The present disclosure relates to the technical field of compressors, and in particular, to a compressor with an oil equalizing pipe, a parallel compressor set, and an oil equalizing method.
A compressor is a fluid machine that lifts a low-pressure gas into a high-pressure gas, and is the heart of a refrigeration system. The compressors connected in parallel in the refrigeration systems bring the advantages that it is convenient to adjust capacity, easy to maintain by single machine shutdown, low in cost and the like, and thus are widely used. Due to manufacturing differences of compressors, or different states of running or shutdown of different compressors, the distribution of oil output or oil return of the compressors is uneven, in this way, the oil masses of some compressors are increased and the oil masses of the other compressors are decreased after running, the compressors with too small oil masses may be damaged due to insufficient lubrication, so an oil balance design should be performed when the compressors are connected in parallel.
At present, the common practice for oil balance is to use an oil balance pipe to connect the oil sumps of two compressors. Although this method can play a role in oil balance to certain extent, it is easy to cause oil transfer between the two compressors due to the pressure difference between the compressors, resulting in imbalanced oil levels.
In order to overcome the above-mentioned shortcomings in the prior art, the objective of the present disclosure is to provide a compressor with an oil equalizing pipe, a parallel compressor set, and an oil equalizing method.
In order to achieve the above objective, the technical solution adopted by the present disclosure to solve its technical problem is as follows: a compressor with an oil equalizing pipe includes a compressor body, the compressor body is provided with a suction port and an exhaust port, an oil sump is disposed at the bottom of the compressor body, the compressor further includes at least one oil equalizing pipe, an opening at one end of the oil equalizing pipe is formed in a target oil level of the oil sump, and the opening at the other end of the oil equalizing pipe is formed in the suction port; and when the oil level of the oil sump of the compressor is higher than the target oil level, the extra oil enters the suction port through the oil equalizing pipe.
Compared with the prior art, the present disclosure has the advantages that, when the compressor is running, the gas in the suction port flows, so that the pressure at the suction port is less than the pressure on the surface of the oil sump, when the oil level of the oil sump of the compressor is higher than the target oil level, the extra oil enters the suction port through the oil equalizing pipe under the action of the above pressure difference, a part of the oil enters vortex and is discharged from the compressor via the exhaust port, and the oil discharged from the compressor returns to the other compressor lack of oil through a pipeline, thereby achieving the oil balance between different compressors.
Further, the oil equalizing pipe is disposed in a compressor body shell.
By adopting the above preferred solution, it is conducive to avoiding the risk that the oil equalizing pipe is damaged by the collision of foreign objects, and the joints between the oil equalizing pipe and other parts are all located in the compressor body shell, thereby avoiding the risk of oil leakage.
Further, the middle pipe body part of the oil equalizing pipe is disposed on an outer side of the compressor body shell.
By adopting the above preferred solution, it is conducive to saving the space in the compressor, and avoiding cost increase resulted from the size increase of the compressor, and the welding between the oil equalizing pipe and a suction pipe can be performed after the compressor is manufactured, so the operation is easy.
Further, the oil equalizing pipe is provided with a bent part at the end of the suction port, and the axis of the pipe body of the bent part is parallel to the airflow direction at the suction port.
By adopting the above preferred solution, the outlet direction of the oil equalizing pipe is along the suction airflow direction, so that the extra oil can be brought into the vortex by the negative pressure of the airflow more easily, so as to be discharged from the compressor via the exhaust port.
Further, an ultrasonic atomizer is disposed on the periphery of the pipe body of the oil equalizing pipe near the suction port.
By adopting the above preferred solution, the oil sucked out by the oil equalizing pipe can be atomized, thereby making it easier for the oil to enter the vortex to be discharged from the exhaust port.
A parallel compressor set includes at least two compressors with oil equalizing pipes as described above, the suction port of each compressor is connected with a main suction port through a suction branch pipeline, the exhaust port of each compressor is connected to an air inlet of an oil-gas separator through an exhaust branch pipeline, then an air outlet of each oil-gas separator is connected to a main exhaust port, and an oil outlet of each oil-gas separator is divided into a plurality of oil return circuits communicating with the suction branch pipelines respectively.
By adopting the above preferred solution, when the compressor is running, the gas in the suction port flows, so that the pressure at the suction port is less than the pressure on the surface of the oil sump, when the oil level of the oil sump of the compressor is higher than the target oil level, the extra oil enters the suction port through the oil equalizing pipe under the action of the above pressure difference, a part of the oil enters vortex and is discharged from the compressor via the exhaust port, a part of the oil discharged from the compressor returns to the other compressor lack of oil through the oil-gas separator, no oil is sucked from the oil sump into the suction port from the oil equalizing pipe of the compressor lack of oil, so that the oil discharged from the exhaust port of the compressor lack of oil is very little, that is, the oil mass discharged from the compressor with extra oil is greater than the oil mass discharged from the compressor lack of oil, and the oil balance between different compressors is realized after multiple circles; and the oil-gas separator is also provided with an oil return circuit that communicates with the suction branch pipeline of its corresponding compressor for ensuring the lubrication requirements of internal parts.
Further, a flowmeter is connected in series to the oil equalizing pipe of each compressor, and a proportional flow control valve is disposed on an oil return circuit at the oil outlet of each oil-gas separator, which communicates with the suction branch pipeline of the paired compressor; the parallel compressor set further includes a controller, which controls the output quantity of the corresponding proportional flow control valve according to the flow data of the flowmeter corresponding to each compressor.
By adopting the above preferred solution, the mass of return oil can be optimized and controlled according to the flow of the oil equalizing pipe, and the oil balance can be achieved more quickly.
Further, the output quantity of the proportional flow valve corresponding to the kth compressor satisfies the following relationship: when the flow Vk of the oil equalizing pipe of the kth compressor is greater than an average value of the flow of all oil equalizing pipes, the output quantity Pk of the proportional flow valve corresponding to the kth compressor is set as the minimum flow Vmin of the flow of all oil equalizing pipes; and when the flow Vk of the oil equalizing pipe of the kth compressor is less than or equal to the average value of the flow of all oil equalizing pipes, the output quantity Pk of the proportional flow valve corresponding to the kth compressor is set as the average value of the flow of all oil equalizing pipes.
By adopting the above preferred solution, the oil return ratio of each oil circuit is further optimized, so that the oil balance and the oil lubrication of the compressors achieve an optimal state.
An oil equalizing method, for balancing the lubricating oil in oil sumps of compressors connected in parallel, includes the following steps: step 1, disposing an oil equalizing pipe between the oil sump and a suction port of each compressor, wherein an opening at one end of the oil equalizing pipe is formed in a target oil level of the oil sump, and the opening at the other end of the oil equalizing pipe is formed in the suction port; and step 2, connecting the suction port of each compressor with a main suction port through a suction branch pipeline, respectively connecting the exhaust port of each compressor to an air inlet of an oil-gas separator through an exhaust branch pipeline, then connecting an air outlet of each oil-gas separator to a main exhaust port, and dividing an oil outlet of each oil-gas separator into a plurality of oil return circuits communicating with the suction branch pipelines respectively.
By adopting the above preferred solution, when the compressor is running, the gas in the suction port flows, so that the pressure at the suction port is less than the pressure on the surface of the oil sump; when the oil level of the oil sump of the compressor is higher than the target oil level, the extra oil enters the suction port through the oil equalizing pipe under the action of the above pressure difference, a part of the oil enters vortex and is discharged from the compressor via the exhaust port, a part of the oil discharged from the compressor returns to the other compressor lack of oil through the oil-gas separator, no oil is sucked from the oil sump into the suction port from the oil equalizing pipe of the compressor lack of oil, so that the oil discharged from the exhaust port of the compressor lack of oil is very little, that is, the oil mass discharged from the compressor with extra oil is greater than the oil mass discharged from the compressor lack of oil, and the oil balance between different compressors is realized after multiple circles; and the oil-gas separator is also provided with the oil return circuit that communicates with the suction branch pipeline of its corresponding compressor for ensuring the lubrication requirements of internal parts.
Further, the method further includes: step 3. connecting a flowmeter in series to the oil equalizing pipe of each compressor, and disposing a proportional flow control valve on an oil return circuit at the oil outlet of each oil-gas separator, which communicates with the suction branch pipeline of the paired compressor, wherein the output quantity of the proportional flow valve corresponding to the kth compressor satisfies the following relationship: when the flow Vk of the oil equalizing pipe of the kth compressor is greater than an average value of the flow of all oil equalizing pipes, the output quantity Pk of the proportional flow valve corresponding to the kth compressor is set as the minimum flow Vmin of the flow of all oil equalizing pipes; and when the flow Vk of the oil equalizing pipe of the kth compressor is less than or equal to the average value of the flow of all oil equalizing pipes, the output quantity Pk of the proportional flow valve corresponding to the kth compressor is set as the average value of the flow of all oil equalizing pipes.
By adopting the above preferred solution, the oil return ratio of each oil circuit is further optimized, so that the oil balance and the oil lubrication of the compressors achieve an optimal state.
To illustrate technical solutions in the embodiments of the present disclosure or in the prior art more clearly, a brief introduction on the drawings which are needed in the description of the embodiments or the prior art is given below. Apparently, the drawings in the description below are merely some of the embodiments of the present disclosure, based on which other drawings can be obtained by those of ordinary skill in the art without any creative effort.
1
a/1b—compressor; 10—compressor body; 11—suction port; 12—exhaust port; 13—oil sump; 14—oil equalizing pipe; 15—oil spray head; 16—spray head angle adjustment mechanism; 161—first connecting rod; 162—piston rod; 163—second connecting rod; 164—rotating wheel; 165—deceleation driving motor; 141—bent part; 2a/2b—suction branch pipeline; 20—main suction port; 3a/3b—exhaust branch pipeline; 30—main exhaust port; 4a/4b—oil-gas separator; 5a1/5a2/5b1/5b2—oil return circuit; 6a/6b—flowmeter; and 7a/7b—proportional flow control valve.
A clear and complete description of technical solutions in the embodiments of the present disclosure will be given below, in combination with the drawings in the embodiments of the present disclosure. Apparently, the embodiments described below are merely a part, but not all, of the embodiments of the present disclosure. All of other embodiments, obtained by those of ordinary skill in the art based on the embodiments of the present disclosure without any creative effort, fall into the protection scope of the present disclosure.
As shown in
The beneficial effects of adopting the above technical solution are that: when the compressor is running, the gas in the suction port 11 flows, so that the pressure at the suction port 11 is less than the pressure on the surface of the oil sump 13, when the oil level of the oil sump 13 of the compressor is higher than the target oil level, the extra oil enters the suction port 11 through the oil equalizing pipe 14 under the action of the above pressure difference, a part of the oil enters vortex and is discharged from the compressor via the exhaust port 12, and the oil discharged from the compressor returns to the other compressor lack of oil through a pipeline, thereby achieving the oil balance between different compressors.
As shown in
As shown in
In some other embodiments of the present disclosure, the oil equalizing pipe 14 is provided with a bent part 141 at the end of the suction port 11, and the axis of the pipe body of the bent part 141 is parallel to the airflow direction at the suction port 11. The beneficial effects of adopting the above technical solution are that: the outlet direction of the oil equalizing pipe 14 is along the suction airflow direction, so that the extra oil can be brought into the vortex by the negative pressure of the airflow more easily, so as to be discharged from the compressor via the exhaust port.
In some other embodiments of the present disclosure, an ultrasonic atomizer is disposed on the periphery of the pipe body of the oil equalizing pipe near the suction port. The beneficial effects of adopting the above technical solution are that: the oil sucked out by the oil equalizing pipe can be atomized, thereby making it easier for the oil to enter the vortex to be discharged from the exhaust port.
As shown in
As shown in
The beneficial effects of adopting the above technical solution are that: when the compressors 1a/1b are running, the gas in the suction port flows, so that the pressure at the suction port 11 is less than the pressure on the surface of the oil sump 13, when the oil level of the oil sump 13 of the compressor 1a is higher than the target oil level, the extra oil enters the suction port 11 through the oil equalizing pipe 14 under the action of the above pressure difference, a part of the oil enters vortex and is discharged from the compressor 1a via the exhaust port 12, and the oil discharged from the compressor 1a returns to the other compressor 1b lack of oil through the oil-gas separator 4a, no oil is sucked from the oil sump 13 into the suction port 11 from the oil equalizing pipe 14 of the compressor 1b lack of oil, so that the oil discharged from the exhaust port 12 of the compressor 1b lack of oil is very little, that is, the oil mass discharged from the compressor 1a with extra oil is greater than the oil mass discharged from the compressor 1b lack of oil, and the oil balance between the compressors 1a/1b is realized after multiple circles; and the oil-gas separator 4a is also provided with the oil return circuit 5a1 that communicates with the suction branch pipeline 2a of its corresponding compressor 1a for ensuring the lubrication requirements of internal parts.
As shown in
In some other embodiments of the present disclosure, the output quantity of the proportional flow valve corresponding to the kth compressor satisfies the following relationship: when the flow Vk of the oil equalizing pipe of the kth compressor is greater than an average value of the flow of all oil equalizing pipes, the output quantity Pk of the proportional flow valve corresponding to the kth compressor is set as the minimum flow Vmin of the flow of all oil equalizing pipes; and when the flow Vk of the oil equalizing pipe of the kth compressor is less than or equal to the average value of the flow of all oil equalizing pipes, the output quantity Pk of the proportional flow valve corresponding to the kth compressor is set as the average value of the flow of all oil equalizing pipes. The beneficial effects of adopting the above technical solution are that: the oil return ratio of the oil circuits is further optimized, so that the oil balance and the oil lubrication of the compressors achieve an optimal state
An oil equalizing method, for balancing the lubricating oil in oil sumps of compressors connected in parallel, includes the following steps: step 1, disposing an oil equalizing pipe between the oil sump and a suction port of each compressor, wherein an opening at one end of the oil equalizing pipe is formed in a target oil level of the oil sump, and the opening at the other end of the oil equalizing pipe is formed in the suction port; and step 2, connecting the suction port of each compressor with a main suction port through a suction branch pipeline, respectively connecting the exhaust port of each compressor to an air inlet of an oil-gas separator through an exhaust branch pipeline, then connecting an air outlet of each oil-gas separator to a main exhaust port, and dividing an oil outlet of each oil-gas separator into a plurality of oil return circuits communicating with the suction branch pipelines respectively.
The beneficial effects of adopting the above technical solution are that: when the compressor is running, the gas in the suction port flows, so that the pressure at the suction port is less than the pressure on the surface of the oil sump, when the oil level of the oil sump of the compressor is higher than the target oil level, the extra oil enters the suction port through the oil equalizing pipe under the action of the above pressure difference, a part of the oil enters vortex and is discharged from the compressor via the exhaust port, a part of the oil discharged from the compressor returns to the other compressor lack of oil through the oil-gas separator, no oil is sucked from the oil sump into the suction port from the oil equalizing pipe of the compressor lack of oil, so that the oil discharged from the exhaust port of the compressor lack of oil is very little, that is, the oil mass discharged from the compressor with extra oil is greater than the oil mass discharged from the compressor lack of oil, and the oil balance between different compressors is realized after multiple circles; and the oil-gas separator is also provided with the oil return circuit that communicates with the suction branch pipeline of its corresponding compressor for ensuring the lubrication requirements of internal parts. The beneficial effects of adopting the above technical solution are that: the oil return ratio of the oil circuits is further optimized, so that the oil balance and the oil lubrication of the compressors achieve an optimal state.
The above embodiments are only used for explaining the technical concepts and features of the present disclosure, and the purpose thereof is to enable those of ordinary skill in the art to understand and implement the contents of the present disclosure, but the protection scope of the present disclosure is not limited thereto, and equivalent variations or modifications made according to the spirit essence of the present disclosure shall fall within the protection scope of the present disclosure.
Number | Date | Country | Kind |
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201711087801.6 | Nov 2017 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2018/093204 | 6/27/2018 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/091126 | 5/16/2019 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3392916 | Engstrom | Jul 1968 | A |
4383802 | Gianni | May 1983 | A |
5236311 | Lindstrom | Aug 1993 | A |
6941767 | Matsuoka | Sep 2005 | B2 |
9470230 | Koyama | Oct 2016 | B2 |
20110081254 | Hafkemeyer | Apr 2011 | A1 |
20120023978 | Chae | Feb 2012 | A1 |
Number | Date | Country |
---|---|---|
1548767 | Nov 2004 | CN |
201196145 | Feb 2009 | CN |
204494911 | Jul 2015 | CN |
205260257 | May 2016 | CN |
107747544 | Mar 2018 | CN |
207454278 | Jun 2018 | CN |
2003130474 | May 2003 | JP |
2005076515 | Mar 2005 | JP |
2013238142 | Nov 2013 | JP |
Entry |
---|
International Search Report of PCT/CN2018/093204, dated Sep. 30, 2018, 8 pages. |
Number | Date | Country | |
---|---|---|---|
20200232687 A1 | Jul 2020 | US |