CN114962217A

CN114962217A - Controlled compressor energy-saving operation system

Info

Publication number: CN114962217A
Application number: CN202210481286.4A
Authority: CN
Inventors: 刘永; 刘振宇; 胡正福; 孙振玉
Original assignee: Huzhou Huipengda Energy Saving Environmental Protection Technology Co ltd
Current assignee: Huzhou Huipengda Energy Saving Environmental Protection Technology Co ltd
Priority date: 2022-04-02
Filing date: 2022-05-05
Publication date: 2022-08-30
Anticipated expiration: 2042-05-05
Also published as: CN114962217B

Abstract

The invention discloses a controlled compressor energy-saving operation system, and relates to the technical field of compressor energy-saving equipment. The water tank comprises a shell, a base is arranged in the shell, a compressor body is arranged on the base, a plurality of deep grooves are formed in the outer side surface of the compressor body, heat conducting parts are arranged on the outer sides of the deep grooves and are communicated with heat exchange tubes arranged in the water tank through pipelines, a water pump is further arranged in the water tank and is communicated with a spray head arranged on the outer side of the water tank, each heat conducting part comprises a heat exchange plate, a first ring seat and a second ring seat, a plurality of heat exchange plates are arranged on the outer sides of the deep grooves and are distributed in an annular shape, and water inlet and outlet parts are arranged on the first ring seat and the second ring seat. According to the invention, the temperature of the water in the water tank is raised through the water subjected to heat exchange by the heat conduction part, the water subjected to temperature rise can be sprayed out from the spray head under the action of the water pump, and the heat generated by the compressor body can be recovered.

Description

Controlled compressor energy-saving operation system

Technical Field

The invention relates to the technical field of compressor energy-saving equipment, in particular to a controlled compressor energy-saving operation system.

Background

A compressor is a driven fluid machine that raises low-pressure gas into high-pressure gas, and is a heart of a refrigeration system. The refrigerating cycle is powered by sucking low-temperature and low-pressure refrigerant gas from the air suction pipe, driving the piston to compress the refrigerant gas through the operation of the motor, and discharging high-temperature and high-pressure refrigerant gas to the exhaust pipe.

Current compressor can produce certain heat when using, and the heat generally all is direct discharge, can not accomplish energy-conserving effect to the compressor, and current compressor simultaneously can not carry out fine fixing to the compressor at the during operation, appears the phenomenon of skew easily, has influenced the normal work of compressor.

Disclosure of Invention

The invention aims to provide a controlled compressor energy-saving operation system, which can raise the temperature of water in a water tank through the water subjected to heat exchange by a heat conduction part, and the water subjected to temperature rise can be sprayed out from a spray head under the action of a water pump, so that the heat generated by a compressor body can be recovered, and the related problems in the background art are solved.

In order to solve the technical problems, the invention provides a controlled compressor energy-saving operation system which comprises a shell, wherein a base is arranged in the shell, a compressor body is arranged on the base, the compressor body is fixed through a first fixing mechanism and a second fixing mechanism which are arranged on the inner wall of the shell, a plurality of deep grooves are formed in the outer side surface of the compressor body, heat conducting parts are arranged on the outer sides of the deep grooves and communicated with heat exchange pipes arranged in a water tank through pipelines, a water pump is further arranged in the water tank and communicated with a spray head arranged on the outer side of the water tank, each heat conducting part comprises a heat exchange plate, a first ring seat and a second ring seat, a plurality of heat exchange plates are arranged on the outer sides of the deep grooves, the plurality of heat exchange plates are distributed annularly, two ends of the plurality of heat exchange plates are respectively communicated with the first ring seat and the second ring seat, and the heat exchange plates, The first ring seat and the second ring seat form a plurality of water flow loops, water inlet and outlet portions are installed on the first ring seat and the second ring seat, heat conducting portions and heat exchange tubes which are arranged form a heat exchange assembly, water inside the heat conducting portions flows in a circulating mode through water inside the pipelines and the heat exchange tubes, the temperature of the water inside the water tank is increased through the water after heat exchange of the heat conducting portions, the water after temperature rise can be sprayed out from a spray head under the action of a water pump, heat generated by the compressor body can be recovered, resources are effectively utilized, and therefore the energy-saving effect is achieved.

Further, the heat exchange plate main part is curved plate, the concave surface of heat exchange plate set up with deep trouth complex arch, install the body between bellied two pairs of both sides face, the both ends of body all communicate with deep trouth, bellied length is less than the length of deep trouth.

Further, install seal assembly in the body, seal assembly includes sliding seat and arc, open the tip of arc has logical groove, the sliding seat cup joints on the body, the internal thread that the sliding seat was equipped with and the external screw thread intermeshing that the body was equipped with, the both ends of sliding seat are equipped with the gliding sliding plate in logical groove of arc, and the arc of installation can drive the arc and remove, and the water that is equipped with gets into the deep trouth through ring seat one or ring seat two at the in-process that flows to the opposite side of deep trouth through the installation body, discharges through ring seat two or ring seat one next time, realizes the circulation through the heat exchange tube inside of intercommunication and flows, and the body that is equipped with is located the deep trouth, accomplishes and takes away the heat of deep trouth inside.

Furthermore, a first annular channel is arranged in the first annular seat, two first partition plates distributed in the vertical direction are arranged in the first annular channel, a first water inlet head or a first water outlet head is arranged on the outer side of the first partition plate, and the first water inlet head or the first water outlet head is communicated with the first annular channels on the two sides of the first partition plate.

Furthermore, a second annular channel is arranged in the second annular seat, two second partition plates distributed in the vertical direction are arranged in the second annular channel, a second water inlet head or a second water outlet head is arranged on the outer side of the second partition plate, and the second water inlet head or the second water outlet head is communicated with the first annular channels on the two sides of the second partition plate.

Further, the first ring seat and the second ring seat are communicated with the deep groove.

Furthermore, check valves are arranged in the water inlet head I, the water outlet head I, the water inlet head II and the water outlet head II.

Furthermore, four heat exchange plates are arranged between the first ring seat and the second ring seat, two arc-shaped plates are arranged in each heat exchange plate, and when the arc-shaped plate on one side extends out of the cavity of the heat exchange plate, the arc-shaped plate on the other side is positioned in the cavity of the heat exchange plate.

Further, if be located two of upside the arc tip stretches into ring seat one, is located two of downside the arc tip stretches into in the ring seat two, if be located two of downside the arc tip stretches into in the ring seat one, is located two of upside the arc tip stretches into in the ring seat two, through the flow direction that changes the inside rivers of different bodys, is convenient for realize through all can through microthermal rivers in different regions, is convenient for carry out even heat dissipation to the week survey of compressor body.

The invention has the following beneficial effects:

1. according to the invention, the heat conducting part and the heat exchange pipe form the heat exchange assembly, water in the heat conducting part circularly flows with water in the heat exchange pipe through the pipeline, the water subjected to heat exchange by the heat conducting part raises the temperature of the water in the water tank, and the raised water can be sprayed out from the spray head under the action of the water pump, so that heat generated by the compressor body can be recovered, resources are effectively utilized, and the effect of energy conservation is achieved.

2. When water flow also passes through the upper pipe body, the threaded rod is arranged in the pipe body, the water flow passing through the threaded rod pushes the pipe body to rotate, the rotating pipe body pushes the sliding seat to move towards one side of the ring seat II until the sliding seat drives the arc-shaped plate to seal a water outlet of the water inlet head I, and the change of the flow direction of the water flow in the pipe body is realized.

3. According to the invention, the pipe body at the lower side pushes the corresponding sliding seat to drive the arc-shaped plate to move towards the inner side of the ring seat II, so that water is fed through the water inlet head I, water is discharged through the water outlet head I, and the flow direction of water flow in different pipe bodies is changed, so that low-temperature water flow which passes through different areas can be conveniently realized, and uniform heat dissipation is conveniently carried out on the circumference of the compressor body.

Of course, it is not necessary for any product in which the invention is practiced to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the description below are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of a heat conducting portion and a compressor body according to the present invention;

FIG. 3 is a schematic cross-sectional view of a heat-conducting portion according to the present invention;

FIG. 4 is a schematic view of a heat conducting portion according to the present invention;

FIG. 5 is a schematic structural view of a heat conducting frame of the present invention;

FIG. 6 is a schematic view of the seal assembly of the present invention;

FIG. 7 is a schematic view of the compressor body structure according to the present invention;

FIG. 8 is a schematic view of a partially developed forward flow structure of the heat conducting portion of the present invention;

FIG. 9 is a schematic view of a structure of the heat conducting portion of the present invention showing a partially developed water flow reversal flow;

FIG. 10 is a schematic view of a ring seat structure of the present invention;

FIG. 11 is a schematic structural view of a second ring seat of the present invention;

in the drawings, the components represented by the respective reference numerals are listed below:

1. a housing; 2. a base; 3. a cover body; 4. a compressor body; 401. deep grooves; 5. a first fixing mechanism; 6. a heat conducting portion; 601. a heat exchange plate; 6011. a protrusion; 602. a first ring seat; 6021. a first clapboard; 6022. a water inlet head I; 6023. a first water outlet head; 603. a second ring seat; 6031. a second clapboard; 6032. a water inlet head II; 6033. a water outlet head II; 605. a pipe body; 6051. a threaded rod; 606. a sliding seat; 607. an arc-shaped plate; 7. a pipeline; 8. a water tank; 9. a heat exchange pipe; 10. a water pump; 11. a spray head; 12. and a second fixing mechanism.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments. The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Referring to fig. 1-11, the present invention is a controlled compressor energy-saving operation system, including a casing 1, a base 2 disposed in the casing 1, a cover 3 mounted on the base 2, a compressor body 4 mounted on the base 2, the compressor body 4 being fixed by a first fixing mechanism 5 and a second fixing mechanism 12 mounted on an inner wall of the casing 1, a plurality of deep grooves 401 disposed on an outer side surface of the compressor body 4, a heat conducting portion 6 mounted on an outer side of the deep grooves 401, the heat conducting portion 6 being communicated with a heat exchanging pipe 9 mounted in a water tank 8 through a pipe 7, a water pump 10 further mounted in the water tank 8, the water pump 10 being communicated with a nozzle 11 disposed on an outer side of the water tank 8, the heat conducting portion 6 including a heat exchanging plate 601, a first ring seat 602 and a second ring seat 603, a plurality of heat exchanging plates 601 mounted on an outer side of the deep grooves 401, the plurality of heat exchanging plates 601 being distributed in a ring shape, two ends of the plurality of heat exchanging plates 601 being respectively communicated with the first ring seat 602 and the second ring seat 603, the heat exchange plate 601, the first ring seat 602 and the second ring seat 603 form a plurality of water flow loops, and water inlet and outlet parts are mounted on the first ring seat 602 and the second ring seat 603.

The heat conducting part 6 and the heat exchange pipe 9 form a heat exchange assembly, water in the heat conducting part 6 flows in a circulating mode through the pipeline 7 and the water in the heat exchange pipe 9, the temperature of the water in the water tank 8 is increased through the water subjected to heat exchange in the heat conducting part 6, the water subjected to temperature rise can be sprayed out from the spray head 11 under the action of the water pump 10, heat generated by the compressor body 4 can be recovered, resources are effectively utilized, and therefore the energy-saving effect is achieved.

The heat transfer board 601 main part is curved plate, the concave surface of heat transfer board 601 seted up with deep trouth 401 complex protruding 6011, install body 605 between protruding 6011's the two pairs of both sides face, the both ends of body 605 all communicate with deep trouth 401, protruding 6011's length is less than deep trouth 401's length.

Install seal assembly in body 605, seal assembly includes sliding seat 606 and arc 607, and open the tip of arc 607 has logical groove, and sliding seat 606 cup joints on body 605, and the internal thread that sliding seat 606 was equipped with and the external screw thread intermeshing that body 605 was equipped with, and the both ends of sliding seat 606 are equipped with the gliding sliding plate in logical groove of arc 607, and the arc 607 of installation can drive the arc 607 and remove.

The water that is equipped with gets into deep groove 401 through ring seat one 602 or ring seat two 603 in the in-process that flows to the opposite side of deep groove 401 through installation body 605 flow direction, next time discharges through ring seat two 603 or ring seat one 602, realizes the circulation flow through inside the heat exchange tube 9 of intercommunication, and the body 605 that is equipped with is located deep groove 401, accomplishes and takes away the heat in deep groove 401.

The first annular channel 602 is internally provided with a first annular channel, the first annular channel is internally provided with two partition plates 6021 which are distributed along the vertical direction, the outer side of the first partition plate 6021 is provided with a first water inlet head 6022 or a first water outlet head 6023, and the first water inlet head 6022 or the first water outlet head 6023 is communicated with the first annular channels at the two sides of the first partition plate 6021.

The second annular seat 603 is internally provided with a second annular channel, the second annular channel is internally provided with two partition plates 6031 distributed along the vertical direction, the outer sides of the second partition plates 6031 are provided with a second water inlet head 6032 or a second water outlet head 6033, and the second water inlet head 6032 or the second water outlet head 6033 are communicated with the first annular channels on the two sides of the second partition plates 6031.

The first ring seat 602 and the second ring seat 603 are both communicated with the deep groove 401.

One-way valves are arranged in the water inlet head 6022, the water outlet head 6023, the water inlet head II 6032 and the water outlet head II 6033.

Four heat exchange plates 601 are arranged between the first ring seat 602 and the second ring seat 603, two arc-shaped plates 607 are arranged in each heat exchange plate 601, and when the arc-shaped plate 607 on one side extends out of the cavity of the heat exchange plate 601, the arc-shaped plate 607 on the other side is positioned in the cavity of the heat exchange plate 601.

If the ends of the two arc-shaped plates 607 at the upper side extend into the first ring seat 602, the ends of the two arc-shaped plates 607 at the lower side extend into the second ring seat 603, and if the ends of the two arc-shaped plates 607 at the lower side extend into the first ring seat 602, the ends of the two arc-shaped plates 607 at the upper side extend into the second ring seat 603.

If the ends of the two arc-shaped plates 607 at the upper side extend into the first ring seat 602 and the ends of the two arc-shaped plates 607 at the lower side extend into the second ring seat 603, the arc-shaped plates 607 are arranged to seal the water outlet of the first water inlet 6022, water inside the heat exchange tube 9 enters the second water inlet 6032 through the water inlet pipeline in the pipeline 7, the check valve in the second water inlet 6032 is pushed to open, the entered water enters the deep groove 401 through the second ring seat 603 and flows to the other side of the deep groove 401 through the tube body 605 to enter the first ring seat 602, the water enters the second ring seat 603 through the tube body 605 at the lower side, the check valve in the second water outlet 6033 is pushed to open to realize water drainage, and the water enters the heat exchange tube 9 through the water outlet pipeline in the pipeline 7 to finish heating the water inside the water tank;

when water flows to the first ring seat 602 through the second ring seat 603 and also flows through the pipe body 605 on the upper side, because the threaded rod 6051 is arranged in the pipe body 605, the water flowing through the threaded rod 6051 pushes the pipe body 605 to rotate, the rotating pipe body 605 pushes the sliding seat 606 to move to one side of the second ring seat 603 until the sliding seat 606 drives the arc-shaped plate 607 to seal the water outlet of the first water inlet head 6022, and the pipe body 605 on the lower side pushes the corresponding sliding seat 606 to drive the arc-shaped plate 607 to move to the second ring seat 603, so that water is fed through the first water inlet head 6022 and is discharged through the first water outlet head 6023;

through the flow direction that changes the inside rivers of different bodys 605, be convenient for realize all can through microthermal rivers through different regional, be convenient for carry out even heat dissipation to the week survey of compressor body 4.

The working principle is as follows:

the heat conducting part 6 and the heat exchange pipe 9 form a heat exchange assembly, water in the heat conducting part 6 circularly flows with water in the heat exchange pipe 9 through the pipeline 7, the temperature of the water in the water tank 8 is raised through the water subjected to heat exchange in the heat conducting part 6, the water subjected to temperature rise can be sprayed out from the spray head 11 under the action of the water pump 10, heat generated by the compressor body 4 can be recovered, resources are effectively utilized, and therefore the energy-saving effect is achieved;

It is to be understood that the described embodiments are merely a few embodiments of the invention, and not all embodiments. All other embodiments, which can be derived by one of ordinary skill in the art and related arts based on the embodiments of the present invention without any creative effort, shall fall within the protection scope of the present invention. Structures, devices, and methods of operation not specifically described or illustrated herein are generally practiced in the art without specific recitation or limitation.

Claims

1. The utility model provides a compressor energy-conserving operating system of control, includes casing (1), be equipped with base (2) in casing (1), install compressor body (4) on base (2), compressor body (4) are fixed its characterized in that through casing (1) interior wall mounting's fixed establishment one (5) and fixed establishment two (12):

the compressor comprises a compressor body (4), and is characterized in that a plurality of deep grooves (401) are formed in the outer side surface of the compressor body (4), heat conducting parts (6) are mounted on the outer sides of the deep grooves (401), the heat conducting parts (6) are communicated with heat exchange tubes (9) mounted in a water tank (8) through pipelines (7), a water pump (10) is further mounted in the water tank (8), and the water pump (10) is communicated with a spray head (11) arranged on the outer side of the water tank (8);

the heat conducting part (6) comprises a heat exchange plate (601), a first ring seat (602) and a second ring seat (603), a plurality of heat exchange plates (601) are mounted on the outer side of the deep groove (401), the plurality of heat exchange plates (601) are distributed annularly, two ends of the plurality of heat exchange plates (601) are respectively communicated with the first ring seat (602) and the second ring seat (603), and the heat exchange plates (601), the first ring seat (602) and the second ring seat (603) form a plurality of water flow loops;

and water inlet and outlet parts are respectively arranged on the first ring seat (602) and the second ring seat (603).

2. The system for controlling the compressor to run in an energy-saving mode according to claim 1, wherein the main body of the heat exchange plate (601) is a curved plate, and a concave surface of the heat exchange plate (601) is provided with a protrusion (6011) matched with the deep groove (401);

a pipe body (605) is arranged between two pairs of two side faces of the protrusion (6011), two ends of the pipe body (605) are communicated with the deep groove (401), and the length of the protrusion (6011) is smaller than that of the deep groove (401).

3. A controlled compressor economized running system according to claim 2, characterized in that inside said tubular body (605) is mounted a sealing assembly;

the sealing assembly comprises a sliding seat (606) and an arc-shaped plate (607), a through groove is formed in the end portion of the arc-shaped plate (607), the sliding seat (606) is sleeved on the pipe body (605), internal threads arranged on the sliding seat (606) are meshed with external threads arranged on the pipe body (605), sliding plates sliding in the through groove of the arc-shaped plate (607) are arranged at the two ends of the sliding seat (606), and the installed arc-shaped plate (607) can drive the arc-shaped plate (607) to move.

4. A controlled compressor energy-saving operation system according to claim 3, wherein a first annular channel is arranged in the first annular seat (602), two first partition plates (6021) are arranged in the first annular channel, the first partition plates (6021) are distributed along the vertical direction, a first water inlet head (6022) or a first water outlet head (6023) is arranged on the outer side of the first partition plates (6021), and the first water inlet head (6022) or the first water outlet head (6023) is communicated with the first annular channels on the two sides of the first partition plates (6021).

5. The controlled energy-saving operation system of the compressor according to claim 4, wherein a second annular channel is arranged in the second annular seat (603), two partition plates (6031) distributed in the vertical direction are arranged in the second annular channel, a second water inlet head (6032) or a second water outlet head (6033) is arranged on the outer side of the second partition plate (6031), and the second water inlet head (6032) or the second water outlet head (6033) is communicated with the first annular channels on two sides of the second partition plate (6031).

6. A controlled compressor economized operation system according to claim 5, characterized in that said ring seat one (602) and said ring seat two (603) are both in communication with the deep groove (401).

7. A controlled compressor run-saving system as claimed in claim 5, wherein the water inlet head one (6022), the water outlet head one (6023), the water inlet head two (6032) and the water outlet head two (6033) are all provided with one-way valves.

8. A controlled compressor energy-saving operation system according to claim 1, wherein four heat exchange plates (601) are installed between the first ring seat (602) and the second ring seat (603), two arc-shaped plates (607) are installed in each heat exchange plate (601), when the arc-shaped plate (607) on one side extends out of the cavity of the heat exchange plate (601), the arc-shaped plate (607) on the other side is located in the cavity of the heat exchange plate (601).

9. A controlled compressor economized running system according to claim 8, characterized in that the ends of two said arc plates (607) at the upper side are extended into the first ring seat (602), and the ends of two said arc plates (607) at the lower side are extended into the second ring seat (603).