RU41034U1 - PUMP FOR INJECTION WORKS, INJECTION PACKER AND SYSTEM FOR INJECTING ORGANIC AND MINERAL COMPOSITIONS - Google Patents

Abstract

The group of utility models relates to the field of construction, namely, all utility models can be used in combination or separately when conducting waterproofing, repair, restoration and restoration work at various construction sites. The purpose of utility models is to create such an integrated system for injecting organic and mineral compounds in the repair and waterproofing works, which provides a wide range of works in various building structures with continuous monitoring of the pressure of the injected composition. To do this, the injection pump is equipped with a protective device made in the form of a housing with two adjacent insulated chambers separated by a membrane, while one chamber is connected to the discharge cavity of the valve box, and the second chamber is hydraulically connected to the inlet fitting of the pressure gauge and is filled with transmission fluid pressure gauge. Injection packer, on one end of which an elastic sleeve is fixed with a stop, mounted together with the pusher coaxially

on a tubular casing with the possibility of limited axial displacement and expansion under the action of a pressure nut, allows for reliable sealing of the well when an injection composition is supplied through the said well. The system consisting of a pump, a packer and a high pressure hose connecting them allows a wide range of repair and insulation work using reliable small-sized equipment.

Description

This group of utility models relates to construction and all utility models can be used in a complex or separately for waterproofing, repair, restoration and restoration works using organic and mineral compounds.

This group of utility models can be used in the technologies currently used, which allow reinforcing soils, foundations, and building structures by investing in pores and cracks of various reinforcing compositions containing, as an additive, mineral dispersed powders with a high specific surface and fine-porous structure, for example bentonite (specific surface - 100,000 cm ² / g).

Also, a group of utility models can be used when carrying out work using hydroactive polyurethane compounds with a viscosity in the uncured state from 15 to 1200 MPa * s, which allows for high-quality injection during a wide range of waterproofing works.

When carrying out such work in soils and building structures, it is necessary to pre-drill the wells. Then in

the injection packer is unfastened to the well, through which injection composition is injected into the well. From the well, the corresponding fixing or waterproofing composition enters through the cracks in the body of the structure. The injection is carried out by a pump with a small capacity, but developing a pressure of up to 10 MPa.

Known pumps for pumping inhomogeneous viscous materials, such as concrete. These pumps can be made according to various design schemes. So, if it is necessary to ensure the pumping of large volumes of the mixture, the concrete pump can be made with two cylinders (see, for example, RF patent No. 2127829, published. 03.20.99). However, such a pump design is not suitable for injecting formulations into concrete structures in local limited places.

Also known is a pump designed for pumping inhomogeneous viscous materials, which can be used for dosed concrete supply and injection work.

The pump includes a drive lever mounted on the frame, connected with a piston placed in the cylinder, a valve box hydraulically connected to the working chamber of the cylinder and a manometer for determining the pressure of the pumped solution (see, for example, US Pat. RF No. 2150606, class CL F 04 B 15/02, 06/10/2000) (1).

However, in this pump, the pressure gauge for determining the pressure in the system and the amount of pumped solution is not directly connected to the hydraulic line of the solution, but is included in the sensor system of the amount of pumped solution. On the one hand, this reduces the accuracy of determining the necessary parameters, and on the other hand, complicates the design of the pump.

The first useful model of the group related to the pump for injection works is aimed at solving the problem of creating a design that would ensure reliable operation of both the pump itself and the entire system for injection of the pumped injection composition, with continuous monitoring of its pressure.

The technical result that can be obtained using the proposed pump is to protect the pressure gauge assembly from the action of the pumped composition, which can damage the entire pressure gauge assembly if it is not removed from the system channels in time, as well as to increase the accuracy of the measured operating parameters of the system.

The problem is solved due to the fact that in the injection pump, including a cylinder mounted on the frame with a piston placed in the cylinder, a valve box hydraulically connected to the cylinder’s working chamber and a pressure gauge, there is a protective device made in the form of a housing with two adjacent insulated chambers , separated by a membrane, while one chamber is connected to the discharge cavity of the valve box, and the second chamber is hydraulically connected to the inlet fitting of the pressure gauge and filled with liquid for pressure transmission to the pressure gauge.

It is advisable to fill with glycerol as a fluid for transmitting pressure to the pressure gauge, the chamber hydraulically connected to the inlet fitting of the pressure gauge.

In addition, the task is solved by making the housing of the protective device detachable and installing it on the valve housing.

Another important task that must be solved and the solution of which is directed to the construction of the second utility model

group, is the creation of such an injection packer, which would solve a wide range of problems that arise when injecting the composition into various designs. At the same time, there is a need to create a simple design of an injection packer that allows you to place and securely fix it in a drilled well selected in accordance with the design features, dimensions and fracturing of the structure into which the injection is carried out.

Known injection packer used to pump the sealing mixture, for example, into the ground (see, for example, the certificate of the Russian Federation for utility model No. 29735, M. class. E 02 D 3/12, published. 05.27.2003).

The specified injection packer includes a tubular body, on one end of which is fixed an elastic sleeve forming an elastic inflatable chamber and at the other end is a blind flange.

The disadvantage of this packer is the difficulty of its use in small diameter wells, since in order to ensure reliable overlapping of the well during its sealing, it is necessary to create large pressures in the cavity of an elastic inflatable chamber having very small dimensions.

The utility model related to the injection packer is aimed at solving the problem of creating a simple and reliable packer design for sealing wells through which the solution is injected into the structure.

The technical result, which can be obtained by using the proposed injection packer, is to reliably unfasten (anchor) the various sizes of the packer in the well with the necessary tightness of the attachment point when using a unified design.

The problem is solved due to the fact that the injection packer includes a tubular body with two threaded ends, on one of which an elastic sleeve is fixed with a stop, mounted together with the pusher coaxially on the tubular body with the possibility of limited axial displacement and expansion under the action of a pressure nut placed at the second threaded end of the tubular body together with a check valve.

And also due to the fact that the non-return valve is made in the form of a valve body, inside of which a spring-loaded locking ball is placed, and on the outer surface there is a seat for connecting the discharge hose of the injection pump.

And also due to the fact that the elastic sleeve, mounted coaxially on the body, is made of vulcanized rubber, in which the effective concentration of cross-links should be in the range (3-19) * 10 ¹⁹ cm ^-3 , shore hardness A 50-90.

And also due to the fact that the packer can be made with the outer diameter of the elastic sleeve mounted coaxially on the body, in the range from 8 to 19 mm, while the ratio of the cross-sectional area of the elastic sleeve to its outer diameter is in the range from 4.5 to 12.5 respectively.

A common system for injecting working solutions into various building structures solves the problem of creating a mobile, compact and reliable installation for waterproofing and repair work.

The technical result that can be obtained using the proposed system for injection is to provide the ability to quickly and efficiently carry out various works in a wide variety of conditions, ranging from surface

works and ending with repair work in tunnels and collectors.

The problem is solved due to the fact that in an injection system comprising an injection pump and an injection packer, the injection pump includes a cylinder mounted on a frame with a piston located in the cylinder, a valve box and a pressure gauge hydraulically connected to the cylinder’s working chamber. The pump is equipped with a protective device made in the form of a housing with two adjacent insulated chambers separated by a membrane, while one chamber is connected to the discharge cavity of the valve box, and the second chamber is hydraulically connected to the inlet fitting of the manometer and filled with liquid to transfer pressure to the manometer.

The pump and the injection packer are hydraulically interconnected by means of a connecting hose, on which a clamp is fixed for tight connection with the seat of the injection packer, including a housing with two threaded ends, on one of which an elastic sleeve is mounted, mounted together with the pusher, coaxially on the tubular housing with limited axial movement under the action of a pressure nut located on the second threaded end of the tubular body together with a check valve.

The description of utility models is illustrated by three drawings, in which Fig. 1 shows a general view of an injection pump, Fig. 2 shows a protective device, and Fig. 3 shows an injection packer.

The pump (figure 1) for injection work, includes a frame 1 on which is mounted a cylinder 2 with a piston 3 located inside the cylinder 3. The piston 3 moves reciprocally inside the cylinder

2 by means of a drive lever 4 connected to the piston 2. A valve box 5 is hydraulically connected to the working chamber of the cylinder 2, on which a pressure gauge is attached 6. The injection cavity (not shown) of the valve box 5 is connected to the inlet fitting of the pressure gauge 6 through a protective device 7 ( figure 2), which is made in the form of a detachable housing 8 with two adjacent insulated cameras 9.10. Both chambers 9 and 10 are separated by a membrane 11. The chamber 9 is connected to the discharge chamber of the valve box 5, and the chamber 10 is hydraulically connected to the inlet fitting of the pressure gauge 6 and is filled with liquid to transfer pressure to the pressure gauge 6. As a liquid to transfer pressure to the pressure gauge 6 chamber 10, hydraulically connected to the inlet fitting of the pressure gauge, is filled with glycerin. Instead of glycerin, another non-aggressive, non-freezing liquid, such as alcohol, can be used.

In addition to the chamber 9, the discharge cavity of the valve box 5 of the pump is hydraulically connected to the injection packer via a connecting hose (not shown in the drawings).

The injection packer (see Fig. 3) contains a tubular body 12 with two threaded ends, one of which has an elastic sleeve 13 fixed with a stop, mounted together with the pusher 14 coaxially on the tubular body 12 with the possibility of limited axial displacement and expansion under pressure a nut 15 located on the second threaded end of the tubular body 12 in conjunction with a check valve. By varying the length and diameter of the tubular body and elastic sleeve, a set of injection packers is obtained for use in wells of various depths and diameters, depending on the required conditions. Most preferred

is the following series of lengths of injection packers: 110 mm, 150 mm, 200 mm, 300 mm and 400 mm.

The non-return valve is made in the form of a housing 16, inside of which a spring-loaded locking ball 17 is placed, and on the outer surface there is a seating socket 18 for connecting the pump discharge hose.

The packer is unfastened in the borehole mechanically, namely by moving the pusher 14 under the action of the pressure nut 15. When moving, the pusher 14 acts on the pressure washer 19 and on the elastic sleeve 13, which is mounted on the tubular body 12 with emphasis in the end nut and washer 20 .

Under the action of the compressive load, the elastic sleeve bursts and fixes the injection packer in the well with its simultaneous sealing. To ensure the necessary effort to fix the packer, as well as reliable sealing of the well, it is essential to select the characteristics of the material of the elastic sleeve 13, as well as its relative dimensions, which allow multiple deformation of the sleeve without damage.

As a material for the manufacture of an elastic sleeve, vulcanized rubber was used, in which the effective concentration of cross-links should be in the range (3-19) * 10 ¹⁹ cm ^-3 , and shore hardness A 60-90, while the ratio of the cross-sectional area of the elastic sleeve to its outer diameter lies in the range from 4.5 to 12.5. This significant interval of the relationship is explained by the need to select the design parameters of the packer, allowing the use of a unified design in various conditions and to solve a wide variety of technological problems associated with the use of described

useful models. Such a unified design is suitable for creating a number of standard sizes of packers intended for installation in wells that differ in diameter and in depth.

To seal a well drilled with a drill diameter of 20 mm, the outer diameter of the elastic sleeve 13, mounted coaxially on the body, is 19 mm, and the ratio of the cross-sectional area of the elastic sleeve to its outer diameter is 12.5. This ratio provides the extension of the elastic sleeve with the achievement of sealing the cavity of the well.

For sealing a well drilled with a drill with a diameter of 18 mm, the outer diameter of the elastic sleeve 13 mounted coaxially on the body is 17 mm, and the ratio of the cross-sectional area of the elastic sleeve to its outer diameter is 10.

To seal a well drilled with a drill diameter of 16 mm, the outer diameter of the elastic sleeve 13 mounted coaxially on the body is 15 mm, and the ratio of the cross-sectional area of the elastic sleeve to its outer diameter is 8.5.

When performing an elastic sleeve 13 with an outer diameter of 13 mm, the ratio of the cross-sectional area of the elastic sleeve to its outer diameter is 8.

The smallest outer diameter of the elastic sleeve 13 with this design of the injection packer is 8 mm. The ratio of the cross-sectional area of the elastic sleeve to its outer diameter is 4.5.

Together, the pump and the injection packer are hydraulically connected by means of a high pressure connecting sleeve 21 (Fig. 1),

forming a single system for injection in the conduct of waterproofing, repair, restoration and restoration works using organic and mineral injection compounds.

Claims (8)

1. Pump for injection work, including a cylinder mounted on the frame with a piston located in the cylinder, a valve box hydraulically connected to the working chamber of the cylinder and a manometer, characterized in that the pump is equipped with a protective device made in the form of a housing with two adjacent insulated chambers separated between each other with a membrane, while one chamber is connected to the discharge cavity of the valve box, and the second chamber is hydraulically connected to the inlet fitting of the pressure gauge and is filled with liquid to transmit pressure I'm on the manometer. 2. The pump for injection work according to claim 1, characterized in that as a fluid for transmitting pressure to the manometer, the chamber hydraulically connected to the inlet fitting of the manometer is filled with glycerin. 3. The pump for injection work according to claim 1, characterized in that the housing of the protective device is made detachable and mounted on the valve housing. 4. An injection packer comprising a tubular body with two threaded ends, on one of which an elastic sleeve is fixed with a stop, characterized in that the elastic sleeve is mounted together with the pusher coaxially on the tubular body with the possibility of limited axial displacement and expansion under the action of a pressure nut placed at the second threaded end of the tubular body together with a check valve. 5. The injection packer according to claim 4, characterized in that the check valve is made in the form of a body, inside which a spring-loaded shut-off ball is placed, and on the outer surface there is a seat for connecting the pump discharge hose made in accordance with claim 1. 6. The injection packer according to claim 4, characterized in that the elastic sleeve mounted coaxially on the housing is made of vulcanized rubber, in which the effective concentration of cross-links must be in the range (3-19) · 10 ¹⁹ cm ^-3 , and hardness Shore A 50-90. 7. The injection packer according to claim 4, characterized in that it is made with an elastic sleeve mounted coaxially on the housing, having an outer diameter ranging from 8 to 19 mm, while the ratio of the cross-sectional area of the elastic sleeve to its outer diameter is within from 4.5 to 12.5, respectively. 8. A system for injecting working solutions containing an injection pump and an injection packer, characterized in that the pump is made in accordance with claim 1, wherein the pump and the injection packer are hydraulically interconnected by means of a connecting hose to which a clamp for a tight connection with the landing nest of the injection packer, made in accordance with paragraph 4.