RU192519U1 - Cabinet for laser and optical equipment - Google Patents

Abstract

The utility model relates to equipment for storage and transportation of laser and optical equipment. The required technical result, which is to increase the protection against vibration and acoustic influences, is achieved in a device made in the form of a cabinet in the form of a rectangular parallelepiped with a floor installation and equipped with means for placing optical and laser components, including shelves for placing optical plates with laser and optical equipment, moreover, the side walls of the cabinet are sealed three-layer panels in which the inner layer is made of heat-insulating material, the outer the third layer is made of sound-reflecting material, and the intermediate layer is made of aluminum-magnesium alloy AMg6, the bottom of the cabinet is made in the form of a plate of aluminum-magnesium alloy AMg6 with the possibility of rigid attachment to the vibration insulation plate through the adapter plate, which provides vibration protection due to the absence of direct mechanical contact of the cabinet with the floor, and the upper wall of the cabinet is made with the possibility of supplying into the cabinet through a flexible corrugation air flow from a thermoelectric cooler installed above the cabinet. 1 ill.

Description

The utility model relates to equipment for storing and transporting laser and optical equipment and is designed to accommodate optical and laser components (optical resonators, a laser system, a femtosecond optical frequency synthesizer and a vacuum optical spectroscope), a transportable generator of ultra-stable reference frequency signals on a single ¹⁷¹ Yb ⁺ ion and ensuring the conditions of their operation (maintaining the temperature and humidity conditions, air purity, slight excess pressure, ec wounding from external magnetic fields, vibration and sound protection).

The device provides tightness, thermal insulation, the possibility of four-way access to optical and laser components, connecting them together via optical fiber and connecting to external electronic devices with reduced weight and size characteristics.

A device is known, made in the form of a cabinet [RU 178957, U1, H05K 5/00, 04.24.2018], including a front metal frame equipped with seats for mounting rings of the organizer, and a rear metal frame connected to the front frame by power elements in the form of metal horizontal beams, horizontal and vertical panels, cabinet legs, profiles and trays for installing unified computing modules, equipment switching means, located in front of the cabinet, at least one control lamp, located in the front of the cabinet, front seals located between the profiles and the front frame and having at least one window, a height-adjustable apron installed in the lower part of the cabinet, at least one cable entry mounted on top of the cabinet, partition dividing the interior of the cabinet into at least two heat-insulated sections, and a cooling system including at least one fan wall provided with at least two fans, made with the possibility of work, m at least in three modes - full stop, fan rotation at medium speed, fan rotation at maximum speed, at least two temperature sensors located in the interior of the cabinet, at least one in each thermally insulated section, each thermally insulated section served by its set of fans installed in at least one fan wall.

The disadvantage of this device is the relatively low cooling efficiency, as well as vibration and sound protection.

The closest in technical essence to the proposed one is a device for placing laser and optical equipment of a transported optical frequency standard on a single ion ⁴⁰ Ca ⁺ ("A compact, transportable single-ion optical clock with 7.8 × 10 ^-17 systematic uncertainty"; Applied Physics B, Volume 123, Issue 4, article id. 112, 9 pp., 04/2017).

The device is a heat-insulated case in the form of a rectangular parallelepiped placed on an active vibration-isolating platform, inside of which there is a vacuum chamber with a system for maintaining a given temperature. The space inside the housing and the vacuum chamber is designed to accommodate highly sensitive laser and optical components of the transported optical ion frequency standard.

The disadvantage of the closest technical solution is the lack of operational reliability.

This is due to a number of factors, in particular, low immunity to sound and vibration interference, insufficient shielding from external magnetic fields, lack of dust protection, increased dimensions and volume, difficult access to optical and laser components, reduced stability characteristics of the frequency standard built on the basis of this system.

The problem, which is solved in a utility model, is aimed at creating a cabinet for laser and optical equipment, characterized by increased operational reliability in conditions of vibration and acoustic influences.

The required technical result is to increase the operational reliability of the device by increasing the protection against vibration and acoustic influences.

The problem is solved, and the required technical result is achieved in that in a device made in the form of a cabinet in the form of a rectangular parallelepiped with a floor installation, equipped with means for placing optical and laser components, including shelves for placing optical plates with laser and optical equipment, according to the utility model , the side walls of the cabinet are sealed three-layer panels in which the inner layer is made of heat-insulating material, the outer layer is made of sound the pressing material, and the intermediate layer is made of aluminum-magnesium alloy AMg6, the bottom of the cabinet is made in the form of a plate of aluminum-magnesium alloy AMg6 with the possibility of rigid attachment to the vibration insulation plate through the adapter plate, which provides vibration protection due to the absence of direct mechanical contact of the cabinet with the floor, and the upper wall of the cabinet is made with the possibility of supplying into the cabinet through a flexible corrugation air flow from a thermoelectric cooler installed above the cabinet.

The drawing shows a cabinet for laser and optical equipment (on the left - assembled, on the right - with the front wall removed) together with a thermoelectric cooler, vibration insulation plate and auxiliary protective case, designed to accommodate equipment sensitive to external magnetic fields.

In the drawing are indicated:

1 - cabinet;

2 - cabinet shelves;

3 - optical plates;

4 - external sound-reflecting layer of the protective walls of the cabinet;

5 - the internal heat-insulating layer of the protective walls of the cabinet;

6 - thermoelectric cooler;

7 - vibration isolation plate;

8 - auxiliary plastic protective case.

The cabinet 1 for laser and optical equipment is made in the form of a rectangular parallelepiped with a floor installation, equipped with means for placing optical and laser components, including shelves 2 for placing optical plates 3 with laser and optical equipment.

The cabinet has a compartment shielded from external magnetic fields, inside of which a protective casing 8 is installed, designed to accommodate equipment sensitive to external magnetic fields, for example, a vacuum optical spectroscope.

In addition, the side walls of the cabinet are sealed three-layer panels in which the inner layer 5 is made of heat-insulating material, the outer layer 4 is made of sound-reflecting material, and the intermediate layer is made of aluminum-magnesium alloy AMg6.

The bottom of the cabinet is made in the form of a plate of aluminum-magnesium alloy AMg6 with the possibility of rigid fastening to the vibration isolation plate 7 through the adapter plate, which provides vibration protection due to the absence of direct mechanical contact of the cabinet with the floor, and the upper wall of the cabinet is made with the possibility of feeding into the cabinet via a flexible corrugation air from a thermoelectric cooler 6 mounted on a horizontal surface directly above the cabinet and not having hard mechanical contact with the cabinet, which reduces the per I’m going to the cabinet of vibration disturbances.

In addition to the above, it is possible to connect to the equipment inside the cabinet through openings in the upper wall of the cabinet of electric cables fixed above the cabinet and hanging freely, which also ensures vibrational stability of the structure.

Shelves for placing optical plates with laser and optical equipment can be made of non-magnetic corrosion-resistant steel 12X18H10T with a thickness of 2 mm, the dimensions of optical plates with laser and optical equipment installed on the shelves of the cabinet are 400 × 400 mm, shelves for placing optical plates with laser and optical equipment made of height-adjustable in increments of 15 mm, the protective walls of the cabinet can have from 16 to 24 cross-shaped slots 110 × 110 mm in size, designed for the possibility of additional connection optical and laser components placed inside the cabinet to external devices so that the internal heat-insulating layer of the protective three-layer cabinet walls can be made of foamed foil polyethylene (penofol) with a thickness of 5 mm, the thermoelectric cooler is connected by feedback to the temperature sensor installed inside the cabinet for automated control of the working temperature inside the cabinet, the cabinet is equipped with a double air filtration system supplied to the interior of the cabinet, which has in its Stava filter gasket coarse and fine filters, and air drying system fed to the interior of the cabinet, being composed of an absorbent material in the form of silica gel KSMG.

Inside the cabinet, an overpressure in the range from 1 to 5 kPa is maintained, which does not allow dust to enter the cabinet, the cabinet contains 5 shelves for placing optical plates with laser and optical equipment, the cabinet height is 1330 mm, the cabinet's width and length are 433 × 467 mm, the material used to cover the plastic protective case and the cabinet's protective panels uses a universal shielding coating HNG100 with a thickness of 80 μm with an electromagnetic field shielding factor of 100 dB at a frequency of 1 GHz.

The cabinet is used as follows.

Laser and optical equipment are installed on the optical plates installed on the shelves of the cabinet. A preliminary adjustment of the equipment can be made. With the front and, if necessary, other walls removed, the electrical cables are connected and, if necessary, the equipment is also connected to each other using fiber optical fibers. After connecting the equipment and its final adjustment, the cabinet is sealed. Four protective three-layer walls are installed, an active vibration isolation plate is connected and launched.

A vibration isolation plate together with an external sound-reflecting layer of protective walls provides damping of acoustic vibrations in a wide frequency range from several hundred to several thousand hertz by a value of about 10 dB. The cabinet is fixed to the plate through its base with M4 countersunk screws. An optical plate is also attached to the base with the same screws on the back to accommodate the protected equipment located in the lower compartment of the cabinet. An auxiliary protective case is installed in the upper compartment of the cabinet, designed to accommodate equipment sensitive to external magnetic fields, for example, a vacuum optical spectroscope. The plastic protective case has the shape of a rectangular parallelepiped with dimensions of 400 × 450 × 365 mm with rounded edges and corners, removable front and rear walls and the possibility of fastening with four M4 screws with countersunk heads to the upper shelf of the cabinet. The plastic protective case and the protective panels of the cabinet are coated on the outside with a self-adhesive material that shields external magnetic fields.

After carrying out the above actions, the thermoelectric cooler is launched to ensure that the working temperature inside the cabinet is maintained with an accuracy of no worse than ± 1 ° C, provided that the ambient temperature is in the range from 10 to 45 ° C. The necessary temperature inside the cabinet is maintained automatically using the PVT100 industrial converter with a temperature range from -40 to 80 ° С and transfer of the measured values to the thermoelectric cooler via the RS-485 interface.

The design of the automatic climate control system provides for the protection of the cabinet’s internal space from the ingress of condensate formed on the cold side of the thermoelectric cooler. Joint sealing and structure sealing are carried out using a 1.6 mm thick self-adhesive silicone tape MATINS 200S. The air flow from the thermoelectric cooler entering the cabinet ensures the maintenance of excess pressure, controlled by means of an electromagnetic normally closed valve and a sensor.

Thus, due to the fact that the side walls of the cabinet are sealed three-layer panels in which the inner layer is made of heat-insulating material, the outer layer is made of sound-reflecting material, and the intermediate layer is made of aluminum-magnesium alloy AMg6, the bottom of the cabinet is made in the form of a plate of AMg6 aluminum-magnesium alloy with the possibility of rigid attachment to a vibration insulation plate through an adapter plate, the efficiency of vibration protection is increased due to the absence of a direct mechanical con an act of the cabinet with the floor, and the upper wall of the cabinet is configured to supply air into the cabinet through a flexible corrugation from a thermoelectric cooler installed on a horizontal surface directly above the cabinet, without hard mechanical contact with the cabinet and not transmitting vibration disturbances to the cabinet, which also improves vibration protection. In addition, it is possible to connect to the equipment inside the cabinet through openings in the upper wall of the cabinet of electric cables fixed above the cabinet and hanging freely. All this ensures the achievement of the required technical result, which consists in increasing the operational reliability of the device by increasing the protection against vibration and acoustic influences.

Claims (10)

1. The cabinet for laser and optical equipment, made in the form of a rectangular parallelepiped with a floor installation and equipped with means for placing optical and laser components, including shelves for placing optical plates with laser and optical equipment, characterized in that the side walls of the cabinet are sealed three-layer panels in which the inner layer is made of heat-insulating material, the outer layer is made of sound-reflecting material, and the intermediate layer is made of aluminum-mag AMg6 alloy, the bottom of the cabinet is made in the form of a plate of aluminum-magnesium alloy AMg6 with the possibility of rigid attachment to the vibration insulation plate through the adapter plate, which provides vibration protection due to the absence of direct mechanical contact between the cabinet and the floor, and the upper wall of the cabinet is made to be fed into the cabinet by flexible corrugation of the air flow from the thermoelectric cooler installed above the cabinet. 2. The device according to p. 1, characterized in that the shelves for accommodating optical plates with laser and optical equipment are made of non-magnetic stainless steel 12X18H10T 2 mm thick. 3. The device according to claim 1, characterized in that the dimensions of the optical plates mounted on the shelves of the cabinet with laser and optical equipment are 400 × 400 mm. 4. The device according to claim 1, characterized in that the shelves for accommodating optical plates with laser and optical equipment are made adjustable in height with a pitch of 15 mm. 5. The device according to claim 1, characterized in that the protective walls of the cabinet have from 16 to 24 cross-shaped slots of 110 × 110 mm in size, designed to allow additional connection of optical and laser components located inside the cabinet to external devices. 6. The device according to claim 1, characterized in that the inner heat-insulating layer of the protective three-layer cabinet walls is made of foamed foamed polyethylene (penofol) with a thickness of 5 mm. 7. The device according to claim 1, characterized in that the thermoelectric cooler is connected by feedback to a temperature sensor installed inside the cabinet for automated control of the operating temperature inside the cabinet. 8. The device according to claim 1, characterized in that the cabinet is equipped with a double filtering system for air supplied to the interior of the cabinet, incorporating coarse and fine filter pads, and a drainage system for air supplied to the interior of the cabinet, which has in its the composition of the adsorbent material in the form of silica gel KSMG. 9. The device according to claim 1, characterized in that an overpressure in the range from 1 to 5 kPa is maintained inside the cabinet, preventing dust from entering the cabinet. 10. The device according to p. 1, characterized in that the cabinet contains 5 shelves for placing optical plates with laser and optical equipment.

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