CZ17847U1 - Apparatus for monitoring structures of composite materials - Google Patents

Description

BACKGROUND OF THE INVENTION

Currently, additionally placed sensors, such as resistance strain gauges, are used to monitor structures. However, these sensors usually monitor the condition only in the immediate vicinity of the place where they are attached to the structure from the outside, usually only on the surface of the structure. They are attached to the structure mechanically or by gluing. This, however, is influenced by errors and deficiencies caused by the sensor mounting itself. The transfer of changes from the design to the sensor is influenced by the material of the element connecting the sensor to the structure and the type of connection of the structure to the sensor. By placing the sensor on the surface of the structure, it often limits the assembly and / or use of the structure equipped with the sensor.

At present, the technical solutions of construction monitoring devices are not known, using sensors located inside the structure to detect physical quantities acting on the structure, such as mechanical stress, pressure and others. Monitoring the condition and loading of concrete reinforcement and / or load-bearing elements of building structures is an important part of the overall building monitoring.

The essence of the technical solution

The technical solution according to the utility model is based on a device for monitoring structures made of composite materials by a sensing device arranged inside the composite material element, the leads of the sensing device for connection to the measuring device are led to the surface of the element.

Furthermore, the principle of the technical solution according to the utility model is that the sensing device is at least one optical fiber and / or at least one strain gauge.

The technical design according to the utility model is also based on the fact that the optical fiber axis and / or the longitudinal axis of the strain gauge is parallel to the longitudinal axis of the fibers of the composite component, from which the component is formed together with the composite matrix.

Furthermore, the essence of the technical solution according to the utility model is that the optical fiber is in place at the point. the surface of the structural element made of composite material is provided with a protective cover made of silicone insulation.

Finally, the technical design according to the utility model is also based on the fact that the composite material components to be monitored are arranged in a system whose elements are in one plane or are arranged in a spatial system.

Examples

In a first exemplary embodiment of the utility model, the composite structural member is a concrete reinforcement with a sensing device inserted into the composite matrix prior to curing, together with the fibers of the composite material. The composite material consists of fibers and a composite matrix. The composite matrix is an epoxy or polyester resin or another polymer. The fibers are carbon and / or glass. In this positive embodiment, the sensing device is an optical fiber that monitors the condition of the concrete reinforcement over its entire functional length, which corresponds to the entire length of the concrete reinforcement. This optical fiber is advantageously provided with a protective cover consisting of a silicone insulation, usually a silicone sleeve, at the point where it is led to the surface of the composite material.

-1 The sensing device monitors the state of the reinforcement when connected to an optical attenuation measuring device common in the art. In the case where the sensing device is an optical fiber, the precondition for correct measurement is its accurate placement within the composite reinforcement. Except for the points of entry and exit of the structural element, the optical fiber must never be in contact with the top of the element and must be parallel to its axis, preferably directly in the longitudinal axis of the composite material reinforcement.

In the second exemplary embodiment of the utility model, the composite material is again a reinforcement in concrete, but the sensing device inserted into the composite matrix prior to curing is a strain gauge. It monitors the condition of the concrete reinforcement only in the place where it is located in the reinforcement. The strain gauge is provided with insulated conductors prior to insertion into the composite structural member and affixed, in a specific example by gluing, to a composite material plate identical to that of the structural composite member being monitored. The strain gauge plate is made up of a bundle of flatly spaced glass-fiber elements, or of four-strand or other fibers, saturated with a composite matrix. The composite matrix is an epoxy or polyester resin or resins of other polymers. The strain gauge plate width is the same as the width of a particular strain gauge. The thickness of the strain gauge plate is always as small as possible relative to the thickness of the particular strain gauge. As a rule, its thickness is less than that of the strain gauge. After the composite matrix of the strain gauge plate has cured, the plate is shortened to the minimum specific length required, depending on the component and the method of use of the strain gauge. The thus prepared plate with the tensiometer glued is inserted into the structural element made of composite material, which in this exemplary embodiment is concrete reinforcement, so that its longer axis is parallel to the axis of reinforcement in concrete made of composite material.

The strain gauge, connected by its conductors lead to the surface of the structural element, to the electrical resistance measuring device known per se, monitors the state of the reinforcement in the concrete at its location in the composite reinforcement material. The condition of the proper function of the strain gauge is that the longitudinal axis of the strain gauge is parallel to the axis of the composite reinforcement. Strain gauge plate

-------- prevent unwanted rotation of the strain gauge before curing the composite matrix. The length of the strain gauge plate is greater than the diameter of the reinforcement, three to six times. In the manufacture, it is advantageous to protect the strain gauge terminals in the same way as protecting the optical fiber at the point where it is led to the surface of the composite material. However, the metal strain gauge conductors themselves are substantially more mechanically resistant.

In a third exemplary embodiment of the utility model, the composite member is a "I" structural profile with a sensing device inserted into the die matrix prior to curing. The composite matrix is also an epoxy or polyester resin or other polymers. The fibers are again carbon and / or glass. In this exemplary embodiment, the sensing device is an optical fiber that monitors the condition of the structural profile "T" over its entire functional length, which is equal to the length of the entire structural profile "T" of the composite material. This optical fiber should be provided with a protective silicone insulation, usually a silicone sleeve, at the point where it is brought to the surface of the composite I-profile.

The sensing device, when connected to an optical attenuation measuring device known in the art, monitors the condition of the design profile "I". Precise placement of the optical fiber within the composite construction profile 45 is a precondition for correct measurement. Except for the points of entry and exit of the structural section 'I', the optical fiber must not be in contact with the surface of the element anywhere and must always be parallel to the longitudinal axis of the structural section 'I'. However, the location of the optical fibers in the perpendicular cross-sectional area "I" of the profile is determined by which values are monitored in the given structural profile "1". The optical fiber, which functions as a scanning device, can be inserted in the web and / or in the flanges of the construction profile "I".

In the fourth exemplary embodiment of the technical solution according to the utility model, the composite material element again constitutes the structural profile "I" but with the sensing device inserted

There is a strain gauge in the composite matrix prior to curing. It monitors the status of the construction profile "1" only in the place where it is located. The strain gauge is provided with insulated conductors prior to insertion into the composite structural member and, in a specific example, adhered to the composite material strain gauge plate identical to that of the monitored structural member. The strain gauge plate is the same as that described in the second exemplary embodiment of the technical solution according to the utility model. A strain gauge connected by its conductors to the surface of the structural profile "I" to the electrical resistance measuring device known per se monitors the condition of the structural profile "I" at its location inside the "I" profile. A precondition for correct measurement is the exact placement of the strain gauge inside the constriction of the tread profile "I". The longitudinal axis of the strain gauge inside the structural profile 'Γ must always be parallel to the longitudinal axis' I' of the profile. However, the position of the strain gauge in the perpendicular cross-section of the "I" profile is determined by which values are monitored and measured in the given "I" structural profile.

All these exemplary embodiments can also be combined with each other. Both the “I” design profile and the concrete reinforcement can be used with both strain gauges and optical fibers as sensing devices. In particular, the use of optical fibers over the entire length of the spatial structural profile and strain gauges only at specific locations of these structural profiles is advantageous.

Sensing devices of both types are always a fixed and integral part of the construction elements into which they are incorporated during their manufacture. Especially for fiber-optic components, immediately after leaving the production line, these components must be protected from damage to the terminals of the sensing devices. Provide them with connectors and protect them with a solid housing of suitable shape. In this way, to prevent deterioration of the entire component equipped with the sensing device, the optical fiber outlet breaks off at the point of discharge to the surface of the component and it is not possible to connect the measuring device.

Finally, it is also possible to form a system from the above-mentioned structural elements, in particular examples of particular embodiments. Its elements are all in one plane, for example a mesh, mat or grille of the above-mentioned structural elements. Similarly, it is possible to create a spatial arrangement of these structural elements, for example when assembling known reinforcement baskets made of concrete reinforcements, which may be provided with sensing devices. In the reinforcement basket, some or all of the reinforcements may be provided with measuring elements. According to the future use of this spatial construction of composite materials.

Industrial applicability

The technical solution according to the utility model is suitable for monitoring and monitoring structures made of composite materials or composite structures in which the composite materials are used. These are combinations of composite materials with concrete, reinforced with concrete, prestressed concrete, masonry, steel and / or timber beams, etc. It is possible to monitor both composite material beams of all known profiles and tubular and solid circular and non-circular composite profiles, especially reinforcement for concrete from composite materials. The monitoring of structures can also be performed remotely, using well-known devices for the transmission of measured values.

PROTECTION REQUIREMENTS

Claims (4)

A device for monitoring structures of composite materials, characterized in that the sensing device is within the structural element of composite material, and its terminals for the measuring device are led to its surface. -32. Device according to claim 1, characterized in that the sensing device is at least one optical fiber and / or at least one strain gauge. Device according to claim 2, characterized in that the axis of the optical fiber and / or the longitudinal axis of the strain gauges is parallel to the longitudinal axis of the fibers of the composite material of which the component is formed together with the composite matrix. Device according to claim 2, characterized in that the optical fiber is provided with a silicone insulation protective cover at the point of discharging onto the surface of the structural element of the composite material. Device according to one of Claims 1 to 4, characterized in that the components made of positive material are arranged in a system whose elements are in a plane or spatially arranged. __. ________________,