RU2699107C1 - Multi-chamber device for growing large diamond crystals without power frame - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to chemical engineering, high pressure engineering and can be used for growing diamond crystals. Device for growing diamond crystals comprises, arranged in recesses of soil on table 6 coaxially in a row, containers 1, 2 with high-pressure apparatus 3 in each container, corresponding to high-punching high-pressure apparatus 3, and between each of extreme containers 1 and 2 and corresponding wall 8 of recess there is at least one unloading plate 7. Each container 1, 2 is closed by at least one of lateral sides of movable in axial direction plug 4, 5.

EFFECT: invention allows to simultaneously, in one device in the absence of a power frame, to grow diamonds with different characteristics in each of containers with a high-pressure chamber under different modes.

9 cl, 3 dwg

Description

The invention relates to chemical engineering, to high-pressure technology and can be used for growing large crystals of diamonds and the synthesis of other materials at high pressure and temperature, the production process of which requires a long time.

Currently, the synthesis (growing) of large diamond crystals is carried out mainly in multi-punch apparatuses with a high-pressure chamber in the form of a cube, or octahedron, or other regular polygon, as well as in “toroid” and “belt” chambers (High Pressure Physics, page on the Internet http://lomonosov-fand.ru/enc/ru/encyclopedia:01275:article). To create and maintain pressure in the pressure chambers, individual power frames are used. So to work on the cameras "toroid" and "Belt" used hydraulic presses. In multi-punch units with a hydraulic drive of punches, the force developed in the container is held by an individual power frame, or the container itself is made in the form of a power frame (BARS system).

Closest to the proposed one is a high-pressure apparatus (RU 2071823, publ. 20.01.1997) containing a multi-punch block having an outer surface in the form of a regular polyhedron, each punch of which is a regular pyramid with a truncated apex. The base of this pyramid serves as one of the outer sides of the multi-punch block, and the truncated peak serves as one of the sides of the compressible volume. The container consists of two half-shells, between which is enclosed an internal cavity in which a multi-punch block is placed. It has the shape of an inverse polyhedron, corresponding in shape to the outer surface of the multi-punch block. The multi-punched block in an elastic sealing case, the edges of which in the area of the connector are hermetically fixed on the surface of the half-shells, is placed in the inner cavity of the container. The high-pressure fluid is supplied to the high-pressure chamber between the elastic cover and the surface of the container's internal cavity. The force perceived by the outer surface of the punch is transmitted to its truncated peak, which has a smaller area, as a result of which high pressure is created in the internal volume. The force generated in the high-pressure container of this device is held by power brackets or a press frame.

The development (production) of large crystals of diamonds is constrained by the high cost of high-pressure equipment, which consists of a high-pressure chamber and a power device (hydraulic press frame and hydraulic cylinder) or a container and a power frame that holds the load created in the container. The most metal-consuming part of these devices is the power frame.

The technical problem solved by the invention is the creation of a simple, non-metal-consuming multi-chamber device that holds large loads for a long time, for growing large crystals of diamonds and other materials in a large volume, the process of growing which takes a long time, in high-pressure chambers with a large working volume.

The technical problem is solved by a device for growing diamond crystals, containing containers mounted in a deepening ground coaxially in a row with a corresponding multi-punch high-pressure apparatus placed in each container, and at least one unloading plate is installed between each of the extreme containers and the corresponding deepening wall.

Containers should be installed on the table.

In addition, each container is closed by at least one of the sides of the axially movable stopper.

In another embodiment, each pair of adjacent containers can be closed from facing each other sides with one axially movable stopper.

To ensure that the package of containers is sealed on the axis of the power frame and to keep the containers closed during synthesis, one of the containers has an inner diameter greater than the other containers, and the cylinder length, that is, the working stroke of the movable plug of this container, is equal to the total width of all the gaps between the containers during their initial installation on the axis of the frame.

In addition, in each container between the multi-punch apparatus and the inner cylindrical surface of the container, liners can be located that are fixed to the cylindrical wall of the container.

In addition, in each container, a multi-punch unit can be mounted on a slide.

In addition, in one of the plugs of each container, hermetically electrical inputs, inputs of a cooling medium, inputs of a high pressure medium, as well as inputs of sensors for monitoring the synthesis process can be made.

The technical result of the invention is to enable the simultaneous cultivation of several characteristics of diamonds and other materials in one installation in the absence of a power frame. This is achieved due to the fact that several containers with multi-punch high-pressure apparatuses for growing diamonds are used coaxially mounted in a row in the deepening of the earth. In this case, the axial force created in the high-pressure containers restrains the reaction of the earth mass and friction through two oppositely arranged parallel walls, for example, reinforced concrete, installed in the burial ground or shaft, and through unloading plates. As a result, a large number of high-pressure apparatuses are located in a small area. Separate control of each container allows you to simultaneously process the synthesis of various materials under different modes and synthesize various materials.

The invention is illustrated by drawings.

In FIG. 1 shows the proposed device, a front view in section.

In FIG. 2 shows the proposed device, a top view.

In FIG. 3 shows a multi-punch apparatus in section.

In FIG. Figure 1 shows a multi-chamber device for growing large diamond crystals located in the depths of the earth. It lacks a power frame. The device consists of a package of containers 1, 2 high pressure, which are multi-punch apparatus 3 high pressure. The containers 1, 2 are closed by movable plugs 4, 5 and mounted coaxially in a row on the working table 6 between the unloading plates 7. The unloading plates 7 are made of metal and reinforced concrete and serve to reduce the specific pressure per unit area of the earth.

One of the outermost containers 2 has a longer length and longer stroke of the movable plug 5 compared with the rest of the containers 1, in order to select the gaps formed during assembly of the package from containers 1, 2 and compensate for the deformation component that occurs under loads.

The operation of the device is organized as follows. In the room, made in the deepening of the earth or in the mine, between two opposite parallel walls 8, unloading plates 7 are installed, one or more on each side. Between them there is a working table 6. On the table 6, coaxially unloading plates 7 are placed in assembled form high-pressure containers 1 and 2 with multi-punch apparatus 3 for growing crystals. The high-pressure container 2 compacts the package of containers 1 on the axis of the unloading plates 7, the inner channel of which has a larger area or greater pressure inside than the others, and one of its movable plugs 6 has a stroke that allows sealing the package of containers 1, 2 of high pressure and to compensate for the deformation component of the package and unloading plates 7 at maximum load.

In FIG. 3 shows an example of a high-pressure container 2 with a multi-punch apparatus 3 for the synthesis of diamonds. In containers 1, 2 of a high pressure of cylindrical shape, multi-punch apparatus 3 of high pressure in the form of a cube are placed. Between the surfaces of the multi-punch apparatus 3 and the inner cylindrical surface of the container 1, 2, four inserts 10 are installed on the keys 9, having an outer surface corresponding to the inner surface of the container 1, 2. The containers 1, 2 are closed on both sides by movable plugs 4 and 5. In the other variant pairs of adjacent containers 2, 3 are closed with one common stopper. Four plugs are made in plugs 4 and 5 opposite the liners 10, in which there are pistons forming hydraulic cylinders 11 for pushing plugs 4 and 5 when disassembling containers 1 and 2. In plugs 5, electrical inlets 12 are made for heating and for monitoring temperature and pressure , inputs 13 of the cooling medium, inputs 14 of a high pressure medium.

The sealing of the package of containers 1, 2 is realized using the container 2 (Fig. 1), which has a larger inner diameter (or greater pressure inside) compared to the other containers 1, and one of its movable plugs - plug 5 has a stroke equal to the total clearance between containers 1, 2 after they are installed on table 5, which allows to seal the package of containers 1, 2.

The hydraulic system of the high-pressure device consists of a high-pressure pump station 15, a multiplier - an accumulator 16, a high-pressure manifold connected to it with controlled valves and valves 17. The synthesis process control system 18 is connected via electrical connectors 19 to control sensors 20 installed in multi-punch units 3 . The pressure in each container 1, 2 is maintained by an individual high pressure controller. The power supply is supplied through the electrical connectors 19. The synthesis process in each apparatus 3 is controlled in a known manner.

The device operates as follows.

The cubic cell 21 for growing diamonds is collected in a known manner. Sensors 20 are installed on it to control the synthesis process, a cell 21 is placed in the center of a multi-punch apparatus 3 located on a slide 22, which are attached to a movable plug 5. First, five punches 23 form a synthesis chamber for synthesis, separated by elastic gaskets 24. Sensors 20 control the synthesis process and the heater cables of the cell 21 are connected through sealed entries 12 in the movable plug 5 with external cables. The last sixth punch 23 is installed, and the entire multi-punch apparatus 3 is sealed with an elastic cover 25. The multi-punch apparatus 3 is placed in the container 1, 2 and the container 1, 2 is closed with movable plugs 4 and 5.

The containers 1, 2 are alternately mounted on the table 5 on the axis of the unloading plates 7, and the entire package is sealed by the container 2. This container 2 creates an axial force exceeding the force required for synthesis in the remaining high-pressure containers 1. Each container 1, 2 high pressure is connected to a known device for automatic control of the synthesis process to the collector of high pressure, cooling and power supply. Upon reaching the required pressure in the multi-punch apparatus 3 in the cell 21, the temperature rises and the process of diamond synthesis begins. The connection procedure is repeated in sequence with all containers 1, 2, placed on the axis of the unloading plates 7. Since the process of growing diamonds lasts for days, the pressure and temperature control systems operate in an autonomous automatic mode. At the end of the process, in each of the devices 3 the heating system is turned off, the high pressure is vented from the container 1, the cooling system is turned off. Lastly, pressure is released from container 2, which compresses the bag. After that, each high-pressure container 1, 2 is disconnected from the high-pressure manifold, the mains, and the control system for the synthesis process. After that, containers 1, 2 are alternately pushed onto table 5. Moving plugs 4, 5 are pulled out from containers 1, 2 together with multi-punch apparatus 3, depressurization of multi-punch apparatus 3 is carried out. One of six punches 22 is pulled out and cell 20 with grown crystals is removed. After cleaning the device and inspecting the punches, the process can be repeated.

Claims (9)

1. A device for growing diamond crystals, containing containers mounted in a burial ground coaxially in a row with a corresponding multi-punch high-pressure apparatus placed in each container, and at least one unloading plate is installed between each of the extreme containers and the corresponding burial wall. 2. The device according to claim 1, in which the containers are installed in the burial ground on the table. 3. The device according to claim 1, in which each container is closed on the sides by axially movable plugs. 4. The device according to claim 1, in which each pair of neighboring containers is closed from the facing each other sides with one axially movable stopper. 5. The device according to claim 3 or 4, in which the hydraulic cylinders are made in the plugs to push the plugs out of the container. 6. The device according to claim 3 or 4, in which one of the containers has an inner diameter larger than the remaining containers, and the working stroke of the movable plug of this container is equal to the total width of all the gaps between the containers during their initial installation. 7. The device according to claim 1, in which in each container between the multi-punch apparatus and the inner cylindrical surface of the container are liners that are fixed on the cylindrical wall of the container. 8. The device according to claim 1, in which in each container the multi-punch apparatus is mounted on a slide. 9. The device according to claim 3 or 4, in which hermetic electrical inputs, inputs of a cooling medium, inputs of a high pressure medium, and also inputs of sensors for monitoring the synthesis process are made in one of the plugs of each container.

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