CN213331052U

CN213331052U - Hydraulic end frame

Info

Publication number: CN213331052U
Application number: CN202021656341.1U
Authority: CN
Inventors: 王佳琦; 宫兆玲; 魏中兰; 王宗雷; 侯祖刚; 庞志国; 徐淑彬; 张浩谦; 石宛铭
Original assignee: Dezhou United Petroleum Technology Corp
Current assignee: Dezhou United Petroleum Technology Corp
Priority date: 2020-07-30
Filing date: 2020-08-11
Publication date: 2021-06-01
Anticipated expiration: 2030-08-11
Also published as: CN213298473U; CN213116645U; CN112032147A; CN112032138B; CN112032139A; CN112032011B; CN112032139B; CN213331049U; CN213017023U; CN112032011A; CN213016526U; CN213017024U; CN213478820U; CN213331733U; CN213298193U; CN112032138A; CN112032147B; CN213116284U

Abstract

The utility model provides a hydraulic end frame, relates to oil and equips technical field, and this hydraulic end frame includes vertical setting and end to end's first wallboard, first end plate, second wallboard and second end plate in order, first wallboard, first end plate, second wallboard and second end plate enclose and form accommodation space, accommodation space is for latticedly by the panel of vertical setting. The embodiment of the utility model provides an in, the inside accommodation space of frame is latticed for by the panel separation of vertical setting, makes the frame strengthen greatly on the whole bearing capacity, provides firm bearing structure for setting up a plurality of working fluid cylinders.

Description

Hydraulic end frame

Technical Field

The utility model relates to a technical field is equipped to the oil, concretely relates to hydraulic pressure end frame.

Background

The pressure flooding technology is a measure production increasing technology which utilizes the conventional fracturing construction technology to inject a large-volume efficient oil displacement agent into a stratum to recover the energy of the stratum, utilizes the displacement and replacement functions of the efficient oil displacement agent to excavate residual oil and improve the utilization degree of the reservoir. In the practice of pressure flooding operation of oil fields in Daqing China, the accumulated oil increase in the pressure flooding technical stage is 4 times of that of conventional fracturing measures, and the effectiveness is fully verified.

At present, a part of oil fields are subjected to pressure drive operation by using a fracturing truck, a common fracturing truck generally comprises a chassis, and a diesel engine, a hydraulic torque converter, a transmission shaft, a fracturing pump and the like which are arranged on the chassis, wherein in the working process, after the diesel engine is started, the diesel engine is subjected to speed change and torque change by the hydraulic torque converter, and then the fracturing pump is driven to rotate by the transmission shaft so as to realize the fracturing operation.

However, in the crankshaft type plunger pump in the prior art, the stroke is short, the reversing times are many, the plunger is frequently moved, and the service life of a wearing part is short, for example, the service life of a valve seat, a valve rubber sheet and the like at a hydraulic end is only dozens of hours; in addition, the coverage range of the output pressure and the flow of the crankshaft type plunger pump is narrow, and if the coverage range is required to be improved, the hydraulic ends with different cylinder diameters are required to be replaced; in addition, when the plunger is frequently and quickly reversed, fracturing fluid is discharged without being fully sucked, so that the suction efficiency is not high, and the working efficiency is low; in addition, a crankshaft, a power input gear, a connecting rod, a box body of a hydraulic end, a seat body and the like are integrally installed in the fracturing pump, so that the fracturing pump is complex in structure, high in manufacturing cost and inconvenient to assemble, disassemble and maintain; in addition, the power input gear rotates at high speed and heavy load, the requirements on lubrication and cooling are high, and a lubrication system with a complex arrangement structure and a corresponding cooling system are required.

The hydraulic pressure driving pump has the advantages of long stroke, less reversing times, long service life of easily damaged parts and the like. However, the existing hydraulic end frame cannot meet the installation requirements of a plurality of working hydraulic cylinders, and the increase of the discharge capacity of the hydraulic pressure drive pump is restricted.

SUMMERY OF THE UTILITY MODEL

The utility model discloses above-mentioned technical problem to exist among the prior art provides a hydraulic pressure end frame, satisfies the installation requirement of a plurality of working fluid cylinders.

In order to realize the technical purpose, the embodiment of the utility model provides a hydraulic pressure end frame, including vertical setting and end to end's first wallboard, first end plate, second wallboard and second end plate in order, first wallboard, first end plate, second wallboard and second end plate enclose and form accommodation space, accommodation space is separated for latticedly by the panel of vertical setting.

Furthermore, the rack is provided with at least one through hole which penetrates through the rack along the length direction.

Further, the plate comprises at least one partition plate extending along the length direction of the rack, one end of the partition plate is fixedly connected with the first end plate, and the other end of the partition plate is fixed with the second end plate.

Further, the panel still includes at least one fixed plate that extends along frame width direction, the one end of fixed plate with first wallboard fixed connection, the other end with second wallboard fixed connection.

Further, the panel includes along at least one backup pad of frame width direction extension, the one end of backup pad with first wallboard fixed connection, the other end with second wallboard fixed connection.

Furthermore, the lower sides of the two ends of the rack are respectively provided with an accommodating cavity.

The embodiment of the utility model provides an in one or more technical scheme, following technological effect or advantage have at least:

the embodiment of the utility model provides a hydraulic end frame can satisfy the operation requirement of a plurality of working cylinders. The first end plate and the second end plate provide support for installation of the valve box, and the first wall plate and the second wall plate can connect the first end plate and the second end plate together and can bear loads in the length direction of the frame when the hydraulic cylinder works. The inside of the frame is divided into a grid shape by a vertically arranged plate, so that the bearing capacity of the whole frame is greatly enhanced.

Drawings

Fig. 1 is a top view of a hydraulic pressure drive pump according to an embodiment of the present invention.

Fig. 2 is a front view of the hydraulic pressure drive pump hydraulic pry according to an embodiment of the present invention.

Fig. 3 is the utility model relates to a top view of hydraulic pressure drives pump hydraulic sled of embodiment.

Fig. 4 is a left side view of fig. 1.

Fig. 5 is a schematic structural view of the rack.

Description of the reference numerals

1-hydraulic pump station pry, 3-hydraulic pry, 301-frame, 3011-first wall plate, 3012-second wall plate, 3013-first end plate, 3014-second end plate, 3015-first partition plate, 3016-second partition plate, 3017-first fixing plate, 3018-second fixing plate, 3019 a-first supporting plate, 3019 b-second supporting plate, 302-hydraulic cylinder, 303-hydraulic piston rod, 304-reversing valve, 305-first valve box, 306-second valve box, 307-first cylinder sleeve, 308-second cylinder sleeve, 6-split connecting pipeline system, 7-slurry sucking pipeline system, 8-slurry discharging pipeline system, 9-spraying system and 10-base.

Detailed Description

Other objects and advantages of the present invention will become apparent from the following explanation of the preferred embodiments of the present application.

Example 1

As shown in figure 1, the hydraulic pressure drive pump comprises a hydraulic pump station pry 1 and a hydraulic pry 3, wherein the hydraulic pump station pry 1 is connected with the hydraulic pry 3 through a split connecting pipeline system 6. Hydraulic pump station sled 1 is used for providing hydraulic oil to hydraulic sled 3, and hydraulic sled 3 then is used for turning into the pressure of working medium with the pressure of hydraulic oil, carries out the pressure and drives the operation.

As shown in fig. 2 to 5, the hydraulic pressure drive pump hydraulic pry 3 comprises a frame 301 and three working units connected with the frame 301. The working unit comprises a hydraulic cylinder 302 and a first hydraulic end and a second hydraulic end which are symmetrically arranged at two sides of the hydraulic cylinder 302. The hydraulic cylinder 302 comprises a hydraulic piston rod 303, the hydraulic piston rod 303 has a first output end and a second output end which are oppositely arranged, the first output end is connected with the first hydraulic end, and the second output end is connected with the second hydraulic end.

The rack 301 is installed on the upper side of the base 10, and the base 10 is used for providing support for the rack 301, the slurry suction pipeline system 7, the slurry discharge pipeline system 8 and the spraying system 9.

In this embodiment, there are three working units, but it should be noted that there are 2 to 10 working units as required. Further preferably, the number of the working units is 3-5. The utility model discloses an increase the quantity of work unit and improved the maximum discharge capacity that the pump was driven to hydraulic pressure.

Each working unit comprises a hydraulic cylinder 302 and a first hydraulic end and a second hydraulic end which are symmetrically arranged at two sides of the hydraulic cylinder 302. The hydraulic cylinder 302, the first hydraulic end and the second hydraulic end are all fixedly connected with the frame 301. In this embodiment, the hydraulic cylinder 302 is configured to convert hydraulic energy into a reciprocating linear motion of the hydraulic piston rod 303, and the hydraulic piston rod 303 drives the first hydraulic end and the second hydraulic end to alternately suck in and discharge a pressure driving medium.

The hydraulic cylinder 302 is connected to a reversing valve 304, and the reversing valve 304 is used for driving the hydraulic cylinder 302 to reverse in a reciprocating manner.

The first hydraulic end includes a first valve housing 305 and a first cylinder jacket 307. The first valve box 305 is fixedly connected with the frame 301, and the first cylinder sleeve 307 is connected with the first valve box 305 in a sealing manner. The first output end is provided with a slurry piston, and the slurry piston is hermetically and slidably connected with an inner hole of the first cylinder sleeve 307.

The second hydraulic end includes a second valve housing 306 and a second cylinder jacket 308. The second valve box 306 is fixedly connected with the frame 301, and the second cylinder sleeve 308 is connected with the second valve box 306 in a sealing manner. The second output end is provided with a slurry piston, and the slurry piston is connected with the inner hole of the second cylinder sleeve 308 in a sealing and sliding manner.

A water supply valve and a water drain valve are arranged in the first valve box 305 and the second valve box 306. When the hydraulic piston rod 303 moves from left to right, the slurry piston in the first cylinder sleeve 307 moves from left to right, the water outlet valve of the first valve box 305 positioned on the left side of the rack 301 is opened, the water inlet valve is closed, and the pressure driving medium is sucked into the first cylinder sleeve 307; meanwhile, the mud piston in the second cylinder sleeve 308 moves from left to right, the water feeding valve of the second valve box 306 on the right side of the frame 301 is opened, the water discharging valve is closed, and the pressure driving medium in the second cylinder sleeve 308 is discharged outwards. When the hydraulic piston rod 303 moves from right to left, the above process is reversed, and the description is omitted. Thereby, the pressure energy of the hydraulic oil can be converted into the pressure energy of the pressure driving medium by the reciprocating motion of the hydraulic piston rod 303.

In this embodiment, three of the working units are arranged in parallel.

In this embodiment, the first valve housing 305 and the second valve housing 306 are preferably L-shaped valve housings having a large diameter and a large pressure-bearing capacity.

The hydraulic pressure drive pump hydraulic pry 3 further comprises a slurry suction pipeline system 7, the slurry suction pipeline system 7 is respectively connected with suction ports of the first hydraulic end and the second hydraulic end, and the first hydraulic end and the second hydraulic end suck a pressure drive medium into the first cylinder sleeve 307 or the second cylinder sleeve 308 through the slurry suction pipeline system 7.

The hydraulic pressure drive pump further comprises a slurry discharge pipeline system 8, and the slurry discharge pipeline system 8 is respectively connected with the discharge ports of the first hydraulic end and the second hydraulic end. The first hydraulic end and the second hydraulic end discharge the pressure driving medium in the first cylinder jacket 307 and the second cylinder jacket 308 through the slurry discharge pipe system 8.

Example 2

In order to provide support for structures such as the hydraulic cylinder 302, the valve box and the cylinder sleeve, the embodiment of the utility model provides a hydraulic end frame 301 is still provided, the installation and the operation requirement of a plurality of working fluid cylinders are satisfied.

The embodiment of the utility model provides a hydraulic end frame 301, including vertical setting and end to end connection's first wallboard 3011, first end plate 3013, second wallboard 3012 and second end plate 3014 in order, first wallboard 3011, first end plate 3013, second wallboard 3012 and second end plate 3014 enclose to close and form accommodation space, accommodation space is separated for latticedly by the panel of vertical setting. The accommodating space inside the rack 301 is divided into a grid shape by the vertically arranged plates, so that the bearing capacity of the rack 301 as a whole is greatly enhanced.

Specifically, frame 301 includes vertical setting and fixed first wallboard 3011, second wallboard 3012, first end plate 3013 and the second end plate 3014 as an organic whole, first wallboard 3011 with second wallboard 3012 sets up relatively, first end plate 3013 with second end plate 3014 sets up relatively. First wallboard 3011, first end plate 3013, second wallboard 3012 and second end plate 3014 end to end connection in order, and weld as an organic whole, enclose to close and form the skin of frame 301 to at the inside accommodation space that forms of frame 301. The first end plate 3013 and the second end plate 3014 provide support for installing the valve box, and the first wall plate 3011 and the second wall plate 3012 can connect the first end plate 3014 and the second end plate 3014 together and can bear loads in the length direction of the frame 301 when the hydraulic cylinder 302 works.

The plate comprises at least one partition board extending along the length direction of the rack 301, one end of the partition board is fixedly connected with the first end board 3013, and the other end of the partition board is fixed with the second end board 3014. In the rack 301 of this embodiment, a first partition 3015 and a second partition 3016 are provided, and the first wall 3011, the second wall 3012, the first partition 3015, and the second partition 3016 jointly bear the load in the length direction of the rack 301.

The plate further comprises at least one fixing plate extending along the width direction of the rack 301, wherein one end of the fixing plate is fixedly connected with the first wall plate 3011, and the other end of the fixing plate is fixedly connected with the second wall plate 3012. In this embodiment, two fixing plates, that is, a first fixing plate 3017 and a second fixing plate 3018, are disposed in the frame 301, through holes are disposed on the first fixing plate 3017 and the second fixing plate 3018, and the first fixing plate 3017, the second fixing plate 3018 and the through holes thereon can provide support for the hydraulic cylinder 302.

The plate comprises at least one supporting plate extending along the width direction of the rack 301, and one end of the supporting plate is fixedly connected with the first wall plate 3011, and the other end of the supporting plate is fixedly connected with the second wall plate 3012. The cylinder sleeve comprises a first supporting plate 3019a and a second supporting plate 3019b, through holes are formed in the first supporting plate 3019a and the second supporting plate 3019b, and the through holes in the first supporting plate 3019a and the second supporting plate 3019b can provide support for the cylinder sleeve.

It is emphasized that the diameters of the through holes of the first end plate 3013, the second end plate 3014, the first fixing plate 3017, the second fixing plate 3018, the first support plate 3019a and the second support plate 3019b may be the same or different, but all are coaxial, corresponding to the same working unit.

Frame 301's both ends downside is equipped with one respectively and holds the chamber, should hold the water tank that the chamber can be used for placing spraying system 9, has rationally utilized the space on the hydraulic sled 3.

The apparatus of the present application has been described in detail with reference to the preferred embodiments thereof, however, it should be noted that those skilled in the art can make modifications, alterations and adaptations based on the above disclosure without departing from the spirit of the present application. The present application includes the specific embodiments described above and any equivalents thereof.

Claims

1. The utility model provides a hydraulic end frame, its characterized in that, including vertical setting and end to end's first wallboard, first end plate, second wallboard and second end plate in order, first wallboard, first end plate, second wallboard and second end plate enclose and form accommodation space, accommodation space is separated for latticedly by the panel of vertical setting.

2. The fluid end frame of claim 1 wherein the frame defines at least one through hole extending lengthwise through the frame.

3. The fluid end frame of claim 1 wherein the sheet material includes at least one spacer extending along a length of the frame, one end of the spacer being fixedly attached to the first end plate and the other end of the spacer being fixedly attached to the second end plate.

4. The fluid end rack of claim 1, wherein the sheet material further comprises at least one securing plate extending widthwise of the rack, the securing plate having one end fixedly attached to the first wall panel and the other end fixedly attached to the second wall panel.

5. The fluid end frame of claim 1 wherein the sheet material includes at least one support plate extending across the width of the frame, the support plate having one end fixedly attached to the first wall panel and the other end fixedly attached to the second wall panel.

6. The fluid end rack of any one of claims 1-5 wherein the rack has a receiving cavity on each of the two lower sides.