RU2380785C2 - Ultrahigh-vacuum transport system - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: invention can be used in loading and unloading of probes and samples in scanning probe microscopes operated in vacuum and limited visual access into reloading area. Proposed transport system comprises loading chamber with first manipulator with gripper and second manipulator with probe and sample cartridges, said chamber being coupled with measurement chamber. The latter comprises first probe carrier holder and second sample carrier holder. Note that probe carrier and sample carrier cartridge is linear one, while first manipulator gripper is coupled with first probe carrier holder and second sample carrier holder.

EFFECT: higher reliability.

6 cl, 2 dwg

Description

The invention relates to vacuum technology and is intended for operations to move objects inside vacuum systems. The invention can be used to load and unload probes and samples in scanning probe microscopes operated under vacuum with limited visual access to the overload zone.

Known ultra-high vacuum transport system for scanning probe microscopes (SPM), containing a linear rotary manipulator, a cartridge for probes and samples and a precision manipulator for installing the probes in the measurement position [1, 2].

The disadvantages of this device are the complexity and, accordingly, the low reliability of the device associated with the location of the cassette in the measurement zone, which also leads to the difficulty of adapting and reconfiguring this system.

Also known is an ultrahigh-vacuum transport system for scanning probe microscopes, comprising a linear rotary manipulator with a magnetic grip docked with a loading chamber, a linear mounting rocking arm equipped with a mechanical grip, a carousel cartridge of probes and samples with a rotary manipulator, docked with a chamber for storing probes and samples and measuring , which, in turn, is connected to the boot chamber [3].

The disadvantages of this device are the limited functionality of the transport system associated with the use of magnetic capture, which, in turn, imposes a limitation on magnetic research, and also limits the choice of holder materials. The second disadvantage is the complexity of the design, which is determined by the presence of both magnetic capture and mechanical. The complexity of the design, respectively, leads to a decrease in the reliability of the entire system and the complexity of operation.

Known transport system for scanning probe microscopes, including the first manipulator with a grip, docked with loading and measuring cameras. In this case, the capture is paired with the first probe carrier and the second sample carrier, arranged to interact with the first and second holders of the loading chamber and the third and fourth holders of the measuring chamber. The first and second holders contain the first and second catchers and the first and second stops, respectively, and are paired with a second manipulator mounted on the loading chamber [4].

The main disadvantage of this device is the lack of a means of automatically installing the probe carriers and samples in the holders, which reduces the reliability of the device, especially in the case of limited mutual access to the overload zone.

The objective of the invention is to create a universal transport system for loading and unloading probes and samples in conditions of limited visual access, for example in vacuum cryostats.

The technical result is to increase the reliability of the operation of the transport system.

The indicated technical result is achieved in that in an ultrahigh-vacuum transport system comprising a loading chamber with a first manipulator with a grip and a second manipulator with a cassette for probe carriers and sample carriers, the loading chamber is docked with a measuring chamber containing a first probe carrier holder and the second holder of sample carriers, the cassette for carrier of probes and sample carriers is linear, and the capture of the first manipulator is paired with the first holder a probe carrier and a second sample carrier holder.

A variant is possible in which the gripper comprises a cylindrical surface with a conical generatrix, the second holder comprises a cylindrical guide with a conical catcher, while the cylindrical surface is arranged to interact with the cylindrical guide, and the conical generator with the conical catcher.

There is an option in which the gripper contains two slats mounted on it with the possibility of frictional fixation, while hooks are mounted on the slats with the possibility of spring movement relative to the slats.

There is also a variant of the device containing the return mechanism, the grippers contain the first protrusions, the carriers of the probes and samples have covers with second protrusions, and the strips are made with wedges, while the first protrusions are arranged to interact with the second protrusions, the wedges have covers, and the return mechanism - with slats.

A variant is also possible in which the sample carrier has a cone generatrix arranged to interact with the cone trap.

There is also an option in which the carrier of the probes has contact pads, and the first holder has a spring and an abutment installed with the possibility of interaction with the contact pads.

Figure 1 shows the ultrahigh-vacuum transport system in general.

Figure 2 - embodiment of the capture.

The ultra-high vacuum transport system (Fig. 1) contains a loading chamber 1 on which a first linear manipulator 2 with a gripper 3 is fixed, a second linear manipulator 4 with a cassette 5, in which are mounted the carriers 6 of the probes 7 (one shown) and the carriers 8 of the samples 9 (also shown one). The loading chamber 1 through the gateway 10 is connected to the measuring chamber 11, in which the measuring device 12 is installed with the first holder 13 of the carrier 6 of the probe 7, and the second holder 14 of the carrier 8 of the sample 9. The holder 14 contains a cylindrical guide 15 and a cone catcher 16, installed with the possibility interacting with the gripper 3. The gripper 3 thus comprises a cylindrical surface 17 and a conical generatrix 18. Two grips 19 are mounted on the gripper 3, for example, on split spring axes 20 with the possibility of rotation and friction fixing on x

The straps 19 have wedges 21, flat springs 22, hooks 23 and stops 24. The springs 22 can be made in the form of separate flat elements.

The carrier 6 of the probe 7 can be made cylindrical with holes 25. The holder 13 can have an electrically insulated spring 26 and a stop 27. The carrier 8 of the sample 9 is cylindrical with holes 28 (analogous to the holes 25) with a conical generatrix 29.

A return mechanism 30 can be installed in the loading chamber. The scanning device 12 is mounted on a flange 31, hermetically (not shown) connected to the chamber 11. Also, a holder 14 is fixed on the flange 31 by means of an adapter 32. In the cassette 5, the media slot 6 may comprise a spring 33 and emphasis 34, and the media socket 8 to be an analogue of the holder 14.

In one embodiment (FIG. 2), the gripper 3 further comprises guides 35 with runners 36 and stops 37. The guides 35 are fixed on the straps 19 and are arranged to interact with the samples 38 made in the cover 39. The hooks 23 may have first protrusions 40, arranged to interact with the second protrusions 41 of the cover 39. In addition, the hooks 23 contain smooth surfaces 42. It should be noted that the covers 39 with the protrusions 41 on the carriers 6 and 8 are the same.

The probe 7, made, for example, in the form of a quartz resonator with a needle 43, conductors 44 can be connected to pads 45 and 46, mounted through insulators 47 on the carrier 6 with the possibility of interaction with the spring 26 and the stop 27, through which you can feed and remove electrical signals from probe 7.

The measuring device 12, including a preliminary approximation system of the probe 7 and sample 9, as well as an analysis unit (not shown), can be a scanning probe microscope.

The chamber 1 is coupled to the pumping means 48, and the measuring chamber 11 is located in a helium cryostat 49. Details of the system elements, such as 2, 4, 10, 12, 48, are described in [1, 2, 3, 4, 5, 6].

The transport system operates as follows. The manipulator 2, using the gripper 3, namely, the hooks 23, which are extended thanks to the flat springs 22, and using the holes 2, remove the carrier 7 from the cartridge 5. After opening the gateway 10, the carrier 6 is transferred to the measuring chamber 11 and installed in the holder 13. Introduction of the carrier 6 under the spring 26 is carried out by further moving the gripper 3 down and after the interaction of the wedges 21 with the walls of the carrier 6. In this case, the strips 19 are breached and oriented in this position due to the axes 20, after which the hooks 23 are removed from the hole Cone 25. Simultaneously the generator 18 grip 3 come into contact with the tapered catcher 16, restricts the movement of grip 3 downwards. After that, it is possible to move the gripper 3 up to transfer the carrier 8 with the sample 9 into the measurement zone. To do this, due to the interaction of the stops 23 with the mechanism 30 of the strap 19 is returned to its original position.

The capture of the carrier 8 and its removal from the cartridge is carried out similarly to the capture of the carrier 6. Namely: the hooks 23, using flat springs 22, are inserted into the hole 28 and the carrier 8 is removed from the slot. After that, it is moved into the chamber 11 and installed in the holder 14 on the conical generatrix 18. The opening of the gripper 3 with the carrier 8 is carried out similarly to that described above.

The specifics of the capture in figure 2, 3 is as follows. After touching the pads 45 and 46 of the spring 26 and the stop 27, the runners 36 fall into the samples 38 and slide on them until they touch the stops 37 of the cover 39. Due to this, the carrier 6 is fixed between the spring 26 and the stop 27 with simultaneous electrical contact with them.

The removal of the carrier 7 occurs due to the interaction of the first 40 and second 41 protrusions.

After loading the probe 7 and sample 9 into the measuring chamber 11, they come closer and then scan the surface of the sample 9 with the probe 7. Scanning is performed by the device 12, and this process is controlled by the analysis unit, which is part of the scanning probe microscope.

The execution of the cartridge carrier for sample carriers is linear, and the capture of the first manipulator is paired with the first holder of probe carriers and the second holder of sample carriers by reducing the number of transfers of objects and the direct interaction of the capture of the first manipulator with the first and second holders, increases the reliability of the device.

Providing the capture with a cylindrical surface with a conical generatrix, located with the possibility of interaction with the cylindrical guide and the cone trap, provides accurate positioning of the capture relative to the first holder and, accordingly, greater reliability of loading and unloading of probe carriers.

The execution of the straps with the possibility of frictional fixation on the grip and hooks with spring movement relative to the straps increases the reliability of the transmission of probe carriers and sample carriers.

The introduction of a return mechanism interacting with the slats of the first protrusions interacting with the second, and the wedges with the cover, introduce additional fixed movements of the gripping elements, which increases the reliability of its operation.

The supply of the sample carrier with a cone generatrix interacting with the cone catcher due to the exact orientation of the sample carriers increases the reliability of their loading and unloading.

The supply of probe carriers with contact pads interacting with the spring and the stop increases the reliability of electrical contacts.

Thus, the proposed device increases the reliability of its operation in conditions of limited visibility.

LITERATURE

1. Information of Park Scientific Inxtruments firm. Auto Probe UHV Scanning Probe Microscope, 1994

2. US patent No. 5157256, H01J 37/26, 1991

3. Information of Omicron. Multi-mode UHV Scanning Probe Microscope, p. 1, 2.

4. Patent RU No. 2158454, 2000

5. Vacuum technology. Handbook, M.: Mechanical Engineering, 1985, 359 p.

6. High vacuum pumping devices. M .: Energy, 1969, 524 p.

Claims (6)

1. An ultra-high vacuum transport system comprising a loading chamber with a first manipulator with a gripper and a second manipulator with a cartridge for probe carriers and sample carriers, wherein the loading chamber is connected to a measuring chamber comprising a first probe carrier holder and a second sample carrier holder, characterized in that the cassette for probe carriers and sample carriers is linear, and the gripper of the first manipulator is paired with the first holder of the probe carriers and the second core resident sample carriers. 2. The device according to claim 1, characterized in that the gripper comprises a cylindrical surface with a conical generatrix, the second holder comprises a cylindrical guide with a conical catcher, while the cylindrical surface is arranged to interact with the cylindrical guide, and the conical generatrix with the conical catcher. 3. The device according to claim 1, characterized in that the gripper contains two brackets mounted on it with the possibility of frictional fixation, while hooks are mounted on the brackets with the possibility of spring movement relative to the brackets. 4. The device according to claim 3, characterized in that it contains a return mechanism, the grippers contain the first protrusions, the carriers of the probes and samples have covers with second protrusions, and the strips are made with wedges, while the first protrusions are arranged to interact with the second protrusions, wedges - with covers, and the return mechanism - with straps. 5. The device according to claim 2, characterized in that the sample carrier has a cone generatrix located with the possibility of interaction with a cone trap. 6. The device according to claim 1, characterized in that the probe carrier has contact pads, and the first holder has a spring and an abutment installed with the possibility of interaction with the contact pads.

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