CN215805032U - Air compressor machine waste heat recovery mechanism for ceramic machining - Google Patents

Abstract

The utility model provides a waste heat recovery mechanism of an air compressor for ceramic processing, which comprises a main body, an air inlet pipe, a first cavity, a second cavity and a third cavity, wherein the air inlet pipe is fixedly connected to the outer end of the main body, the first cavity, the second cavity and the third cavity are fixedly arranged in the main body, cooling water is injected into the first cavity and the second cavity, a separation device is embedded in the first cavity, and a partition plate is fixedly connected in the separation device. The separation device is internally provided with a partition plate, the separation device is internally separated into two sections of chambers, an interface between the air inlet pipe and the separation device is arranged below the partition plate, along with the fact that external oil gas enters the separation device, gas and liquid between oil gas substances are simultaneously subjected to separation treatment, the liquid is concentrated in the bottom chamber of the separation device, the gas rises and is filtered and concentrated in the top chamber of the separation device through the partition plate, and the separated oil gas substances are conveyed and treated through the first conduction pipe and the second conduction pipe.

Description

Air compressor machine waste heat recovery mechanism for ceramic machining

Technical Field

The utility model relates to the technical field of air compressors, in particular to an air compressor waste heat recovery mechanism for ceramic processing.

Background

The air compressor is generally an air compressor, which is a device for compressing air, and is similar to a water pump in structure, and is roughly divided into a reciprocating piston type air compressor, a rotary blade or a rotary screw and a centrifugal type air compressor; in the air compressor machine use, the air compressor machine body can produce a large amount of high temperature high pressure oil-gas mixture, can waste a large amount of heat energy, leads to the energy comprehensive utilization low.

To above-mentioned problem, application number is 202020444743.9's utility model, a press waste heat recovery device is proposed, through inside first oil gas filter and the second oil gas filter of an oil-gas separation section of thick bamboo, carry out the separation processing with oil gas, carry the gas of separation through the air duct, thereby accomplish the heat conversion in the gas, store the liquid of separation through the batch oil tank, carry out the heat conversion with cold water simultaneously, thereby carry out abundant recycle, the effectual comprehensive utilization who improves the energy to the air press waste heat.

Above-mentioned device is in the in-service use, when the oil gas separation section of thick bamboo separates oil gas, oil gas that can not be quick separates, lead to the heat conversion among gas and the liquid thoroughly inadequately, and air duct structure setting and position among the above-mentioned device distribute, lead to gaseous when the air duct, the heat can not outwards be changed through the air duct completely, the device is simultaneously to the heat conversion of liquid only outwards derive through the batch oil tank with cold water contact, there is the not thorough problem of heat conversion equally, therefore, need a new air compressor machine waste heat recovery mechanism for ceramic machining.

SUMMERY OF THE UTILITY MODEL

The purpose of the air compressor waste heat recovery mechanism for ceramic processing in the embodiment is achieved by the following specific technical means:

a waste heat recovery mechanism of an air compressor for ceramic processing comprises a main body, an air inlet pipe, a first chamber, a second chamber and a third chamber, wherein the air inlet pipe is fixedly connected to the outer end of the main body, the first chamber, the second chamber and the third chamber are fixedly arranged in the main body, cooling water is injected into the first chamber and the second chamber, a separating device is embedded in the first chamber, a partition plate is fixedly connected to the inside of the separating device, a concentration box is fixedly connected to the outer end of the main body, a first conducting pipe and a second conducting pipe are embedded in the second chamber, a heat conducting plate is fixedly connected to the surface of the first conducting pipe, an output head is fixedly connected to the outer side of the first conducting pipe, a heat conducting head and an air outlet head are fixedly connected to the inner portion and the front end of the output head respectively, the air outlet head is positioned below the heat conducting head, a valve is fixedly connected to the body of the output head, and a temporary storage box is fixedly arranged at the bottom of the third chamber, the outer end fixedly connected with third conduction pipe of storing the box temporarily, the top fixedly connected with delivery pump of third chamber, delivery pump and outside pipeline butt joint.

Further preferred embodiments: the separating device is vertically embedded inside the first chamber.

Further preferred embodiments: the baffle transversely sets up in separator's inside top one third position, and the baffle sets up to netted ventilative baffle, and the interface position between intake pipe and the separator is seted up in the below of baffle simultaneously.

Further preferred embodiments: first conduction pipe and second conduction pipe outer end dock with separator simultaneously, and first conduction pipe wholly is "U" form and distributes the setting, and the second conduction pipe sets up two sets ofly, distributes in the bottom outside both sides position of first conduction pipe, and first conduction pipe is vertical setting, and the second conduction pipe is transverse distribution and sets up.

Further preferred embodiments: the heat-conducting plate evenly distributed is in the outside surface of first conduction pipe, and horizontal level is outstanding to be set up, and the heat-conducting plate sets up to the metal sheet.

Further preferred embodiments: the valve is set as an electromagnetic valve, a built-in control element and is electrically connected with an external control device.

Further preferred embodiments: the output head is transversely arranged, and vertical distribution sets up, and the embedding is in the third chamber simultaneously, and heat conduction head and play gas head all are the horizontal outstanding setting, and the embedding is in the third chamber simultaneously.

Further preferred embodiments: the temporary storage box is simultaneously communicated with the second conduction pipe.

Further preferred embodiments: the third conduction pipe is simultaneously vertically arranged in a U shape in the third chamber, and the outer end extension pipe is connected with the central tank.

Has the advantages that:

this kind of air compressor machine waste heat recovery mechanism for ceramic machining sets up the baffle in separator inside, separates into two sections cavities with separator inside, and the interface position between intake pipe and the separator sets up in the below of baffle, and in along with outside oil gas entering separator, the gaseous and liquid of oil gas material between separate the processing simultaneously, and liquid concentrates on in separator's the bottom cavity, and gaseous rising concentrates on separator's top cavity through the baffle filtration.

This kind of air compressor machine waste heat recovery mechanism for ceramic machining carries the processing through first conduction pipe and second conduction to the oil gas material of separation.

This kind of air compressor machine waste heat recovery mechanism for ceramic machining through the heat-conducting plate, when first pipe carries gas, concentrates the heat to reach the effect of reinforcing gaseous heat conversion.

This kind of air compressor machine waste heat recovery mechanism for ceramic machining, the transport of the inside gas of first transfer line through valve control.

This kind of air compressor machine waste heat recovery mechanism for ceramic machining reaches the effect of carrying out the inside conveying gas of first conduction pipe outwards through the output head, will concentrate the heat in the gas that will be exported through the heat conduction head, reaches the effect of reinforcing heat swivel, and the setting of gas outlet head will contain the thermal gas and discharge in to the third chamber.

This kind of air compressor machine waste heat recovery mechanism for ceramic machining carries the liquid of separation through the third conduction pipe, and the effectual area of contact who increases and cooling water in the third chamber reaches the effect of heat conversion.

Drawings

Fig. 1 is a sectional view of the overall structure of the present invention.

FIG. 2 is an enlarged view of the structure at A in FIG. 1 according to the present invention.

Fig. 3 is an enlarged view of the structure at B in fig. 1 according to the present invention.

In FIGS. 1-3: the device comprises a main body 1, an air inlet pipe 2, a first chamber 3, a second chamber 4, a third chamber 5, a delivery pump 6, a separating device 7, a partition plate 8, a first conducting pipe 9, a second conducting pipe 10, a temporary storage box 11, a third conducting pipe 12, a centralized box 13, a heat conducting plate 14, an output head 15, a heat conducting head 16, a valve 17 and an air outlet head 18.

Detailed Description

As shown in figures 1 to 3:

the utility model provides a waste heat recovery mechanism of an air compressor for ceramic processing, which comprises a main body 1, an air inlet pipe 2, a first chamber 3, a second chamber 4 and a third chamber 5, wherein the air inlet pipe 2 is fixedly connected with the outer end of the main body 1, the first chamber 3, the second chamber 4 and the third chamber 5 are fixedly arranged in the main body 1, cooling water is injected into the first chamber 3 and the second chamber 4, a separation device 7 is embedded in the first chamber 3, a partition plate 8 is fixedly connected in the separation device 7, a concentration box 13 is fixedly connected at the outer end of the main body 1, a first conduction pipe 9 and a second conduction pipe 10 are embedded in the second chamber 4, a heat conduction plate 14 is fixedly connected to the surface of the first conduction pipe 9, an output head 15 is fixedly connected to the outer side of the first conduction pipe 9, a heat conduction head 16 and an air outlet head 18 are respectively fixedly connected in the inner part and the front end of the output head 15, the air outlet head 18 is located below the heat conducting head 16, the valve 17 is fixedly connected to the body of the output head 15, the box 11 is temporarily stored in the bottom of the third chamber 5, the outer end of the box 11 is fixedly connected with the third conducting pipe 12, the top end of the third chamber 5 is fixedly connected with the conveying pump 6, and the conveying pump 6 is in butt joint with an external pipeline.

Wherein the separating device 7 is vertically embedded inside the first chamber 3.

Wherein, baffle 8 transversely sets up the inside top third position at separator 7, and baffle 8 sets up to netted ventilative baffle, the interface position between intake pipe 2 and separator 7 is seted up in the below of baffle 8 simultaneously, set up baffle 8 in separator 7 is inside, with the inside separation of separator 7 into two sections cavities, and the interface position between intake pipe 2 and separator 7 sets up in the below of baffle 8, along with outside oil gas gets into separator 7, gas and liquid between the oil gas material carry out the separation processing simultaneously, liquid concentrates in separator 7's the bottom cavity, and gas rises to filter through baffle 8 and concentrates in separator 7's top cavity.

Wherein, first conduction pipe 9 and the butt joint of second conduction pipe 10 outer end with separator 7 simultaneously, and first conduction pipe 9 wholly is "U" form and distributes the setting, and second conduction pipe 10 sets up two sets ofly, distributes in the bottom outside both sides position of first conduction pipe 9, and first conduction pipe 9 is vertical setting, and second conduction pipe 10 is the transverse distribution setting, thereby carries the processing through first conduction pipe 9 and second conduction 10 to the oil gas material of separation.

Wherein, heat-conducting plate 14 evenly distributed is at the outside surface of first conduction pipe 9, and horizontal level is outstanding to be set up, and heat-conducting plate 14 sets up to the metal sheet, through heat-conducting plate 14, when first conduction pipe 9 carries gas, concentrates the heat to reach the effect of reinforcing gaseous heat conversion.

Wherein, the valve 17 is set as an electromagnetic valve, a built-in control element is electrically connected with an external control device, and the delivery of the gas in the first delivery pipe 9 is controlled by the valve 17.

Wherein, output head 15 transversely sets up, vertical distribution sets up, the embedding is in third chamber 5 simultaneously, heat conduction head 16 and play gas head 18 all are the setting of horizontal salient, the embedding is in third chamber 5 simultaneously, reach the outside effect of carrying on the transport with the inside conveying gas of first transfer pipe 9 through output head 15, heat in the gas that will be about to output through heat conduction head 16 is concentrated, reach the effect of reinforcing heat swivel, and the setting of giving vent to anger head 18, gas to the third chamber 5 discharge that will contain the heat.

Wherein the temporary storage box 11 is simultaneously communicated with the second conductive pipe 10.

Wherein, third conduction pipe 12 is the vertical setting of "U" form simultaneously in third chamber 5, and outer end extension pipe and header 13 are connected simultaneously, carry the liquid of separation through third conduction pipe 12, and the effectual area of contact who increases and cooling water in the third chamber 5 reaches heat conversion's effect.

The working principle is as follows:

the specific use mode and function of the embodiment are that external oil gas enters the separation device 7 through the air inlet pipe 2, the separation device 7 separates gas and liquid in the oil gas, the gas and the liquid are respectively conveyed into the second chamber 4 through the first conducting pipe 9 and the second conducting pipe 10, after the gas and the liquid are contacted with cooling water in the second chamber 4, the gas is contacted with the cooling water in the third chamber 5 through the heat conducting head 16 and the air outlet head 18 at the front end of the output head 15, the whole heat conversion is completed, after the liquid is concentrated in the temporary storage box 11, the liquid is contacted with the cooling water in the third chamber 5 through the third conducting pipe 12, the heat conversion of the liquid is completed, and finally the liquid is conveyed to the concentration box 13 through the third conducting pipe 12 to be collected.

Claims (9)

1. The utility model provides an air compressor machine waste heat recovery mechanism for ceramic machining, including main part (1), intake pipe (2), first cavity (3), second cavity (4), and third cavity (5), intake pipe (2) fixed connection is in the outer end of main part (1), first cavity (3), second cavity (4) and third cavity (5) are all fixed and are seted up in the inside of main part (1), the inside cooling water that pours into of first cavity (3) and second cavity (4), its characterized in that: a separation device (7) is embedded in the first chamber (3), a partition plate (8) is fixedly connected in the separation device (7), a concentration box (13) is fixedly connected at the outer end of the main body (1), a first conduction pipe (9) and a second conduction pipe (10) are embedded in the second chamber (4), a heat conduction plate (14) is fixedly connected to the surface of the first conduction pipe (9), an output head (15) is fixedly connected to the outer side of the first conduction pipe (9), a heat conduction head (16) and an air outlet head (18) are respectively fixedly connected in the inner part and the front end of the output head (15), the air outlet head (18) is positioned below the heat conduction head (16), a valve (17) is fixedly connected to the body of the output head (15), a temporary storage box (11) is fixedly arranged at the bottom of the third chamber (5), a third conduction pipe (12) is fixedly connected to the temporary storage box (11), the top end of the third chamber (5) is fixedly connected with a delivery pump (6), and the delivery pump (6) is in butt joint with an external pipeline.

2. The air compressor waste heat recovery mechanism for ceramic processing according to claim 1, characterized in that: the separation device (7) is vertically embedded inside the first chamber (3).

3. The air compressor waste heat recovery mechanism for ceramic processing according to claim 1, characterized in that: baffle (8) transversely set up the inside top third position at separator (7), and baffle (8) set up to netted ventilative baffle, and the interface position between intake pipe (2) and separator (7) is seted up in the below of baffle (8) simultaneously.

4. The air compressor waste heat recovery mechanism for ceramic processing according to claim 1, characterized in that: first conduction pipe (9) and second conduction pipe (10) outer end dock with separator (7) simultaneously, and first conduction pipe (9) wholly are "U" form and distribute the setting, and second conduction pipe (10) set up two sets ofly, distribute in the bottom outside both sides position of first conduction pipe (9), and first conduction pipe (9) are vertical setting, and second conduction pipe (10) are the transverse distribution setting.

5. The air compressor waste heat recovery mechanism for ceramic processing according to claim 1, characterized in that: the heat-conducting plates (14) are uniformly distributed on the outer side surface of the first conducting pipe (9) and transversely and horizontally arranged in a protruding mode, and the heat-conducting plates (14) are metal plates.

6. The air compressor waste heat recovery mechanism for ceramic processing according to claim 1, characterized in that: the valve (17) is set as an electromagnetic valve, a built-in control element and is electrically connected with an external control device.

7. The air compressor waste heat recovery mechanism for ceramic processing according to claim 1, characterized in that: the output heads (15) are transversely arranged and vertically distributed and are embedded into the third chamber (5), and the heat conducting heads (16) and the air outlet heads (18) are transversely arranged in a protruding mode and are embedded into the third chamber (5) simultaneously.

8. The air compressor waste heat recovery mechanism for ceramic processing according to claim 1, characterized in that: the temporary storage box (11) is communicated with the second conduction pipe (10) at the same time.

9. The air compressor waste heat recovery mechanism for ceramic processing according to claim 1, characterized in that: the third conduction pipe (12) is vertically arranged in a U shape in the third chamber (5), and meanwhile, an outer end extension pipe is connected with the header tank (13).

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