44 and flow control valves 43 to one or more loads X, Y and Z, three in the example shown.

(59) FIG. 5 is a block diagram showing hybrid energy harvesting from different sources such as, but not limited to, solar A, geothermal B, the outdoor environment C, body heat D and other sources E to the energy exchange unit 41 shown in FIG. 4 to and from the thermal storage unit 46.

(60) Referring to FIG. 1 in conjunction with FIG. 2, each of the heat pumps 11 is piped to access the following fluid streams via various control value sequences, the hot fluid supply/return 1 and 2, chilled fluid supply/return 4 and 5, warm geothermal fluid supply/return 12 and 13 and cool geothermal fluid supply/return 15 and 16. Additional custom temperature fluids are optional. The energy chassis device includes computer controller to selectively position control valves 8, 9 and control the speed of the circulating pumps 10 to allow each heat pump module 11 to operate independently to move heat from any fluid to any other fluid.

(61) When fluid temperatures are in the range required for cooling the building space, the device can use a plate and frame heat exchanger to provide chilled fluid from the cool geothermal fluid 15 and 16 by operating the circulating pumps 10 only and not operating the refrigeration system thereby significantly reducing energy consumption and increasing energy efficiency. Additionally the system can manage the various thermal energy storage devices to add heat to, or subtract heat from the various fluid paths.

(62) The computer-based control system determines on a real-time basis the current heating and cooling current energy need and the projected energy need. In real time, using the internet, the system includes current electricity rate structures and on-peak/off-peak rate structures as well as voluntary electrical load shedding or rescheduling. Predictions for the projected energy needs are based partly upon one, or more of weather forecasts provided via internet connection and accumulated building/weather performance response history. The energy chassis system includes artificial intelligence software that uses the weather data and the building performance response history to optimize the use of energy based on one or more of the present and predicted cost of the energy and the environmental impact. Then, based upon these loads and the temperatures of the various fluid streams, the control system determines which individual fluid stream or combination of fluid streams to extract heat from or deposit heat into, to optimize energy cost.

(63) The controller also maintains communication with the next generation geothermal heat exchanger (described below) to optimize its operation with consideration for current and projected energy needs and fluid temperatures. The control system also logs all operating parameters to allow for system tuning and optimization as well as providing information related to equipment failure for trouble shooting and logs operating parameters to allow for system tuning and optimization as well as providing information related to equipment failure for trouble shooting. FIG. 9 shows a variety of collective data for different types of sources and sinks such as fabric, geothermal, phase change, etc.

(64) FIG. 6 is a schematic diagram showing multiple different independent geothermal loops connected to a central plant. This heat exchanger takes advantage of installing the intelligence and controls of the system into a standardized product that can be attached to any form of closed loop geothermal heat pump system. It uses emerging computer, sensor, and control technology, advanced heating and cooling concepts, and the ability to package the intelligence and control platform into a standardized product to increase the performance of the geothermal system while maintaining, or reducing the cost of the system. Building sensible cooling often equal to approximately 60 to approximately 80% of the total cooling load, can potentially be performed without the aid of energy consuming compressors. The heat exchanger can be used as a component of a total building energy system, or stand alone.

(65) A typical geothermal, heat pump, heat exchanger system comes in various monolithic fluid circuit configurations using only one of these: vertical closed loop, horizontal closed loop, slinky loop, pond loop, etc. but generally when applied to a system they will have the following characteristics. First, a single fluid circuit configuration is applied. For example, a vertical loop is not typically combined with a horizontal loop. Second, the fluid in the single fluid circuit is generally mixed and delivered to all heating/cooling devices at one temperature. This mixing of temperature dilutes the ability to transfer heat through a reduction of the temperature difference between the fluid and the terminal heat transfer device. The greater the temperature difference, the greater the heat transfer and conversely less temperature difference means less heat transfer.

(66) The method, systems and devices of the present invention addresses the efficiency-reducing characteristics of the said typical geothermal system by incorporating multiple independently-circuited geothermal heat exchangers, multiple independent variable speed circulating pumps, control valves to direct the fluid flow to either a warm or cool geothermal fluid header (optional as the flows can remain independent), and sensors to measure fluid temperatures and heat flow based on temperature difference and mass flow rate, or from a simple btu meter in each loop and in the warm and cool geothermal fluid headers. Computer-based controls include the software designed to optimize and manage the flows and temperatures. FIG. 7 is a block diagram showing an example of an efficient system load data according to a preferred embodiment of the present invention including real-time loads, predicted load data as well as present and historical system performance data.

(67) As shown in FIG. 7, the system determines the real time load and the predicted load and uses the load data in combination with the system performance data and historical system performance data to determine the effective system load. The system uses information such as equipment load, occupancy, humidity external environment conditions along with user inputs and the like to determine the real time load. Information used to determine the predicted load includes information such as historical weather data, historical internal loads, occupancy predictions, weather forecast, the fabric thermal mass, surface temperature and core temperature and the like as well as user inputs and set points. Examples of user inputs are shown in FIG. 8 as desired temperature, humidity, predicted and or planned occupancy of the space, equipment schedule, ventilation and the like. The user input can be by zone, for example an auditorium may be expected to have full occupancy at the same time the office space is not occupied. In this example the two zones with different predicted occupancy will have different energy requirements.

(68) The independent geothermal heat exchangers, in the configuration shown in FIG. 2, are arranged on a two-ended distribution header with separate supply and return piping that directs warmer geothermal fluid to one end and cooler geothermal fluid to the opposite end. This configuration allows unique operational characteristics including not mixing hot to cold geothermal fluid so that the temperature is not diluted and retains an ability to transfer heat because of the greater temperature differences. Second, sensible cooling devices such as active and passive chilled beams and radiant cooling panels can be supplied with much cooler water (typically 55 to 60 F.) for most, if not all, of the cooling season by only operating a circulating pump and not engaging refrigerant-based heat pumps. This is possible with the configuration shown in FIG. 2 because the novel circuiting and controls prevents the cooler independent geothermal heat exchangers from being thermally contaminated with relatively high temperature rejected heat from refrigerant-based heat rejection devices.

(69) The rejected heat from refrigerant-based heat rejection devices is circuited to the warmer independent geothermal heat exchangers where their heat is dissipated. The warmer geothermal heat exchangers become more efficient in heat recovery, in heating mode, due to the higher temperature difference between the fluid and the surrounding earth. The heat stored in the warmer heat exchangers is available as a first source for heat extraction systems that might be heating domestic hot water, etc. If the building heating load, the extraction of heat from the earth and moving it to heat the building or its systems, is greater than the heat available in only the warm geothermal heat exchangers, or if it is more efficient to do this, the cooler geothermal heat exchangers are diverted to become a heat source instead of a heat sink and thereby they will be recharged to a lower temperature to provide sensible cooling.

(70) If the annual heating/cooling demands are heating dominated, and additional heat sources are available such as solar thermal collection, one or more of the warmer geothermal heat exchangers can be designated as the hottest and it will receive any solar-generated heat that is not used immediately. This heat raises the temperature of the soil surrounding this geothermal heat exchanger and a portion of this heat will remain available for future use. This allows the system to take advantage of natural seasonal temperature swings to capture and store heat, or cool when it is available for use later in the year when it is needed. This long term thermal storage increases the availability of harvested energy for future use, resulting in increased efficiency as well as providing a mechanism to manage the total energy available in the exchangers thereby reducing the potential that the energy in the exchangers will become depleted and run short of energy.

(71) The configuration shown in FIG. 6 allows for an optimum mix of the various geothermal heat exchanger configurations (vertical, horizontal, pond loop, thermal piles, etc.) to be used simultaneously in a manner that controls and optimizes the varying thermal characteristics of each of these heat exchanger types. This will increase the opportunities to use geothermal and to more cost effectively build geothermal based on the available land. It also allows the geothermal heat exchangers to be designed specifically for long term or short term storage, hot or cold storage, or direct use a.k.a. no storage such as an open loop system.

(72) This invention also covers an alternative to said covered fluid header which is to connect every geothermal heat exchanger, heat exchanger, source/sink independently and control them independently. This would allow for full optimization and could increase efficiency even compared to the fluid header. This is due to all the same independent, direct temperature uses as described above.

(73) The computer-based controls, in coordination with energy chassis device (FIGS. 1-2) and its embedded energy exchange unit (FIG. 4) described above, will monitor and measure heat flow into and out of the ground as well as determine the thermal response characteristics of each independent geothermal heat exchanger, alternative source/sink, to allow the system operational sequences to be optimized real time and predictive as actual performance data is measured.

(74) Each independent energy source and or sink has independent performance characteristics that are stored in a data base as collective data. An example is shown in FIG. 9 with present and historical performance characteristics including, energy capacity, energy decay and gain, dissipation rate, efficiency and the like. FIG. 10 shows an example of different system data and equipment specifications that are used when selecting equipment and designing the heating/cooling system for a building. The system data includes tracing the equipment used and the specification for the equipment, the piping specifications, radiant and duct specification and specifications for any other equipment connected with the system. Each piece of equipment also has specifications and operating parameters, examples of which are shown in FIG. 10.

(75) FIG. 11 shows energy management computer data types and different optimization target parameters. When optimizing the system it is important to keep in mind the initial cost, intermediate cost and lifecycle cost. Other important parameters include energy usage, which effects the total cost, the impact usage has on the environment, and the value of thermal comfort and indoor air quality. Of course, owner and user requirements and requests should also be considered. The energy management computer maintains collective data of the sources and sinks available to the system, tracks system load data, and determines the optimized control method and controls the outputs. Initial system performance, historical system performance and historical equipment performance is maintained for use during system operation.

(76) FIG. 12 shows building and system controls for components with variable outputs including pumps, valves, and heat pumps to name a few and provides examples of design method, engineering and software data. FIG. 13 is a schematic block diagram showing examples of system load signals. For example, the system receives equipment failure signals and responds with equipment failure notification and the system data is communicated to the user, owner, hardware and/or software engineer, and installation specialist as appropriate.

(77) FIG. 14 is a schematic block diagram showing an example of an optimized method for controlling the system based on inputs from the target parameters, system data, collective data related to the system sources and sinks and the system load data. Based on the collected data, control is optimized to measure fluid temperatures and mixing of fluids for optimized performance.

(78) The flow diagrams shown in FIG. 15 and FIG. 16 show the steps for optimization of the system performance to meet the needs of the occupants of the building. As shown, data is collected and stored and used to made decisions for heating and cooling of the interior space and determining if the load requirements are met. Referring to FIG. 16, the steps include determining which sources and/or sinks to use, and which sources and sinks to mix to best fill the optimization parameters.

(79) FIG. 17 shows examples of data used to design an energy chassis device and energy exchange device according to a preferred embodiment of the present invention including independent equipment data, building material information, building construction data and shows examples of the types of data maintained on the system management computer. The examples shown are for illustration and not limitation. FIG. 18 is a process flow diagram showing an example of design optimization according to a preferred embodiment of the present invention.

(80) Experimental Results for Energy and Cost Efficiency Analysis

(81) System Performance and Description Summary:

(82) The following is a simulation of a laboratory building that has been subsequently designed and is now being built for the University of Findlay. The inventors prepared a system simulation including the building envelope, HVAC, fume hood controls and lighting configuration to provide a lower life cycle cost facility that is more energy efficient compared to standard design and construction. The simulation of this system uses the techniques described in the present patent application. The result of these efforts is an integrated building energy system design that when compared to a conventional building and HVAC practices provides substantial benefits to the University of Findlay including: 100% outside air (no recirculation) to improve occupant health and safety Up to 68% energy cost reduction and 35% maintenance cost reduction Up to 76% peak electrical demand reduction Up to 68% building energy footprint reduction Up to 68% CO2 emission reduction Annual energy and maintenance savings of approximately $1.20 per square foot of floor area Simple payback period of 4.3 years on the initial additional investment of $200,000

(83) The system is based on radiant heating/cooling technology embedded within the building structure and coupled with active chilled beams. The entire system is supplied with heating and cooling fluids from a central geothermal heat pump energy plant with a geothermal earth heat exchanger. This design uses both the short term energy storage of the thermally-massive building with the seasonal energy storage of the earth heat exchanger.

(84) When compared to a conventional HVAC System, the inventor's system has a first cost premium of approximately $200,000 based on an initial cost of $1,400,000 for the system according to the present invention versus $1,200,000 for the conventional HVAC system. These estimates do not include any potential financial incentivesthere are opportunities to reduce the first cost difference via current government incentives for alternative energy systems that are not included in the cost comparisons.

(85) Comparison to Standard HVAC System:

(86) The inventors prepared a cost estimate and energy simulation for a standard HVAC system typical for this application, but sized to handle the significant additional requirements of the laboratory fume hoods. The HVAC configuration included a variable air volume air handling unit (the penthouse was increased in size by 800 SF to accommodate this larger unit). The air handling system was supplied hot water from a new boiler and chilled water from a new air-cooled chiller. Conditioned air was fed via ductwork to variable air volume reheat boxes which were also connected to the hot water system. Note that this conventional system recirculates air from room-to-room whereas the inventors system does not. A computer-based building automation system was included in the estimate.

(87) Estimated energy savings for the inventors system are approximately $39,000 per year based on a standard HVAC energy cost estimate of $57,500 per year versus the inventions annual energy cost of $18,500 per year and the estimated maintenance savings are $7,500 per year based on a standard HVAC maintenance cost estimate of $21,500 per year versus a the inventions annual maintenance cost of $14,000 per year. This yields a simple payback period of approximately 4.3 years.

(88) Description of the Building:

(89) This project includes an approximately 40,000 square foot, two story addition to the Davis Street Facility on the University of Findlay Campus in Findlay, Ohio. Projected building use includes multiple labs with fume hoods, classrooms, faculty offices and various support spaces.

(90) Design Process:

(91) The inventors completed multiple energy simulations looking at various components within the building including wall construction, windows, roof insulation, lighting, and the like; tested various configurations of the invention and determined which areas were providing the best positive impact on overall energy use. Building operating schedules and projected fume hood usage were provided by University Staff. Utility rate structures were assumed to average $0.075/kWH and $10.00 per million BTU natural gas.

(92) A base building configuration was also prepared to give us a benchmark to which to contrast the invention design. In this case the inventors followed the US Green Building Council guideline for LEED certification and used the ASHRAE 90.1-2007 Energy Conservation Standard as the baseline for their methodology. The base case building model was assumed to be fully compliant with this standard. The simulation results were quite significant, see Table 1 which shows the proposed building using ASHRAE and LEED standards showing results for invention compared to results for standard design.

(93) TABLE-US-00002 TABLE 1 Changing from This is ASHRAE 90.1- equal to a 2007 Construction reduction to the invention of the could save following approximately percentage Peak Cooling Loads (tons) 28 28% Peak Heating Load (MBH) 179 15% Peak Electrical Demand (kW) 287 76% Annual Electrical Usage (KWH) 519,833 68% Bldg Energy Footprint (KBTU/SF/Year) 46 68% CO2 Emissions (tonnes/tear) 419 68% Maintenance Costs ($/year) 7,525 35% Energy Costs ($/year) 38,988 68% Maintenance + Energy ($/year) 46,513 59% Net Savings in Annual Maint. & Energy 1.21 59% Costs/SF

(94) The results in Table 1 are based on the full system with the proposed geothermal system and control options. These calculations were based on decisions made by the inventorsas those decisions change the energy model needs to be updated as well.

(95) Energy System Configuration:

(96) The building energy system includes the present invention; the energy chassis device that includes the energy exchange unit as shown in FIG. 5. This system monitors performance of each system component on a real time basis and in turn provides hot or chilled water to the building from the most efficient source.

(97) The energy exchange unit monitors and controls both a combination of geothermal earth heat exchangers (this is a configuration that is unique to the inventioninstead of a single, mixed-flow earth heat exchanger the present invention uses several and separate them for specific thermal applications) and other heat sources and sinks such as cooling towers and boilers.

(98) The unique energy saving opportunity with this configuration is its ability to provide chilled water for the radiant floor and active chilled beam systems without starting a heat pump for a significant portion of the year. When in this mode, the system can deliver cooling at an Energy Efficiency Ratio (EER) that is approximately 75 to 100 versus a conventional chiller EER of 10 to 15. This allows us to provide a significant portion of the cooling at an energy consumption rate that is approximately one-seventh ( 1/7th) of a regular HVAC system.

(99) The chilled or warm water is distributed via piping to both radiant cooling/heating (PEX tubing embedded in a concrete structure), active chilled beams, and reheat coils. These devices work together to provide space temperature control. Ventilation air is provided by a Dedicated Outside Air System (DOAS) located in the Penthouse Mechanical Room. This unit recovers typically wasted energy from building exhaust and uses it to pre-condition outside air used for ventilation. This system provides 100% outside air to each roomno air is recirculated from space to space. This reduces the potential for the spread of airborne contaminants and odors.

(100) All of the above systems are controlled and optimized by a computer-based direct digital control system shown in FIG. 15. This system could also provide an energy performance dashboard that could be located in a public area to provide on-going feedback on building performance.

(101) While the invention has been described, disclosed, illustrated and shown in various terms of certain embodiments or modifications which it has presumed in practice, the scope of the invention is not intended to be, nor should it be deemed to be, limited thereby and such other modifications or embodiments as may be suggested by the teachings herein are particularly reserved especially as they fall within the breadth and scope of the claims here appended.