CN218077104U - Gas-liquid separation device for air compressor - Google Patents

Abstract

A gas-liquid separation device for an air compressor comprises a bottom support frame, a separation box body, a gas inlet pipeline, an exhaust pipeline, a liquid discharge pipeline and a multiple separation mechanism; the gas entering the gas-liquid separator is firstly dispersed by the longitudinally-arranged annular mesh enclosure and the annular baffles around the longitudinally-arranged annular mesh enclosure and simultaneously liquid is separated, and then the gas is dispersed by the transversely-arranged annular mesh enclosure and the annular baffles around the transversely-arranged annular mesh enclosure and simultaneously liquid is separated in the upward conveying process of the gas, so that multiple dispersing effects are achieved, and the gas and liquid dispersing effect is improved.

Description

Gas-liquid separation device for air compressor

Technical Field

The utility model relates to a gas-liquid separation device for air compressor machine.

Background

At present, compressed air discharged by an air compressor can be conveyed for use through a pipeline after being cooled and separated, but the compressed air which is just cooled needs to be conveyed by a long-distance pipeline sometimes, in the process, the generation of mechanical carrying condensed water is inevitable, and when equipment uses the compressed air, the equipment needs to dry the compressed air, and gas and liquid are separated by using a gas-liquid separator; the existing compressed air gas and liquid separation device has poor separation effect and low separation efficiency.

Disclosure of Invention

To the weak point of above-mentioned prior art, the utility model provides a problem do: the gas-liquid separation device for the air compressor has a good separation effect.

In order to solve the problem, the utility model discloses the technical scheme who takes as follows:

a gas-liquid separation device for an air compressor comprises a bottom support frame, a separation box body, a gas inlet pipeline, an exhaust pipeline, a liquid discharge pipeline and a multiple separation mechanism; two sides of the bottom of the separation box body are respectively provided with a bottom support frame; an exhaust pipeline is arranged in the middle of the upper end of the separation box body, an air inlet pipeline is arranged in the middle of one side of the separation box body, and a liquid discharge pipeline is arranged below the inner part of the separation box body; the multiple separation mechanism is arranged inside the separation box body; the multiple separation mechanism comprises a vertical annular mesh enclosure, a transverse annular mesh enclosure, an annular baffle and a driving motor; the longitudinal annular mesh enclosure is arranged in the middle of the inside of the separation box body, and the inner end of the air inlet pipeline is over against the side part of the longitudinal annular mesh enclosure; the transverse annular mesh enclosure is arranged above the inside of the separation box body, and the lower end of the exhaust pipeline is opposite to the upper side surface of the transverse annular mesh enclosure; a plurality of annular baffles are uniformly arranged on the outer sides of the peripheries of the longitudinal annular mesh enclosure and the transverse annular mesh enclosure; the annular baffles are in conical structures, the annular baffles are sequentially stacked on the outer sides of the peripheries of the longitudinal annular mesh enclosure and the transverse annular mesh enclosure, and an annular gap is reserved between the annular baffles; the driving motor is installed on one side of the outer portion of the separation box body and drives the longitudinal annular mesh enclosure and the transverse annular mesh enclosure to rotate synchronously.

Further, the device also comprises a cooperative driving component; the driving motor drives the longitudinal annular mesh enclosure and the transverse annular mesh enclosure to rotate through the cooperative driving assembly; the cooperative driving assembly comprises a connecting rod, a driving worm, a driven worm wheel, a middle transmission column, a bottom rotating column, a bottom gear, a supporting plate and a transmission chain; connecting rods are respectively arranged in the middles of two ends of the transverse annular mesh enclosure, a driving worm is arranged outside the middle of the connecting rod at one end of the transverse annular mesh enclosure, the outer end of the driving worm is rotationally clamped on the inner wall of the separation box body, and a driving motor extends into the separation box body through a rotating shaft and is connected to the middle of the connecting rod at the other end of the transverse annular mesh enclosure; one side of the driving worm is meshed with a driven worm wheel, and the middle of the driven worm wheel is connected with a fixed middle transmission column in a penetrating manner; a supporting plate is arranged below one side inside the separation box body; the lower end of the middle transmission column is provided with a bottom rotating column; a connecting rod is arranged in the middle of the bottom of the longitudinally-arranged annular net cover, and a bottom rotating column is arranged at the lower end of the middle of the connecting rod; the bottom rotating columns are respectively and rotationally clamped on the upper end surfaces of the supporting plates; and bottom gears are respectively arranged on the bottom rotating columns and are connected through a transmission chain.

Further, a rotary positioning rod is arranged at the outer end of the driving worm; a rotary clamping groove is formed in the inner wall of one side of the separation box body; the rotary positioning rod is rotatably clamped on the rotary clamping groove.

Furthermore, a positioning plate is arranged on one side above the inside of the separation box body; a clamping column is arranged on the outer side of the middle of the connecting rod at the other end of the transverse annular mesh enclosure; the clamping column is rotationally clamped on one side of the positioning plate; the inner of driving motor's pivot is equipped with the extension rod, and the extension rod passes the locating plate and with joint column connection.

Further, an opening and closing valve is arranged on the liquid discharge pipeline; an annular cone is arranged below the separating box body; the periphery of the upper end of the annular cone is connected with the peripheral inner side wall of the separation box body, and the periphery of the lower end of the annular cone is connected with the periphery of the upper end of the liquid discharge pipeline.

Furthermore, the annular cone is of a conical ring structure with a large upper part and a small lower part.

The utility model has the advantages as follows:

1. the gas entering the gas-liquid separator is firstly dispersed and simultaneously separated from the liquid through the longitudinally-arranged annular mesh enclosure and the annular baffles around the longitudinally-arranged annular mesh enclosure, and then the gas is upwards conveyed and is dispersed and simultaneously separated from the liquid through the transversely-arranged annular mesh enclosure and the annular baffles around the transversely-arranged annular mesh enclosure, so that multiple dispersing effects are achieved, and the dispersing effect of the gas and the liquid is improved.

2. The invention can drive the longitudinal annular mesh enclosure and the transverse annular mesh enclosure to synchronously rotate through a driving motor, a driving worm is arranged outside the middle of a connecting rod at one end of the transverse annular mesh enclosure, one side of the driving worm is connected with a driven worm wheel in an occluded manner, a middle transmission column is fixedly connected in the middle of the driven worm wheel in a penetrating manner, the lower end of the middle transmission column and the lower end of the longitudinal annular mesh enclosure are rotatably clamped on the upper end surface of the supporting plate, and the lower end of the middle transmission column and the lower end of the longitudinal annular mesh enclosure are transmitted through a bottom gear and a transmission chain, so that synchronous driving is realized.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural view of the horizontal annular mesh enclosure of the present invention.

Fig. 3 is a schematic structural view of the vertically disposed annular mesh enclosure of the present invention.

Fig. 4 is a schematic side view of the driving worm, the driven worm wheel and the intermediate transmission column of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1 to 4, a gas-liquid separation device for an air compressor comprises a bottom support frame 2, a separation box body 1, a gas inlet pipeline 3, an exhaust pipeline 4, a liquid discharge pipeline 5 and a multiple separation mechanism 6; two sides of the bottom of the separation box body 1 are respectively provided with a bottom support frame 2; an exhaust pipeline 4 is arranged in the middle of the upper end of the separation box body 1, an air inlet pipeline 3 is arranged in the middle of one side of the separation box body 1, and a liquid drainage pipeline 5 is arranged below the inner part of the separation box body 1; the multiple separation mechanism 6 is arranged inside the separation box body 1; the multiple separation mechanism 6 comprises a vertical annular mesh enclosure 61, a horizontal annular mesh enclosure 62, an annular baffle 64 and a driving motor 63; the longitudinally-arranged annular mesh enclosure 61 is arranged in the middle of the inside of the separation box body 1, and the inner end of the air inlet pipeline 3 is over against the side part of the longitudinally-arranged annular mesh enclosure 61; the transverse annular mesh enclosure 62 is arranged above the inside of the separation box body 1, and the lower end of the exhaust pipeline 4 is over against the upper side surface of the transverse annular mesh enclosure 62; a plurality of annular baffles 64 are uniformly arranged on the outer sides of the peripheries of the vertical annular mesh enclosure 61 and the horizontal annular mesh enclosure 62; the annular baffles 64 are in a conical structure, the annular baffles 64 are sequentially stacked on the outer sides of the peripheries of the vertical annular mesh enclosure 61 and the horizontal annular mesh enclosure 62, and an annular gap is reserved between the annular baffles 64; the driving motor 63 is installed at one side of the outside of the separation box body 1, and the driving motor 63 drives the vertical annular mesh enclosure 61 and the horizontal annular mesh enclosure 62 to synchronously rotate.

As shown in fig. 1 to 4, in order to realize synchronous driving of the vertical annular mesh enclosure 61 and the horizontal annular mesh enclosure 62, a cooperative driving assembly 7 is further included; the driving motor 73 drives the longitudinal annular mesh enclosure 61 and the transverse annular mesh enclosure 62 to rotate through the cooperative driving component 7; the cooperative driving assembly 7 comprises a connecting rod 71, a driving worm 72, a driven worm wheel 73, an intermediate transmission column 74, a bottom rotating column 75, a bottom gear 76, a supporting plate 79 and a transmission chain 77; the middle parts of two ends of the transverse annular mesh enclosure 62 are respectively provided with a connecting rod 71, the outer side of the middle part of the connecting rod 71 at one end of the transverse annular mesh enclosure 62 is provided with a driving worm 72, the outer end of the driving worm 72 is rotationally clamped on the inner wall of the separation box body 2, and the driving motor 63 extends into the separation box body 1 through a rotating shaft 631 and is connected to the middle part of the connecting rod 71 at the other end of the transverse annular mesh enclosure 62; one side of the driving worm 72 is meshed with a driven worm wheel 73, and the middle of the driven worm wheel 73 is connected with a fixed middle transmission column 74 in a penetrating way; a supporting plate 79 is arranged below one side of the interior of the separation box body 1; the lower end of the middle transmission post 74 is provided with a bottom rotating post 79; a connecting rod 71 is arranged in the middle of the bottom of the vertically-arranged annular mesh enclosure 61, and a bottom rotating column 75 is arranged at the lower end of the middle of the connecting rod 71; the bottom rotating columns 75 are respectively and rotationally clamped on the upper end faces of the supporting plates 79; the bottom rotating columns 75 are respectively provided with bottom gears 76, and the bottom gears 76 are connected through a transmission chain 77.

As shown in fig. 1 to 4, further, the outer end of the driving worm 72 is provided with a rotation positioning rod 721; a rotary clamping groove 21 is formed in the inner wall of one side of the separation box body 1; the rotation positioning rod 721 is rotatably clamped on the rotation clamping groove 21. Further, a positioning plate 22 is arranged on one side above the inside of the separation box body 1; a clamping column 711 is arranged on the outer side of the middle of the connecting rod 71 at the other end of the transverse annular mesh enclosure 62; the clamping column 711 is rotatably clamped on one side of the positioning plate 22; an extension rod 632 is arranged at the inner end of the rotating shaft 631 of the driving motor 63, and the extension rod 632 penetrates through the positioning plate 22 and is connected with the clamping column 711. Further, an on-off valve 51 is arranged on the liquid discharge pipeline 5; an annular cone 52 is arranged below the separating box body 1; the periphery of the upper end of the annular cone 52 is connected with the peripheral inner side wall of the separation box body 1, and the periphery of the lower end of the annular cone 52 is connected with the periphery of the upper end of the liquid discharge pipeline 5. Further, the ring cone 52 is a tapered ring structure with a large top and a small bottom.

The gas entering the gas-liquid separator is firstly dispersed and simultaneously separated from the liquid through the longitudinally-arranged annular mesh enclosure 61 and the annular baffles 64 around the longitudinally-arranged annular mesh enclosure, and then the gas is upwards conveyed and is dispersed and simultaneously separated from the liquid through the transversely-arranged annular mesh enclosure 62 and the annular baffles 64 around the transversely-arranged annular mesh enclosure, so that multiple dispersing effects are achieved, and the gas and liquid dispersing effect is improved.

The invention can drive the longitudinal annular mesh enclosure 61 and the transverse annular mesh enclosure 62 to synchronously rotate through a driving motor 63, a driving worm 72 is arranged outside the middle of a connecting rod 71 at one end of the transverse annular mesh enclosure 62, one side of the driving worm 72 is connected with a driven worm gear 73 in an engaged manner, a middle transmission column 74 is fixedly connected in the middle of the driven worm gear 73 in a penetrating manner, the lower end of the middle transmission column 74 and the lower end of the longitudinal annular mesh enclosure 61 are rotatably clamped on the upper end surface of a supporting plate 79, and the lower end of the middle transmission column 74 and the lower end of the longitudinal annular mesh enclosure 61 are transmitted through a bottom gear 76 and a transmission chain 77, so that synchronous driving is realized.

The above description is only for the preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. A gas-liquid separation device for an air compressor is characterized by comprising a bottom support frame, a separation box body, a gas inlet pipeline, an exhaust pipeline, a liquid discharge pipeline and a multiple separation mechanism; two sides of the bottom of the separation box body are respectively provided with a bottom support frame; an exhaust pipeline is arranged in the middle of the upper end of the separation box body, an air inlet pipeline is arranged in the middle of one side of the separation box body, and a liquid discharge pipeline is arranged below the inner part of the separation box body; the multiple separation mechanism is arranged inside the separation box body; the multiple separation mechanism comprises a vertical annular mesh enclosure, a transverse annular mesh enclosure, an annular baffle and a driving motor; the longitudinal annular mesh enclosure is arranged in the middle of the inside of the separation box body, and the inner end of the air inlet pipeline is over against the side part of the longitudinal annular mesh enclosure; the transverse annular mesh enclosure is arranged above the inside of the separation box body, and the lower end of the exhaust pipeline is opposite to the upper side surface of the transverse annular mesh enclosure; a plurality of annular baffles are uniformly arranged on the outer sides of the peripheries of the longitudinal annular mesh enclosure and the transverse annular mesh enclosure; the annular baffles are all in a conical structure, the annular baffles are sequentially stacked on the outer sides of the peripheries of the longitudinally-arranged annular mesh enclosure and the transversely-arranged annular mesh enclosure, and an annular gap is reserved between the annular baffles; the driving motor is arranged on one side of the outer portion of the separation box body and drives the longitudinally-arranged annular mesh enclosure and the transversely-arranged annular mesh enclosure to rotate synchronously.

2. The gas-liquid separation device for the air compressor according to claim 1, further comprising a cooperative drive assembly; the driving motor drives the longitudinal annular mesh enclosure and the transverse annular mesh enclosure to rotate through the cooperative driving component; the cooperative driving assembly comprises a connecting rod, a driving worm, a driven worm wheel, a middle transmission column, a bottom rotating column, a bottom gear, a supporting plate and a transmission chain; connecting rods are respectively arranged in the middles of two ends of the transverse annular mesh enclosure, a driving worm is arranged outside the middle of the connecting rod at one end of the transverse annular mesh enclosure, the outer end of the driving worm is rotationally clamped on the inner wall of the separation box body, and a driving motor extends into the separation box body through a rotating shaft and is connected to the middle of the connecting rod at the other end of the transverse annular mesh enclosure; one side of the driving worm is meshed with a driven worm wheel, and the middle of the driven worm wheel is connected with a fixed middle transmission column in a penetrating manner; a supporting plate is arranged below one side inside the separation box body; the lower end of the middle transmission column is provided with a bottom rotating column; a connecting rod is arranged in the middle of the bottom of the longitudinally-arranged annular net cover, and a bottom rotating column is arranged at the lower end of the middle of the connecting rod; the bottom rotating columns are respectively and rotationally clamped on the upper end surfaces of the supporting plates; and bottom gears are respectively arranged on the bottom rotating columns and are connected through a transmission chain.

3. The gas-liquid separation device for the air compressor as claimed in claim 2, wherein a rotation positioning rod is provided at an outer end of the driving worm; a rotary clamping groove is formed in the inner wall of one side of the separation box body; the rotating positioning rod is rotatably clamped on the rotating clamping groove.

4. The gas-liquid separation device for the air compressor as claimed in claim 2, wherein a positioning plate is provided at an upper side inside the separation case; a clamping column is arranged on the outer side of the middle of the connecting rod at the other end of the transverse annular mesh enclosure; the clamping column is rotationally clamped on one side of the positioning plate; the inner of driving motor's pivot is equipped with the extension rod, and the extension rod passes the locating plate and with joint column connection.

5. The gas-liquid separation device for the air compressor according to claim 1, wherein an on-off valve is provided on the liquid discharge pipe; an annular cone is arranged below the separating box body; the upper end of the annular cone is connected with the peripheral inner side wall of the separation box body, and the lower end of the annular cone is connected with the upper end of the liquid discharge pipeline.

6. The gas-liquid separation device for the air compressor as claimed in claim 5, wherein the annular cone has a tapered ring structure with a large upper part and a small lower part.

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