Application of Design Aspects in Uniaxial Loading Machine Development

요약

Here we present a protocol to develop a pure uniaxial loading machine. Critical design aspects are employed to ensure accurate and reproducible testing results.

초록

In terms of accurate and precise mechanical testing, machines run the continuum. Whereas commercial platforms offer excellent accuracy, they can be cost-prohibitive, often priced in the $100,000 - $200,000 price range. At the other extreme are stand-alone manual devices that often lack repeatability and accuracy (e.g., a manual crank device). However, if a single use is indicated, it is over-engineering to design and machine something overly elaborate. Nonetheless, there are occasions where machines are designed and built in-house to accomplish a motion not attainable with the existing machines in the laboratory. Described in detail here is one such device. It is a loading platform that enables pure uniaxial loading. Standard loading machines typically are biaxial in that linear loading occurs along the axis and rotary loading occurs about the axis. During testing with these machines, a load is applied to one end of the specimen while the other end remains fixed. These systems are not capable of conducting pure axial testing in which tension/compression is applied equally to the specimen ends. The platform developed in this paper enables the equal and opposite loading of specimens. While it can be used for compression, here the focus is on its use in pure tensile loading. The device incorporates commercial load cells and actuators (movers) and, as is the case with machines built in-house, a frame is machined to hold the commercial parts and fixtures for testing.

서문

Mechanical testing has an interesting history that can be traced back to hardness testing equipment developed by Stanley Rockwell in the early in the twentieth century. While technology has grown to the extent that standard, documented practices guide everything from the verification of machine performance to the guidelines for carrying out specific tests^1,2,3,4. Today, mechanical tests are conducted on everything from building materials such as concrete, steel, and wood to food and textile products^5,6,7,8,9. Given that the fields of biomedical engineering and, more specifically, biomechanics utilize mechanical testing, loading machines are commonplace in biomechanics labs.

Loading machines run the range of scale in biomechanics. As an example, larger loading machines can be used to conduct full-body impact studies or determine human femoral mechanical properties, while smaller loading machines can be used to test murine bones or stimulate cells^{10,11,12,13,14}. Two types of loading machines are found in the testing laboratory; those that are purchased commercially and those that are built by the user. Loading machines developed in-house are often favored for their personalization and customization options¹⁵.

In testing, a specimen is secured in the machine so that a displacement can be applied, generating a measurable force. If the load is used as the driving feedback, the test is load-controlled; if the displacement is used as the driving feedback, the test is displacement-controlled. Loading machines, in general, are built upon a frame that connects a mover to a fixed support. As such, testing generally involves one end of the specimen being moved while the other end remains fixed.

Shown in Figure 1 is a sketch of a simple loading machine demonstrating its basic components. Fundamental to all loading machines is a base or frame. Whereas the vast majority of commercial brands utilize a fixed base, the drawing depicts a platform that allows planar (XY) movement. The mover, in this case, is the upper arm that holds a load cell and is driven by a stepper motor. Attached to the frame are the fixtures which hold the specimen and dictate the type of test that is run. Shown in the drawing are three-point bend fixtures. The top fixture (the single contact) is mounted to the moving arm; the bottom fixture (the double contact) is mounted to the stationary base. During testing, the motor drives the upper fixture downward to where the center contact engages the specimen. As the contact engages the specimen, the load cell records the increase in resistance or the force placed upon the specimen.

There are occasions where machines are designed and built in-house to accomplish a motion not attainable with the existing machines in the laboratory. Here we describe in detail one such device. It is a loading platform that enables pure uniaxial specimen loading or equal and opposite motion at both ends. The device incorporates commercial load cells and actuators (movers); a frame is machined to hold the commercial parts and loading fixtures for specimen testing. Understanding the basic principles of testing machine construction can aid in the design of one's own machine. We have provided the drawing files we created as a starting point to assist researchers with their own machine development. The video will focus on the assembly of the device and the application of mechanical design principles to ensure alignment and reliable testing.

프로토콜

NOTE: The finished device is shown in Figure 2. The device enables pure uniaxial testing of specimens in a horizontal position.

1. Component Parts

1. Prepare two programmable actuators with a 30 mm (1.2 in) travel per actuator capable of spanning 60 mm (2.3 in) when programmed to pull/push together. To accommodate a variety of potential uses, select actuators having a reasonable force capacity [67 N (15 lb)], peak thrust [58 N (13 lb)], speed resolution [0.9302 µm/s (0.00004 in/s)], and a unidirectional accuracy [25 µm (0.001 in)].
2. Daisy-chain the actuators to sync them for an equal application of extension/retraction.
3. Prepare a 24 V controller to provide the driving motion to the actuator; these systems enable a precise linear motion by the rotation of a screw, the leadscrew.
4. Prepare two load cells with a maximum force capacity of 44.5 N (10 lb). Select a low profile or canister-style load which is ideal for confined spaces.
5. Prepare the rail/carriage block system. Prepare one rail and two carriages; one to hold each actuator. Because steel will rust, select stainless-steel material if the device will be utilized for materials that require hydration; for all other purposes, steel is acceptable.
   NOTE: An exploded view of the loading platform with the rail/carriage block shown in purple is provided in Figure 3.

2. Frame Construction

NOTE: For explanatory purposes, the platform is color-coded in the graphics.

1. Prepare aluminum stock material. Select aluminum for its cost-effectiveness and ease of machining. Prepare both plate and 'L'-shaped angle stock.
2. Prepare stock material to machine fixtures. Select plexiglass; it is strong while lightweight.

3. Metal Base and Side Plate (Frame) Assembly

1. Cut the base plate from the aluminum stock, making sure it is approximately 64 x 15 x 1.3 cm (25 x 6 x 0.5 in). Clean up the edges in the mill and cut the base plate to its final dimensions.
2. Machine the plate flat in the mill, according to the specifications provided in the supplemental files.
3. Face it, ensuring the plane is level.
4. Machine a track into the base plate to align the side plates with a tolerance of 0.0126 mm (0.0005 in).
5. Machine the side plates according to specifications provided in the supplemental files.
6. Drill and tap the side plates on their bottom face.
7. Mount the side plates upright in the track.
8. Fasten the side plates to the base plate from underneath (Figure 4).

4. Attaching the Rail/Carriage Assembly to the Frame

1. Machine tracks into the front face of each side plate to enable the mounting of the rail/carriage assembly according to the specifications provided in the drawing links (Figure 5).
2. Fasten the rail to the track through the clearance holes in the rail via drilled and tapped holes (to accommodate #10-32 screws) in each side plate.

5. Rear Mount Attachment of the Actuators

1. Machine rear mount attachments from the 'L'-shaped angle stock according to the specifications provided in the supplemental files.
2. Machine a bar to attach to the bottom of the mount to serve as a keyway and ride it in the machined track on the face of the side plate according to the specifications provided in the supplemental files. Screw the bar into the bottom of the mount.
3. Drill a through hole in the base of the rear mount for the actuator clearance.
4. Attach the rear mount to the body of the actuator via the hole pattern in the commercial actuator.
   NOTE: One reason for making a rear mount is to eliminate the need to repeatedly attach the actuator directly to the frame using the small #2 metric screws that come stock on the actuators. The mount eliminates the concern of stripping the internal threads of the actuator with repeated use.
5. Slot the base of the mount to attach the rear actuator mount to the frame via two screws.
6. Drill and tap a series of holes (to accommodate #10-32 screws) flanking the track on the front face of the side plates to allow for an adjustable mount attachment if it is desirable to accommodate specimens of varying sizes.

6. Front Mount Attachment of the Actuators via Connectors

NOTE: The front mount is an 'L'-shaped piece that attaches the front of the actuator to the carriage. The actuator does not physically contact the mount; it attaches via a series of connectors that extend from the actuator tip.

1. Machine front mount attachments from the 'L'-shaped angle stock according to the specifications provided in the supplemental files.
2. Drill a hole in the base of the front mount to accommodate the tapered connector.
3. Machine a track in the side of the front mount to accommodate a plate.
4. Machine the plate with a track to accommodate the fixtures.
5. Machine an aluminum, cylindrical connector according to the specifications provided in the drawing links. This adaptor connects the load cell to the actuator.
6. Drill and tap the connector for a #2 metric screw on the actuator end and a #6 metric screw on the load cell end to support the axial mounting and alignment of the load cell and actuator.
7. Repeat this process to machine two identical connectors, one for each load cell.
8. Machine an aluminum, tapered, cylindrical connector according to specifications provided in the drawing links. This adaptor connects the load cell to the fixture and the carriage.
9. Drill and tap the connector to the threaded load cell connection on one end.
10. Pass the cylinder into the hole of the front actuator mount and use a set screw to anchor the cylinder end.
11. Duplicate the system for the right and left actuators.
    NOTE: As shown in Figure 6, once assembled, the base of the actuator is rigidly attached to the side plate. The front of the actuator is attached to the carriage and, as the actuator is extended and retracted, the carriage is pushed and pulled. This provides the framework for the fixture attachment and specimen loading.

7. Fixtures

1. Machine the fixtures according to the specifications provided in the supplemental files (Figure 7).
2. Machine a central, vertical slot in the fixture holder to accommodate the height.
3. Attach the actuator front mounts to the rectangular plate with three drilled and tapped holes (to accommodate #10-32 screws) vertically aligned in the center of the plate.
4. Raise or lower the holder as necessary, for example, if a saline bath for hydrated testing is being used, and secure it with screws.

8. Operating Procedure:

1. Download the actuator software to remotely control the device¹⁶.
2. Create a link between the computer and the 24 V controller with a 6-pin mini-din male-to-female PS/2 extension cable; each actuator controller has two 6-pin mini-din connector cable links.
3. Use a USB-to-6-pin mini-din converter to connect the actuators to a standard computer; the converter contains one female 6-pin mini-din connector end and a USB connection port.
4. Daisy-chain the actuators so that a single computer cable is sufficient for the operation, or alternatively, use an HDMI adapter in place of the USB adapter.
5. Connect the actuators to the 24 V power supply.
6. Once connected and powered, select the devices and customize the actuator performance.
7. Alternatively, control the actuators manually by the dial on each actuator, which is useful for the set-up.
   NOTE: This software is applicable to any standard operating system. With this software, the actuators can be moved at varying speeds to any set distance, synced at a set distance or synced to each other to move in unison.

결과

In order to verify the use of the system, actuator speed and performance tests were conducted¹⁷. These tests consisted of measuring the actuator speed and distance in comparison to the input values. To verify the sample travel distance accuracy, arbitrary travel distances along the shaft between 254 - 2540 µm (0.01 - 0.10 in) were selected. The device was run to these distances and compared to the actual distance measured using combinations of gauge blocks and...

토론

The goal of this work was to design and fabricate a cost-effective and reliable uniaxial loader for its use with small-scale specimens such as tissue and fibers. A device was constructed that met the requirements set forth while also being flexible enough in design to allow for new attachments to be fabricated as the user needs grow. For example, the device will allow for the testing of dry and wet specimens in a uniaxial or fixed-end configuration.

Critical steps in the design and fabrication...

자료

Name	Company	Catalog Number	Comments
Power supply, 24 V DC 2.5 A out, 100-240 V AC in, plug for North America	Zaber Technologies inc	PS05-24V25
6 pin mini din-male to female PS/2 extension cable	Zaber Technologies inc	T-DC06
Stepper motor controller, 2 phase	Zaber Technologies inc	A-MCA
Linear actuator, NEMA size 11, 30 mm travel, 58 N maximum continuous thrust	Zaber Technologies inc	NA11B30
Corrosion resistant maintenance-Free Ball Bearing Carriages and Guide Rails	McMaster-Carr	9184T31
6061-t6 Aluminum Stock	McMaster-Carr	NA
Plexiglas Stock	McMaster-Carr	NA
Canister load cell, 4.5N	Honeywell Sensotec	NA
USB to 6 pin mini-din	Universal	NA