RU140181U1 - DEVICE FOR DETERMINING CONCRETE STRENGTH - Google Patents

Abstract

1. A device for determining the strength of concrete, comprising a housing with an aperture in which a vertical rod is mounted with the possibility of longitudinal movement and rotation relative to the housing, rigidly connected at one end to an anchor device and the other with a mechanism for pre-tensioning the anchor device, and an electronic unit placed in the housing connected to the pressure sensor, a piston pump connected by channels formed in the housing to at least two hydraulic cylinders, the rods of which are coaxially connected to supports, characterized in that a second piston pump is installed, the pumps are connected through a gearbox to a common drive, and elements for controlling the position of the pistons in the initial and final positions are placed in the piston pumps. 2. A device for determining the strength of concrete according to claim 1, characterized in that the hole in the housing is made axial. 3. A device for determining the strength of concrete according to claim 1, characterized in that the axes of the piston pumps are parallel to the longitudinal plane of the housing. 4. A device for determining the strength of concrete according to claim 1, characterized in that the supports are made equidistant from the axial hole and placed in the longitudinal plane of the body. A device for determining the strength of concrete according to paragraphs. 1 and 4, characterized in that the supports are made adjustable in length. 6. A device for determining the strength of concrete according to claim 1, characterized in that the elements for controlling the position of the pistons in the initial and final positions are made in the form of magnetoresistors connected to the electronic unit. A device for determining the strength of concrete according to claim 1, characterized in that the casing has the advantage

Description

The utility model relates to measuring equipment, namely, devices for determining the strength of concrete by tearing off with shearing during technological quality control of monolithic and precast concrete, when examining buildings, structures, products and structures.

The prior art devices for the operational control of the strength of concrete, the principle of operation of which is based on the existing relationship between the strength of concrete and the value of the force created when the anchor device is fixed in the concrete under study.

A device for testing devices is known (RU 2212663, IPC G01N 33/08, publ. September 20, 2003), comprising a housing with extendable supports and a hydraulic cylinder having a working piston with a hollow rod, a pump, an anchor device, a rod with a hard anchor anchor fixtures, a micrometric nut structurally connected with the rod in the area of the anchor fixture rigid fixing unit, a quick-detachable washer for fixing the rod, the helm and the recording device.

A disadvantage of the known device is its large weight and overall dimensions, which makes it difficult to carry it over long distances and operation during measurements.

As the closest analogue, a power device for testing concrete of building structures (RU 2271528, IPC G01N 3/00, published March 10, 2004) is adopted, comprising a horizontal housing with a central hole for a rod located along the vertical axis of the housing with the possibility of its longitudinal movement and rotation relative to the housing, rigidly connected to the anchor device, and the pre-tensioning mechanism of the anchor device in the form of a traction drive mounted on the steering wheel housing mounted on the upper threaded end of the traction. The housing is equipped with retractable bearings equidistant from the vertical axis of the housing, made in the axial longitudinal plane of the housing, a piston pump with a manual drive connected by channels made in the housing with a loading device made in the form of two hydraulic cylinders located on the same axis with sliding supports connected to the rods of the hydraulic cylinders moreover, one support is made U-shaped and connected to the hydraulic cylinder rod with the possibility of rotation, the second support is made in the form of a height-adjustable cap with a con catfish, connected to the rod by a threaded connection, and the piston pump axis extends in the housing parallel to the longitudinal plane.

In the constructions of the known devices, there is one piston pump that creates a pressure of the working fluid, which, through the channels formed in the housing, enters the hydraulic cylinders and associated supports. The presence of only one piston pump limits the limit force exerted on the anchor device in order to break it out of concrete to 50 kN (5 tons), which naturally limits the scope of application of the devices.

The piston pump drive is manual: the user evenly twists the drive handle to the required loading of the anchor device, or until it is pulled out of concrete. Moreover, in the known constructions there are no elements limiting the piston stroke or indicating that the piston is in the initial or final positions. The user, while not having the ability to visually monitor the position of the piston, continues to twist the handle when the piston is in the extreme positions, which leads to damage to the piston pump (jamming, mechanical damage, etc.).

The problem to which the present utility model is directed is to increase the value of the created ultimate force applied to the anchor device and increase the reliability of the device.

The solution to this problem in a device for determining the strength of concrete, containing a housing with an aperture in which a vertical rod is mounted with the possibility of longitudinal movement and rotation relative to the housing, rigidly connected at one end to the anchor device, and the other with the pre-tensioning mechanism of the anchor device, and placed in the housing an electronic unit associated with a pressure sensor, a piston pump connected by channels formed in the housing with at least two hydraulic cylinders, a rod and which are coaxially connected to the supports, is achieved by the fact that a second piston pump is installed, the pumps are connected through a gearbox with a common drive, and elements for controlling the position of the pistons in the initial and final positions are placed in the piston pumps.

The hole in the housing is made axial.

The axes of the piston pumps are parallel to the longitudinal plane of the housing.

The supports are made equidistant from the axial hole and placed in the longitudinal plane of the housing.

The supports are made adjustable in length.

Elements for controlling the position of the pistons in the initial and final positions are made in the form of magnetoresistors connected to the electronic unit.

The housing has a predominantly horizontally oriented box shape.

The pre-tensioning mechanism of the anchor device is made in the form of a helm mounted on the upper threaded end of the rod.

The piston of the piston pump is made hollow, connected by a threaded connection to a drive screw, interacting through a gearbox with a drive.

The piston pump drive can be either manual or made in the form of an electric drive.

The pressure sensor interacts with one of the hydraulic cylinders.

Thanks to the introduction of a second piston pump, which works simultaneously with the first pump, into the design of the known device, an increased degree of injection of the working fluid (oil) into the hydraulic cylinder system is provided, which leads to the possibility of increasing the value of the created ultimate force applied to the anchor device to 100 kN (10 t ), while the mass-dimensional characteristics of the device are slightly increased in comparison with the prototype. So a prototype with one piston, which creates a maximum force of up to 50 kN (5 tons), weighs up to 4 kg, and the device according to this utility model with two pistons up to 6 kg.

The presence of two piston pumps with a common drive ensures a smooth piston stroke, a uniform distribution of the generated working fluid pressure between the channels. The introduction of the gearbox reduces the force exerted on the handle of the drive, which increases the operational properties of the device.

In contrast to the prototype with one piston and two channels, one of which is "spurious", i.e. not working, but perceiving the loading force of the working fluid created by the piston of the second channel, in the proposed utility model both channels are working, which increases the efficiency of the hydraulic system of the device.

The presence of elements for controlling the position of the pistons, made in the form of magnetoresistors connected to the electronic unit, increases the reliability of the device and the service life, due to the fact that the magnetoresistors change their electrical resistance when the pistons are in extreme positions, the electronic unit records this change and displays text warning about overloaded piston overloads.

The essence of the utility model is illustrated by drawings: in FIG. 1 is a side view of the device, in FIG. 2 is a front view of a device with local cuts, in FIG. 3 is a top view of the device (longitudinal section AA).

A device for determining the strength of concrete contains a housing 1, made in the form of a predominantly horizontally oriented parallelepiped with a central axial hole 2, in which a rod 3 is vertically mounted with the possibility of its longitudinal movement and rotation relative to the housing 1. The lower end of the rod 3 is connected via a threaded connection to the anchor device (not shown in the drawing), fixed in the test material (concrete). The upper end of the rod 3 is connected via a threaded connection to the removable steering wheel 4. The rod 3 is mounted with the possibility of its removal from the hole 2 of the housing 1 with the steering wheel removed 4. The mechanism for pre-tensioning the anchor device, including the rod 3 and the steering wheel 4, carries out the tension of the anchor before the measurement process .

In the housing 1 there are two equidistant from the central axial hole 2 adjustable along the length of the support 5, located in the axial longitudinal plane.

In the housing 1 there are two piston pumps 6 installed in two symmetrically arranged channels 7, connected through a gearbox 8 with a manual drive with a handle 9, the axis of which coincides with the longitudinal plane of the housing 1.

The piston pump drive 6 can be made in the form of a low-power electric drive, for example, organized by an electric drill, screwdriver, etc.

The pistons 10 of the piston pumps are mounted with the possibility of longitudinal movement along the channels 7. To avoid deviations from the axial movement of the pistons 10 are fixed with guide keys 11.

The pistons 10 are hollow and threadedly connected to the drive screws 12, which interact through the gearbox 8 with the drive 9. When the drive handle 9 is rotated, the torque is transmitted through the drive shaft and gearbox 8 to the drive screws 12, which twist or screw the pistons 10 (depending from the direction of rotation of the handle of the actuator 9), the pistons 10, in turn, making translational motion along the channels 7, reduce or increase the volume occupied by the working fluid in the channels 7.

Piston pumps 6 are connected via channels formed in the housing to a loading device. The loading device is made in the form of two hydraulic cylinders 13, connected coaxially with the supports 5. In this case, one support 5 is made U-shaped (in the form of a “shoe”), mounted on the rod 14 of the hydraulic cylinder 13 with the possibility of rotation by means of a locking screw. The U-shaped support ensures the stability of the device in the transverse direction when it is installed on the concrete surface during the measurement. The second support 5 is made adjustable in height, connected to the rod 14 by means of a threaded connection. During the operation of piston pumps 6, the working fluid is pumped into the hydraulic cylinders 13 from the channels 7.

In the working position, the device is based on supports 5 on the concrete surface at three points, centered with a rod 3, rigidly connected to the anchor device fixed in the hole and preloaded by the helm 4.

In the upper outer part of the housing 1 there is an electronic measuring unit 15 for processing data and displaying results, associated with a pressure sensor 16 interacting with one hydraulic cylinder 13. The electronic measuring unit 15 includes a microprocessor, a graphic display, a keyboard and a connector for communication with a computer. The display and keyboard of the electronic measuring unit are located on the upper front panel of the housing 1. The display is equipped with a switchable backlight.

Piston pumps 6 are equipped with elements for controlling the position of the pistons 17 during the forward (loading) and reverse (unloading) stroke of the pistons 10, made in the form of magnetoresistors. The magnetoresistors 10 are placed in the initial and final positions of the pistons 10 of the pumps 6. When the pistons 10 reach the initial and final operating positions, the magnetic field of the magnetoresistors 17 changes sharply, causing a change in their electrical resistance, the electronic unit 15 captures this change and displays a text warning, accompanied by a sound signal.

The device provides overload protection by force: when a breaking force of 100,000 N (100 kN) is reached, the pressure sensor 16 transmits a signal to the electronic unit 15, the display of which displays a warning message, accompanied by an intermittent sound signal.

The operation of the device is as follows.

An anchor device is installed in a pre-prepared hole or concreted at the stage of manufacturing a structure or object in accordance with GOST 22690-88 “Concretes. Determination of strength by mechanical methods of non-destructive testing. "

The hole is drilled with a rotary impact tool, while its deviation from perpendicularity should not exceed 4 mm to a height of 100 mm.

After drilling, the hole is thoroughly cleaned of dust and concrete chips, for example, by blowing with compressed air and, if necessary, calibrated in diameter, for example, with a jumper.

Using a special boring device, similar to that described in patent RU 2271528, an annular groove is made in a hole for reliable adhesion of concrete to the anchor device. The groove is performed at a given capture depth.

An anchor device assembled with segments is installed in the hole, such that the dimensions of the anchor device correspond to the parameters of the hole, and the diameter of the hole must not exceed the diameter of the anchor device by more than 1 mm. The protrusions of the segments of the anchor device must fall into the groove.

Screw the lower end of the rod 3 with an interference fit on the anchor device.

The device is installed on the surface of the test material by passing the rod 3 fixed on the anchor device into the central hole 2 of the housing 1. The helm 4 is screwed onto the upper threaded end of the rod 3, pulling the anchor device, leaving a gap between the end of the helm 4 and the housing 1, corresponding to about half a turn helm 4.

The device is rotated around the rod 3 in such a way as to find a stable position for the supports 5 and the possibility of convenient rotation of the handle of the actuator 9.

After choosing the best position, the supports 5 are adjusted, turning them up to contact with the concrete surface, tighten the helms4, creating a preliminary tension of the rod 3 with the anchor device (up to 5 kN), which is necessary for reliable positioning of the device on the concrete surface at three reference points (two supports 5 and thrust 3).

When tightening the helm 4, the anchor device should not slip in the hole. Otherwise, reinstall the anchor device after additional deepening of the grooves to ensure reliable adhesion of concrete with segments.

Turn on the electronic unit 15 of the device.

Using the keyboard in the electronic unit 15 enter the values of the size of the anchor device, the type of concrete and the conditions of its hardening (normal hardening or heat treatment).

In the memory of the electronic unit 15 can be entered information about new materials that are being investigated by peeling with chipping.

Press the key of the electronic unit 15, the device goes into measurement mode.

Evenly rotating the handle of the actuator 9 in a clockwise direction, the anchor device is loaded, while the loading speed is maintained within 1.5-3 kN / s, indicated on the linear indicator of loading of the electronic unit 15. During the entire test cycle, the loading speed is monitored by the indicator.

When the threshold load force of more than 2 kN is reached, the display of the electronic unit 15 will automatically switch to the indication mode of the loading process, i.e. will display information about the strength value.

When the handle of the drive 9 is rotated, torque is transmitted through the drive shaft and gearbox 8 to the drive screws 12. Rotating, the drive screws 12 translate the pistons 10, which move along the channels 7 in the direction from the handle 9. The working fluid displaced by the pistons 10 from the channels 7 enters the hydraulic cylinders 13, which synchronously push the pistons 18 with the rods 14 and supports 5. The housing 1 of the device moves along the supports 5 in the direction from the concrete surface and through the rod 3 creates a tearing force on the anchor device. When the pistons 18 and, respectively, the housing 1 are moved a certain distance, the anchor device is pulled out and a piece of concrete is chipped off in the area adjacent to the anchor device.

The loading of the anchor device is carried out either before the control force on the strength of concrete, or until the anchor device is pulled out with a fragment of concrete.

During the measurement process, the pressure sensor 16 senses the force exerted by the piston 18 of the hydraulic cylinder 13 connected to the support 5 and generates a signal entering the electronic measuring unit 15. The electronic unit 15 automatically calculates the concrete strength value, displays it on the display and stores it in memory devices.

Each result contains the measurement conditions: type of material, type of hardening, expected strength class, size of coarse aggregate, dimensions of the anchor device; number, date and time of receipt of the result.

The device provides for a series of measurements from 2 to 5 with the calculation of the average strength of concrete and the maximum deviation from the average value in percentage terms.

The device described in this utility model, in the presence of additional devices, can also be used to determine the adhesion strength of bricks and stones in masonry walls, measure the breaking strength of bolts and dowels, adhesion of coatings, etc.

The device is also used to clarify the calibration characteristics of ultrasonic and shock-pulse devices in accordance with the Methodological Instructions NIIIZhB MDS 62 - 2.01 and GOST 22690-88 “Concretes. Determination of strength by mechanical methods of non-destructive testing. "

Claims (12)

1. A device for determining the strength of concrete, comprising a housing with an aperture in which a vertical rod is mounted with the possibility of longitudinal movement and rotation relative to the housing, rigidly connected at one end to an anchor device and the other with a mechanism for pre-tensioning the anchor device, and an electronic unit placed in the housing connected to the pressure sensor, a piston pump connected by channels formed in the housing to at least two hydraulic cylinders, the rods of which are coaxially connected to supports, characterized in that a second piston pump is installed, the pumps are connected through a gearbox to a common drive, and elements for controlling the position of the pistons in the initial and final positions are placed in the piston pumps. 2. A device for determining the strength of concrete according to claim 1, characterized in that the hole in the housing is made axial. 3. A device for determining the strength of concrete according to claim 1, characterized in that the axis of the piston pumps are parallel to the longitudinal plane of the housing. 4. A device for determining the strength of concrete according to claim 1, characterized in that the supports are made equidistant from the axial hole and placed in the longitudinal plane of the housing. 5. A device for determining the strength of concrete according to paragraphs. 1 and 4, characterized in that the supports are made adjustable in length. 6. A device for determining the strength of concrete according to claim 1, characterized in that the elements for controlling the position of the pistons in the initial and final positions are made in the form of magnetoresistors connected to the electronic unit. 7. A device for determining the strength of concrete according to claim 1, characterized in that the housing has a predominantly horizontally oriented parallelepiped shape. 8. A device for determining the strength of concrete according to claim 1, characterized in that the pre-tensioning mechanism of the anchor device is made in the form of a helm mounted on the upper threaded end of the rod. 9. A device for determining the strength of concrete according to claim 1, characterized in that the piston of the piston pump is made hollow, connected by means of a threaded connection to a drive screw, interacting through a gearbox with a drive. 10. A device for determining the strength of concrete according to paragraphs. 1 and 9, characterized in that the piston pump is made with a manual drive. 11. A device for determining the strength of concrete according to paragraphs. 1 and 9, characterized in that the piston pump is made with an electric drive. 12. A device for determining the strength of concrete according to claim 1, characterized in that the pressure sensor interacts with one of the hydraulic cylinders.

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