RU42059U1 - Wellhead CHEMICAL REAGENT SUPPLY UNIT - Google Patents

Abstract

1. Wellhead unit for supplying a chemical reagent to the well, including a tank for a chemical reagent heated by a heating system, a metering pump located in an airtight compartment, and a hydraulic system connecting the metering pump through a pipe to a tank, characterized in that the unit further comprises a cabinet, box or similar case with walls, a lid and doors, consisting of two compartments, in one of which, hermetically sealed, a metering pump with a reagent supply mechanism, an electrical cabinet with electrical equipment, e electrically connected to the reagent supply mechanism of the metering pump and to the tank heating system, a chemical reagent temperature sensor and a manometer for determining the pressure of the chemical reagent supply to the well, and in the second compartment there is a heated reagent tank equipped with a level sensor electrically connected to the electrical equipment of the control cabinet, and a hydraulic system connecting through the pipelines the tank with the reagent supply mechanism of the metering pump, while the temperature sensor of the chemical reagent is connected nen heated with capacitance manometer and - a hydraulic system and a feed-dozatora.2 reagent pump mechanism. The wellhead unit according to claim 1, characterized in that the electrical cabinet with electrical equipment and the metering pump are located in a sealed compartment floor. The wellhead unit according to claim 1, characterized in that the tank is equipped with a drain valve, as well as necks for installing a level sensor and for pouring the reagent into the tank. The wellhead block according to claim 3, characterized in that openings are made in the cabinet lid for outputting the neck of the container. 5. Wellhead according to claim 1, characterized

Description

The utility model relates to the field of oil production, in particular, to compact explosion-proof installations for dosed supply of a chemical reagent into a well for all methods of well operation (fountain, gas lift, UECC, USShK, etc.), and can be used for small dosing volumes, for example, surface active substances (surfactants), salt and paraffin inhibitors, corrosion inhibitors, demulsifiers, etc.

A known installation for the metered supply of surfactants in oil reservoirs containing a heated chemical tank installed on a common frame, an intermediate heating tank and a metering pump, which are connected in series with each other by pipelines with valves (see Auth. Certificate. USSR No. 827756 class E 21 B 43/00, 1979). At the same time, the capacity for the chemical reagent is heated by installing electric heaters in its cavity, which are placed in sealed chambers filled with a heat-resistant, explosion-proof liquid. This creates a safe working environment of the known installation when using explosive and fire hazardous reagents.

However, this known installation is very cumbersome, designed to dispense large volumes of reagents.

In addition, such a constructive implementation of the known installation, involves its use only in a relatively warm period of time, because at subzero temperatures, it is possible that the reagent freezes in pipelines connecting the tank to the metering pump.

Another disadvantage of the known installation is the lack of explosion safety of the installation as a whole, because in emergency situations

(for example, when a pipeline ruptures, the tank is depressurized) explosive chemicals can enter the electrical equipment zone, the metering pump zone, which can cause a fire. To exclude this, explosion-proof equipment is required, which leads to increased material costs.

Closest to the proposed utility model in technical essence is a chemical dosing unit, including a chemical tank heated by a heating system, a metering pump located in an airtight compartment, and a hydraulic system that connects the metering pump through the pipelines to the tank, while the airtight compartment with a metering pump located inside the tank for a chemical reagent (see Aut. certificate of the USSR No. 926243, class E 21 B 43/00, from 1979)

For this known installation is characterized by the same disadvantages as for the analogue, namely:

- it is intended for large volumes of dispensing;

- the placement area of the known installation, although somewhat smaller than that of the analogue, contains additional special nodes for introducing the reagent into the tank, which also makes it cumbersome;

- it is not explosion and fireproof due to the placement of the compartment with the metering pump directly in the tank in the environment of a chemical reagent. As a result of corrosion, the compartment may be depressurized and liquid will enter the electrical equipment area, which may lead to an explosion or fire. This makes the work of the known installation unreliable, and also requires constant monitoring of the condition of the material of the pressurized compartment for corrosion.

The technical problem to which the proposed utility model is directed is to create a compact wellhead feed unit

chemical reagent into the well, which is characterized by operational reliability and almost complete explosion safety when using standard explosion-proof equipment in the design, while at the same time ensuring the convenience of controlling the dosing process, reducing material costs and the possibility of the unit functioning both in summer and in winter.

The specified technical problem is solved by the proposed wellhead unit for supplying a chemical reagent to the well, including a chemical reagent tank heated by a heating system, a metering pump placed in an airtight compartment, and a hydraulic system connecting the metering pump through the pipelines to the tank, while the new one is that the unit additionally contains a cabinet, drawer or similar case with walls, a lid and doors, consisting of two compartments, in one of which, hermetically sealed, a metering pump with fur by the reagent supply mechanism, an electrical cabinet with electrical equipment, electrically connected to the reagent supply mechanism of the metering pump and the tank heating system, a chemical reagent temperature sensor and a pressure gauge to determine the pressure of the chemical reagent supply to the well, and a heated reagent tank equipped with a sensor is placed in the second compartment level, electrically connected to the electrical equipment of the control cabinet, and a hydraulics system connecting through the pipelines the tank with the pump-d reagent supply mechanism ozator, while the temperature sensor of the chemical reagent is connected to a heated tank, and the pressure gauge is connected to the hydraulic system and to the reagent supply mechanism of the metering pump.

In this case, the electrical cabinet with electrical equipment and the metering pump can be located in a sealed compartment floor.

The container in the proposed unit is equipped with a drain valve, as well as necks for installing the level sensor and for pouring the reagent into the vessel, and in this case, openings are made in the cabinet lid for the outlet of the vessel mouths.

The proposed wellhead unit may be additionally equipped with a visual level gauge located in the second compartment and mounted on the wall of the tank. The visual level gauge is connected to the indicated capacity through a ball valve and filter. In this case, the visual level gauge is made of steel and glass tubes, the first of which is equipped with a scale for visual determination of the volume of a chemical reagent in a tank and a scale for determining the exact consumption of a reagent for a certain period of time.

The temperature sensor of the chemical reagent in the proposed unit is connected to a heated container by means of a capillary tube passed through openings in the separation partition that separates the compartments of the cabinet, while the holes in the separation partition that separates the cabinet compartments are sealed with a rubber washer that compresses the capillary tube with screwed fittings.

As a manometer in the proposed block, an electrocontact manometer can be used, and at the same time the manometer is connected to the hydraulic system through a media separator. In this case, the pipeline from the media separator to the manometer is filled with an explosion-proof liquid.

Walls, a cover and cabinet doors can be made insulated.

The compartments in the cabinet are equipped with separate doors.

The specified technical problem is achieved due to the following. Due to the fact that the proposed unit additionally contains a cabinet with walls, a lid and doors, consisting of two compartments, their guaranteed isolation of these compartments from each other is ensured.

And due to the fact that in these different compartments are placed separately from each other, electrical equipment and capacity with the system

hydraulics, eliminating the ingress of liquid reagent into the zone of electrical equipment, which means that the likelihood of an explosion, fire is excluded. Placing a separator between the pressure gauge and the hydraulic system of the media, as well as filling the pipeline from this media separator to the pressure gauge with an explosion-proof liquid, also works for this task and creates another level of protection against liquid entering the compartment with electrical equipment.

Placing in the hermetic compartment along with the control cabinet and metering pump also a temperature sensor of the chemical reagent and pressure gauge allows for convenient control of the dosing process, as the control circuit of the metering pump and the tank heating system, located in the control cabinet, is directly connected to informative sensors. As a result, the operator easily monitors the dosing process by monitoring the equipment of only one compartment.

Thanks to the implementation of the block compact with the optimal arrangement of nodes and parts, a reduction in material costs is provided. Also, the fact that the design of the proposed wellhead block can be used standard, and not special (explosion-proof) equipment, which is very expensive.

The essence of the proposed utility model is characterized by figure 1 and figure 2, which depicts a General view of the wellhead block in the context: figure 1 is a front view, figure 2 is a side view.

The proposed wellhead supply unit of the chemical reagent contains a cabinet 1 with walls, a cover 2 and doors 3 and 4, consisting of two compartments 5 and 6. In the compartment 5, which is hermetically sealed, a metering pump 7 with a reagent supply mechanism consisting of a drive (hydraulic pusher) and reciprocating mechanism

the movement of the plunger, and an electrical cabinet 8 with electrical equipment located above it. The compartment 5 also has a sensor 9 for the temperature of the chemical reagent and a pressure gauge 10 (mainly electrical contact type) to determine the pressure of the supply of chemical reagent into the well. In the second compartment 6, a heated reagent tank 11 is placed, having a mainly rectangular cross section and equipped with a level sensor 12 electrically connected to the electrical equipment of the control cabinet 8, and a hydraulic system 13 connecting pipelines to the tank 11 with the reagent supply mechanism of the metering pump 7. The main function of the level sensor 12 is to turn off the drive of the metering pump 7 in the event of a decrease in the level of chemical reagent in the tank 11 below the minimum acceptable level. The level sensor 12 consists of a float with a magnet that moves along the guide tube. There are two reed elements in it for supplying a signal to the control cabinet 8 to the control panel. The temperature sensor 9 of the chemical reagent, located in compartment 5, is connected to a heated tank 11 by a capillary tube, and the pressure gauge 10 is connected to the hydraulic system 13 through a medium separator 19. The tank 11 is equipped with a drain pipe 14, and also with a neck 15 for installing a level sensor 12 and neck 16 for pouring a chemical reagent. The cover 2 of cabinet 1 also has openings for the outlet of the necks 15 and 16 of the tank 11. In the compartment 6 on the wall of the tank 11 a visual level gauge 17 is fixed, connected through a ball valve and a filter to the tank 11. To ensure the tightness of the compartments 5 and 6 of the hole in the partition separating compartments 5 and 6 of cabinet 1 are sealed either by means of a rubber washer compressing the capillary tube or by means of a fitting rigidly connected to this partition.

In order to exclude reagent leaks through the manometer 10 (in case of a malfunction), and to prevent this reagent from entering the electrical equipment zone, the manometer is connected by a pipeline to the hydraulic system 13 through a medium separator 19. Moreover, the specified pipeline from the medium separator 19 to the manometer 10 is filled with an explosion-proof liquid.

In the control cabinet 8, there are control circuits for the metering pump 7 and the heating system of the tank 11. The metering pump 7 is regulated by two time relays that control the frequency of movement of the metering pump drive - the hydraulic pusher rod. It is possible to monitor the following parameters from the operator’s control panel: the presence of the reagent in the tank 11 and the operation of the metering pump 7.

For trouble-free operation of the proposed wellhead in both summer and winter, the walls, cover 2 and doors 3 and 4 of cabinet 1 are made insulated.

The proposed wellhead chemical feed unit operates as follows.

The unit is installed at the facility, for example, at the well, the power supply is connected to the control cabinet 8, and the hydraulic system 13 through the pipe 18 to the pipeline connected to the cavity of the tubing of the well. Capacity 11 is filled with a chemical reagent. The volume of reagent injection is determined for one swing of the metering pump 7. The time relay of the frequency generator of the control unit located in the control cabinet 8 is set to the required frequency of movement of the hydraulic pusher of the metering pump 7. The oscillating movement of the hydraulic pusher drives the plunger of the metering pump 7 and the chemical reagent is pumped into the hydraulic system 13 and then through the pipeline into the well. In the event of an increase in pressure in the hydraulic system 13 above the maximum

permissible pressure gauge 10 connected by a pipeline to the hydraulic system 13, disconnects the power supply to the metering pump 7.

In the process, the reagent is heated in the tank 11 due to the heating system to reduce its viscosity and to ensure reliable operation of the entire unit in the winter. When working with the proposed wellhead unit, the operator monitors the following parameters: injection pressure, temperature of the chemical reagent, its presence in the tank 11 and its flow rate during injection.

The proposed wellhead supply unit of the chemical reagent is compact, providing small injection volumes, which is especially important when working with low-production wells.

The specified unit is almost completely explosion-proof, and at the same time it is made of standard equipment, which significantly reduces its cost compared to the cost of the installation made of explosion-proof equipment.

Thanks to the special implementation of the structural units and their location, the proposed unit is successful in both summer and winter.

Claims (13)

1. Wellhead unit for supplying a chemical reagent to the well, including a tank for a chemical reagent heated by a heating system, a metering pump located in an airtight compartment, and a hydraulic system connecting the metering pump through a pipe to a tank, characterized in that the unit further comprises a cabinet, box or similar case with walls, a lid and doors, consisting of two compartments, in one of which, hermetically sealed, a metering pump with a reagent supply mechanism, an electrical cabinet with electrical equipment, e electrically connected to the reagent supply mechanism of the metering pump and to the tank heating system, a chemical reagent temperature sensor and a manometer for determining the pressure of the chemical reagent supply to the well, and in the second compartment there is a heated reagent tank equipped with a level sensor electrically connected to the electrical equipment of the control cabinet, and a hydraulic system connecting through the pipelines the tank with the reagent supply mechanism of the metering pump, while the temperature sensor of the chemical reagent is connected nen heated with capacitance manometer and - a hydraulic system and a feed mechanism reagent metering pump. 2. Wellhead block according to claim 1, characterized in that the electrical cabinet with electrical equipment and the metering pump are located in a sealed compartment floor. 3. The wellhead unit according to claim 1, characterized in that the tank is equipped with a drain valve, as well as necks for installing a level sensor and for filling the reagent into the tank. 4. Wellhead block according to claim 3, characterized in that in the cabinet lid holes are made for outputting the neck of the container. 5. Wellhead according to claim 1, characterized in that it is further provided with a visual level gauge mounted on the wall of the tank in the second compartment and connected to the tank through a ball valve and filter. 6. Wellhead according to claim 5, characterized in that the visual level gauge is made of steel and glass tubes, the first of which is equipped with a scale for visually determining the volume of the chemical reagent in the tank and a scale for determining the exact consumption of the reagent for a certain period of time. 7. Wellhead according to claim 1, characterized in that the temperature sensor of the chemical reagent is connected to the heated tank by means of a capillary tube passed through openings in the dividing wall separating the compartments of the cabinet. 8. The wellhead block according to claim 7, characterized in that the holes in the dividing wall separating the compartments of the cabinet are sealed with a rubber washer compressing the capillary tube with screwed fittings. 9. Wellhead block according to claim 1, characterized in that an electrocontact pressure gauge is used as a manometer. 10. Wellhead block according to claim 1 or 9, characterized in that the pressure gauge is connected to the hydraulic system through a media separator. 11. Wellhead according to claim 10, characterized in that the pipeline from the media separator to the pressure gauge is filled with an explosion-proof liquid. 12. Wellhead block according to claim 1, characterized in that the walls, lid and cabinet doors are made insulated. 13. Wellhead unit according to claim 1, characterized in that the compartments in the cabinet are equipped with separate doors.