DE102010028412A1 - Geothermal measuring probe for carrying out geothermal response test during geo-technical building ground in-situ-investigation for e.g. preparation of planned deep foundation on construction site, has open pipe arranged in hollow probe - Google Patents

Abstract

The probe has a thin downward open pipe (2) arranged in a hollow probe (1) and connected with an inlet-and drain line (7) in a fitting article (8) at a probe head (5). A geothermal response test unit (9) is connected with electro-thermal suggestion sources and temperature sensors. The sources comprise heating elements. A probe tip part (6) and/or a test probe include measurement units for acquisition of temperature. Heat carrier fluid (3) is introduced into the open pipe. Effective heat conductivity of a started building ground is determined via the test unit that is attached to the probe. An independent claim is also included for a method for carrying out geothermal response test using a directional test probe inserted into a ground.

Description

The invention relates to a geothermal measuring probe and a method for carrying out geothermal response tests. The geothermal measuring probe according to the invention is used for the determination of structural-mechanical parameters (inter alia storage density of soils, peak pressure, skin friction) and the measurement of the effective thermal conductivity of soils (geothermal response test) and temperature by probes driven or pushed into the soil. In this respect, the invention is a combination of geotechnical and geothermal exploration methods.

State of the art

For in-situ determination of the storage density of soils, ramming probes have been proven for decades and are widely used as a recognized field method.

Pressure probing is another method of determining the strength of the soil in the field by placing a pressure probe in the ground.

The determination of the effective thermal conductivity of the substrate as a relevant parameter for the design of geothermal heat exchangers is carried out in-situ via geothermal response tests / thermal response tests on test geothermal probes, test energy piles or test soil collectors. In addition, background temperatures are often recorded.

The geothermal activation of foundation piles to energy piles and the geothermal activation of other earth-contacting components for the purpose of using near-surface geothermal energy has been practiced for several years and is state of the art. In the course of the design of such complex geothermal plants, geothermal response tests on test geothermal probes or test energy piles are very often carried out for the in-situ determination of the effective thermal conductivity.

The technical expenses for the introduction of test geothermal probes or test energy piles for the purpose of performing geothermal response tests for the settling of a later energy pile system are relatively very high or expensive due to the required equipment and taking into account the sometimes only small drilling depths.

Presentation of the invention

The object of the invention is that for ground investigation z. For example, in preparation of planned deep foundations, excavations, excavation walls, heavy foundations typical exploratory methodology of Rammsondierungen / pressure probing combined with a geothermal response test technically and economically useful and so to expand the geotechnical investigations by geothermal investigations.

According to the invention, the geothermal measuring probe introduced into the underground is used at the same time as a test soil heat exchanger (fluid circuit) or thermoelectric excitation source (heating elements along the probe or at its tip) for carrying out the geothermal response test.

For this purpose, the hollow rods used for pressure probing with continuous (hollow) joints, which previously served exclusively for the implementation of the measuring cables of the pressure probes, additionally or alternatively used for the implementation of an inner tube or an electrochemical excitation source and the measuring sensors to perform a geothermal response test. In the case of ramming probing, in contrast to common practice, correspondingly continuous hollow rods are also used.

In one embodiment, a thin, downwardly open tube, which is connected to an inlet and a drain line in a fitting attachment on the probe head, and a geothermal response test unit is centered in the hollow and bottomed rod of the probe (ram probe or pressure probe) connected. Through this tube, a heat transfer fluid is introduced, which is deflected at the top of the tube and guided on the wall back up to the probe head (fluid circuit).

A further embodiment prefers, instead of a thermal excitation by means of a fluid circuit, built-in electrothermal elements for thermal excitation in the course of the geothermal response test.

According to the invention, one or more electrothermal excitation sources and temperature sensors, which are connected to a geothermal response test unit, are arranged in a geothermal measuring probe.

Furthermore, the geothermal measuring probe itself can be activated in whole or in sections as an electrothermal excitation source. The Electrothermal excitation source consists of one or more heating elements.

The method according to the invention for carrying out a geothermal response test using a directional test probe introduced into the soil is characterized in that either a hollow, downwardly open tube is introduced into a hollow probe, into which a heat transfer fluid for the geothermal response test is introduced. or in a geotechnical probe one or more electrothermal excitation sources and temperature sensors are arranged, which determine the temperature as a function of the depth. A connected geothermal response test unit determines the effective thermal conductivity of the approached subsoil as a function of the temperature behavior in the course of the electrothermal excitation.

The geotechnical exploration takes place before the geothermal probing or parallel to it.

A special embodiment of this geothermal measuring probe is used in relation to the probe length short or punctiform thermal excitation source and temperature sensors, z. B. in the probe tip, for discrete rapid determination of the substrate temperature and thermal conductivity of the substrate with gradual measurement with increasing penetration depth of the geothermal probe and used in parallel to capture the geotechnical parameters. The rapid test is evaluated either analytically or by numerical inverse parameterization.

Advantage of the invention is that at the same time different measurements (geotechnical and geothermal) can be carried out with resources that are already present in geotechnical investigations of the ground, for example for pile foundations, excavations, bung and bored pile walls on the construction sites, so that personnel costs, Material costs and costs of additional construction site facilities can be saved. Separate exploration in the course of geothermal investigations can be omitted or significantly reduced. Also, the invention enables a deep stepwise rapid determination of the thermal conductivity and temperature of the substrate.

The advantageous combination of the already known geotechnical measuring methods (ramming sounding or pressure sounding) and the geothermal measuring method (geothermal response test) brings a justifiable expense, in addition to the geotechnical measured values and in-situ measured values of the effective thermal conductivity of the substrate for design z. B. of geothermally activated deep foundations to win. In addition, the background temperature can be detected. The geothermal measuring probe according to the invention is suitable for rapid determination of the thermal conductivity.

Thus, the added value of the invention results from the effective thermal conductivity of the substrate as well as the temperature and the possibility of dispensing with large-caliber exploratory boreholes (eg scavenging boreholes with 160 mm diameter) constructed with test soil heat exchangers Diameter) for performing geothermal response tests. By using the probe according to the invention for the depth after gradual rapid determination of the thermal conductivity and temperature, the time-parallel implementation of geotechnical and geothermal investigation is possible.

Brief description of the illustrations

The invention will be explained in more detail with reference to drawings. This shows

1 the schematic structure of the solution according to the invention with a ram probe or pressure probe,

2 the inventive solution with electrothermal excitation source and

3 Probe tip with punctiform or cylindrical electrothermal excitation source and temperature sensor.

Embodiment of the invention

In 1 schematically a introduced into the soil directed test probe (ramming probing, pressure probing, etc.) is shown. This is usually introduced by a so-called ram (Rammsonde), by a hydraulic press (pressure probe) or by vibration.

Advantageously, the introduced probes are for geotechnical exploration with a closed probe tip 6 provided hollow probes 1 , which was not necessary in any case until then. The probe tip 6 or the test probe may include temperature sensing units (eg, a pressure probe).

In these hollow probes 1 Depending on the measuring method, a thin, downwardly open tube 2 introduced. Through this tube is a heat transfer fluid 3 introduced, which at the lower end of the tube 4 deflected and on the wall back up to the probe head 5 to be led. Through a correspondingly designed fitting attachment 8th at the probe head 5 (above the site) can then an inlet and a drain line 7 installed and so the fluid circuit can be realized. Via a geothermal response test unit connected to the probe 9 the effective thermal conductivity of the approached subsoil is determined.

In a further embodiment, which in 2 is shown, instead of the fluid circuit, an electrothermal excitation source 10 (eg, one or more heating elements or discrete electrothermal elements) into the hollow probe 1 introduced. The measurements of the effective thermal conductivity are carried out accordingly with a geothermal response test unit connected to the probe 9 according to 1 and also into the hollow probe 1 or in the pipe material built-in temperature sensors 12 , These temperature sensors are located on the inside of the geothermal measuring probe 12 be parallel with the pressure probe measuring cable 11 , which transmits the signals of the sensor jacket friction 13 and peak pressure 14 in the cavity of the geothermal measuring probe. The electrothermal excitation source can also be attached to the outside of the measuring probe. Another embodiment of the electrothermal excitation is that the measuring probe itself is activated in whole or in sections as an electrothermal excitation source. This can then also be a full probe, which is not shown in detail in the drawings.

A direct assessment of the nature of the soil layers, ie the direct geotechnical investigation with the extraction of soil samples can be done for example by a Rammkernsondierung at Sondierstandort. In addition, pressure probing offers the possibility of indirect detection of the existing soil layers. The exploration results can be compared with later exploration wells or production wells.

The invention makes elaborate large-caliber exploratory boreholes (flush bores, dry bores) constructed with ground heat exchangers for test borehole heat exchangers or test energy piles specially introduced for carrying out geothermal response tests by the inexpensive, rapid introduction of a hollow probe and carrying out the geothermal response test on such a substrate Hollow probe substituted.

The measuring probe according to the invention is suitable for carrying out a special geothermal response test as a rapid test for quick determination of the thermal conductivity and the substrate temperature if according to 3 in the area of the probe tip 6 a point-shaped electrothermal excitation source 17 with temperature sensor 15 is installed and a defined heat input 16 produced in the mountains. The electrothermal excitation source can also be cylindrical and then generates a line-shaped excitation to the mountains, which must be taken into account in the evaluation. The evaluation is carried out analytically and / or as numerical inverse parameterization.

LIST OF REFERENCE NUMBERS

1

hollow probe

2

downwardly open pipe

3

Heat transfer fluid

4

lower end of the tube

5

probe head

6

probe tip

7

Inlet and drain line

8th

fitting essay

9

geothermal response test unit

10

electrothermal excitation source (heating wire)

11

Pressure Probe Leads

12

temperature sensors

13

Sensorial jacket friction

14

Sensor technology top pressure

15

temperature sensor

16

heat input

17

electrothermal excitation source (punctiform)

Claims (9)

Geothermal measuring probe, which geotechnical in-situ investigations is used, characterized in that it is used in the course of geotechnical in-situ investigations for carrying out a geothermal response test. Geothermal measuring probe according to claim 1, characterized in that in a hollow probe ( 1 ) a thin, downwardly open tube ( 2 ) is arranged, which with an inlet and a drain line ( 7 ) in a fitting attachment ( 8th ) on the probe head ( 5 ), and a geothermal response testing unit ( 9 ) connected. Geothermal measuring probe according to claim 1, characterized in that in a geothermal measuring probe one or more electrothermal excitation sources and temperature sensors are arranged, which with a geothermal response test unit ( 9 ) are connected. Geothermal measuring probe according to claim 1, characterized in that the geothermal Measuring probe itself is activated in whole or in sections as an electrothermal excitation source. Geothermal measuring probe according to claim 3 or 4, characterized in that the electrothermal excitation source consists of one or more heating elements. Method for carrying out a geothermal response test using a directional test probe introduced into the soil, characterized in that a hollow probe ( 1 ) a thin, downwardly open tube ( 2 ) into which a heat transfer fluid ( 3 ) is initiated for the geothermal response test, or in a geotechnical probe one or more electrothermal excitation sources and temperature sensors are arranged, which determine the temperature as a function of the depth, and a connected geothermal response test unit ( 9 ) determines the effective thermal conductivity of the approached subsoil. A method according to claim 6, characterized in that the geotechnical exploration takes place before the geothermal probe or in parallel thereto. A method according to claim 6 or 7, characterized in that the geothermal response test is carried out stepwise in depth and a discrete measurement of the thermal conductivity and the substrate temperature is carried out as a rapid test in parallel with the detection of geotechnical parameters. A method according to claim 8, characterized in that the rapid test is evaluated analytically or by numerical inverse parameterization.

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