CN201771564U - Screw rod expansion power machine and control system thereof - Google Patents

Abstract

The utility model provides a screw rod expansion power machine comprising an overturn type inlet device and a screw rod expansion power machine main body, wherein the overturn type inlet device comprises an inlet pipe and an overturn piece, work fluid is input to the screw rod expansion power machine main body through the input pipe; the overturn piece is arranged in the inlet pipe, and comprises an all-in-one rotating shaft, a rotary rod and an overturn surface; the overturn surface just covers the inlet pipe, the rotating shaft comprises a rotating shaft end part which is clamped at the inner side of the inlet pipe along the radial direction of the inlet pipe, the rotating shaft rotates by surrounding the radial direction of the inlet pipe through the rotating shaft end part, wherein the rotating shaft penetrates through the side wall of the inlet pipe, and the rotary rod and the rotating shaft end part penetrate through the side wall part of the inlet pipe and are fixedly connected. The utility model further provides a control system of the screw rod expansion power machine. By the arrangement, in the technical scheme, the size of the cross section of the inlet pipe, used for the circulation of the work fluid, can be adjusted automatically according to the flow or pressure of the current work fluid, thus improving the heat utilizing efficiency.

Description

A kind of screw expansion motor and control system thereof

[technical field]

The utility model belongs to the waste heat utilization technology field, particularly relates to a kind of screw expansion motor and control system thereof.

[background technique]

The primary energy present situation of China allows of no optimist, though the coal resources reserves world rankings second (U.S. first, be a times of China's reserves), but the minable coal resources of China are not enough the century-old time, country far fewer than world's first six digits coal storage quantity, in addition, the oil and natural gas resource of China is also only enough exploited decades, and worldwide petroleum production is shortage within this century also.

Therefore, at above situation, it is very with practical value with the waste vapour recycling system of generating electricity effectively to reclaim unnecessary heat, usually, unnecessary heat in the recyclable industrial wastewater of waste vapour recycling system, blast furnace waste residue, the high temperature waste vapour etc. is converted to unnecessary heat that mechanical energy is generated electricity or other work.

Please refer to Figure 1A and Figure 1B, shown the basic principle of the screw expansion motor main body 10 of prior art.Waste heat flue gas or hydrothermal solution by admission passage 3 in admission road junction 4 enters the teeth groove of positive screw rod 1, rotation along with positive screw rod 1 and female screw 2, the cavity volume of working fluid (as waste vapour or working medium) increases gradually, working fluid step-down cooling is expanded and is done work, lead-screw rotates, and finishes the working fluid of merit and is discharged by steam exhausting way 5.Power can drive equipment such as feed water pump, blower fan, generator by the output terminal output of positive screw rod 1.

Fig. 2 has shown the basic structure of the screw expansion motor 30 of prior art, and it comprises screw expansion motor main body 10, load equipment 20, modulating valve 32, electric control cabinet 33, fuel tank 34 and pedestal 31.Screw expansion motor main body 10 has admission passage shown in Figure 13 and steam exhausting way 5.Screw expansion motor 10 links to each other with the output shaft of load equipment 20 by positive screw rod (figure does not show).Sometimes the rotating speed of screw expansion motor 10 is very fast, and speed reducer (figure does not show) need be set between screw expansion motor 10 and load equipment 20.

In existing waste vapour recycling system, the admission inlet size of screw expansion motor is determined by following mode usually, promptly estimate working fluid (for example being waste vapour or the working medium) flow that the waste vapour recycling system can be obtained in advance, the size of the admission inlet that matches according to this working fluid flow set then, therefore in the normal use afterwards, generally speaking can in screw expansion motor, use the admission inlet of fixed size.

The screw expansion motor that more than adopts fixedly admission inlet is very efficient under to the flow of work at present fluid (for example waste vapour or working medium) or the big or small metastable situation of pressure, when but the flow of work at present fluid or pressure size are unstable, the admission inlet that is set to fixed size can be wasted the heat and the build-up of pressure deficiency (or excessive) of work at present fluid, and this is very disadvantageous for the efficiency of utilization that improves whole waste vapour recycling system.

Therefore, need provide a kind of inlet duct of can adjusting automatically according to work at present fluid flow or pressure size can be, thereby overcome the above problems for the screw expansion motor and the control system thereof of the cross-section area size of working fluid circulation.

[summary of the invention]

Technical problem to be solved in the utility model is to provide a kind of screw expansion motor and control system thereof, it can adjust inlet duct automatically according to the flow of work at present fluid or pressure size can be for the cross-section area size of working fluid circulation, thereby has improved efficiency of utilization.

The utility model provides a kind of screw expansion motor, comprising: convertible inlet device is used to control the flow of the working fluid of input; The screw expansion motor main body is communicated with convertible inlet device, obtains working fluid from convertible inlet device, utilizes the working fluid acting with output mechanical energy; Wherein, convertible inlet device comprises: inlet duct, and working fluid inputs to the screw expansion motor main body through inlet duct; Flip piece, be arranged in the inlet duct, comprise integrated rotating shaft, swing arm and upset face, upset face is set to just cover inlet duct, and rotating shaft comprises roller end, and roller end is along the inboard that radially is placed in inlet duct of inlet duct, rotating shaft is by the radially rotation of roller end around inlet duct, wherein, roller end is passed the inlet duct sidewall, and swing arm passes the inlet duct wall portion with roller end fixedlys connected.

According to the utility model one preferred embodiment, working fluid is a waste vapour.

According to the utility model one preferred embodiment, working fluid is a working medium.Working medium can be the form of liquid, fluid or solid.

The utility model further provides a kind of control system of controlling above-mentioned screw expansion motor, comprising: the pressure measurement valve is used for the force value of surveying work fluid; The flow measurement valve is used for the flow value of surveying work fluid; The control module is controlled the rotating angle of the swing arm of convertible inlet device according to force value or flow value.

According to the utility model one preferred embodiment, the control module comprises: oil engine produces hydraulic stroke according to hydraulic pressure signal; Displacement transducer obtains the stroke detection signal according to hydraulic stroke; The digital electro-hydraulic control module is obtained force value and flow value, exports servo setting value according to force value or flow value; Servo module receives stroke detection signal and servo setting value, according to stroke detection signal and servo setting value output control signal; Electro-control converter receives control signal, control signal is converted to hydraulic pressure signal exports oil engine to; Driver module is controlled the rotating angle of the swing arm of convertible inlet device according to hydraulic stroke.

According to the utility model one preferred embodiment, oil engine comprises: piston, by the mobile generation hydraulic stroke of piston; Cavity, piston are arranged in the cavity, and piston moves in cavity; Oil pump is moved to promote piston cavity oiling or oil suction by electro-control converter control; Spring produces elastic force to make piston be positioned at the cavity sidepiece under the state that does not have oiling at cavity; First connecting rod, an end is fixedlyed connected with piston, and the other end is fixedlyed connected with spring, and spring interacts by first connecting rod and piston.

According to the utility model one preferred embodiment, driver module comprises: second connecting rod, and an end is fixedlyed connected with piston; Slide block, the other end of second connecting rod is fixedlyed connected with slide block one side; Guide rail, slide block are set to slide in guide rail; Third connecting rod, an end is articulated in the slide block opposite side, and the other end and swing arm are hinged.

Therefore, the utility model provides a kind of screw expansion motor and control system thereof, and it can adjust inlet duct automatically according to the flow of work at present fluid or pressure size can be for the cross-section area size of working fluid circulation, thereby has improved efficiency of utilization.

[description of drawings]

Can more specifically describe the utility model by example with reference to the accompanying drawings, wherein accompanying drawing is not proportionally drawn, in the accompanying drawings:

Figure 1A and Figure 1B have shown the basic principle of the screw expansion motor main body of prior art;

Fig. 2 has shown the basic structure of the screw expansion motor of prior art;

Fig. 3 has shown the schematic diagram of a preferred embodiment of the waste vapour recycling system of having used screw expansion motor of the present utility model;

Fig. 4 has shown the schematic diagram of another preferred embodiment of the waste vapour recycling system of having used screw expansion motor of the present utility model;

Fig. 5 has shown that the convertible inlet device in the screw expansion motor of the present utility model is in the structural representation under first state;

Fig. 6 has shown the structural representation under second state of being in of convertible inlet device in the screw expansion motor of the present utility model;

Fig. 7 has shown that the convertible inlet device in the screw expansion motor of the present utility model is in the transverse cross-sectional view under first state;

Fig. 8 has shown that the convertible inlet device in the screw expansion motor of the present utility model is in the transverse cross-sectional view under second state;

Fig. 9 has shown that the circuit of the control system of screw expansion motor of the present utility model connects block diagram;

Figure 10 has shown the control system and the mechanical connection figure of convertible inlet device under first state of screw expansion motor of the present utility model; And

Figure 11 has shown the control system and the mechanical connection figure of convertible inlet device under second state of screw expansion motor of the present utility model.

[embodiment]

In order further to understand the utility model is to reach technology, means and the effect that predetermined purpose is taked, see also following about detailed description of the present utility model and accompanying drawing, believe the purpose of this utility model, feature and characteristics, can obtain thus going deep into and concrete understanding, yet appended graphic reference and the explanation usefulness of only providing not is to be used for the utility model is limited.

Please refer to Fig. 3, Fig. 3 has shown the schematic diagram of a preferred embodiment of the waste vapour recycling system of having used screw expansion motor of the present utility model.In Fig. 3, waste vapour is discharged from waste steam exhausting equipment 101, enter screw expansion motor 104 via pipeline 105, flow measurement valve 106, pressure measurement valve 160 are arranged on the inlet side of screw expansion motor 104 in the pipeline 105, and control module 111 obtains flow, pressure data from flow measurement valve 106, pressure measurement valve 160.Screw expansion motor 104 comprises convertible inlet device 140 and screw expansion motor main body 102, wherein, convertible inlet device 140 controlled module 111 controls, screw expansion motor main body 102 will be converted to mechanical energy from the heat that high-temp waste gas contained of convertible inlet device 140 inputs, power is from the output terminal output of screw expansion motor main body 102, can drive load equipment (does not illustrate among Fig. 3, it can be a water pump, equipment such as blower fan and generator, the utility model is not made restriction to this), waste vapour after the acting can be discharged from screw expansion motor 104, flows to waste vapour recovery operation station 103 along S1.

Fig. 4 has shown the schematic diagram of another preferred embodiment of the waste vapour recycling system of having used screw expansion motor of the present utility model.In Fig. 4, waste vapour is discharged from waste steam exhausting equipment 201, enter heat exchanger 217 via pipeline 205, after handling, heat exchange flows out to waste vapour recovery operation station 203, working medium circulation loop 216 is same through heat exchanger 217, heat exchanger 217 can be with the working medium in the heat transferred working medium circulation loop 205 that the waste vapour in the pipeline 205 contained (this working medium flow direction be pointed for S2 among Fig. 4), flow measurement valve 206, pressure measurement valve 260 is arranged on the inlet side of screw expansion motor 204 in the working medium circulation loop 205, and control module 211 is from flow measurement valve 206, pressure measurement valve 260 obtains flow, force value.Screw expansion motor 204 comprises convertible inlet device 240 and screw expansion motor main body 202, wherein, convertible inlet device 240 controlled module 211 controls, screw expansion motor main body 202 will be converted to mechanical energy from the heat that high temperature refrigerant contained of convertible inlet device 240 inputs, power is from the output terminal output of screw expansion motor main body 202, can drive load equipment (does not illustrate among Fig. 4, it can be water pump, equipment such as blower fan and generator, the utility model is not made restriction to this), working medium after the acting can be discharged from screw expansion motor 204, flows to heat exchanger 217 along S2 and reheats.In addition, in Fig. 4, also can comprise condenser 218 in working medium circulation loop 205, condenser 218 is arranged on the working medium outlet side of screw expansion motor 221, is used for further cooling working medium.

Please refer to Fig. 5, it has shown that convertible inlet device in the screw expansion motor of the present utility model is in the structural representation under first state.Wherein, convertible inlet device 340 in the screw expansion motor of the present utility model shown in Fig. 5 and Fig. 3 and convertible inlet device 140 and 240 shown in Figure 4 are identical, and convertible inlet device 340 can be used for controlling the flow of the hot operation fluid (as waste vapour or working medium) of input.As shown in Figure 5, convertible inlet device 340 comprises inlet duct 330 and is arranged on flip piece 320 in the inlet duct 330, flip piece 320 comprises integrated rotating shaft 321, swing arm 322 and upset face 324, upset face 324 is set to just cover inlet duct 330, rotating shaft 321 comprises roller end 323, roller end 323 is along the inboard that radially is placed in inlet duct 330 of inlet duct 330, rotating shaft 321 is by the radially rotation of roller end 323 around inlet duct, wherein, roller end 323 is passed inlet duct 330 sidewalls, and swing arm 322 is fixedlyed connected with the wall portion that roller end 323 is passed inlet duct 330.

Therefore, utilize the rotation of rotating shaft 321 can drive 324 upsets of upset face.In addition, thereby can pass through to use external force turn swing arm 322 rotating shafts 321, and then 324 upsets of feasible upset face.It should be noted that, convertible inlet device 340 in screw expansion motor of the present utility model be in for first state following time, upset face 324 is in the state that covers inlet duct 330 fully, and working fluid can not enter the screw expansion motor main body by inlet duct 330.

Fig. 6 has shown the structural representation under second state of being in of convertible inlet device in the screw expansion motor of the present utility model.As shown in Figure 6, when using the external force turn to be arranged on swing arm 322 inlet duct 330 outside, can make upset face 324 be in rollover states wholly or in part, thereby control is by the size of the working fluid flow of inlet duct 330 inflow screw expansion motor main bodys.

Fig. 7 has shown that the convertible inlet device in the screw expansion motor of the present utility model is in the transverse cross-sectional view under first state.As shown in Figure 7, end 323 parts of axis body 321 protrude in inlet duct 330, and (it is through encapsulation process, make working fluid can be from the end 323 openings that protrude in inlet duct 330 flow out), swing arm 322 (not illustrating) can be fixedlyed connected with end 323, when being in first state, upset face 324 can cover inlet duct 330, and the cross-section area that makes inlet duct 330 to pass through for working fluid is 0.

Fig. 8 has shown that the convertible inlet device in the screw expansion motor of the present utility model is in the transverse cross-sectional view under second state.As shown in Figure 8, when swing arm 322 (not illustrating) is subjected to the external force turn, can make rotating shaft 321 drive upset face 324 321 upset 0-90 degree around the shaft, thereby make inlet duct 330 between 0-1, to change (cross-section area of supposing inlet duct is 1, and ignores upset face 324 thickness) for the cross-section area that working fluid passes through.

It should be noted that and use different external force turn swing arms 322, can make upset face 324 between the 0-90 degree, 321 overturn around the shaft, thus the cross-section area size that may command inlet duct 330 passes through for working fluid.

Fig. 9 has shown that the circuit of the control system of screw expansion motor of the present utility model connects block diagram.Please refer to Fig. 7, this control system comprises control module 700, pressure measurement valve 711 and flow measurement valve 731, wherein controls module 700 and comprises digital electro-hydraulic control module 702, servo module 703, electro-control converter 704, oil engine 705, driver module 706 and displacement transducer 741.Digital electro-hydraulic control module 702 can be obtained the force value of the working fluid convertible inlet device 340 from pressure measurement valve 711, can obtain the flow value of the working fluid convertible inlet device 340 from flow measurement valve 731.

702 pairs of force value of digital electro-hydraulic control module and flow value calculate, and export servo setting value.

Servo module 703 is used for realizing driver module 706 is controlled, this servo module 703 can receive the servo setting value of digital electro-hydraulic control module 702 outputs and the stroke detection signal of being exported by displacement transducer 741, and above signal is carried out computing with the output control signal.

Electro-control converter 704 is used to receive the control signal of servo module 703 outputs, and control signal is converted to hydraulic pressure signal output.

Oil engine 705 is used to receive the hydraulic pressure signal of electro-control converter 704 outputs, produce hydraulic stroke according to this hydraulic control signal, thereby driver module 706 is controlled the flow of the rotating angle control inflow screw expansion motor main body of the swing arm 322 in the convertible inlet device 340 according to hydraulic stroke.

The hydraulic stroke that displacement transducer 741 detects oil engine 705 obtains the stroke detection signal, and the stroke detection signal is inputed to servo module 703.

Servo module 703, displacement transducer 741, electro-control converter 704 constitute servo loop, servo setting value according to digital electro-hydraulic control module 702, and the hydraulic stroke that detects oil engine 705 obtains the stroke detection signal, pass through feedback control, obtain the desired oil engine hydraulic stroke of servo setting value, realize servocontrol oil engine 705.

Figure 10 has shown the control system and the mechanical connection figure of convertible inlet device under first state of screw expansion motor of the present utility model.As shown in figure 10, the oil engine of being introduced in Fig. 9 705 comprises spring 301, first connecting rod 302, piston 303, cavity 304 and oil pump 305, wherein first connecting rod 302 is fixedly connected between piston 303 and the spring 301, moving of piston 303 can produce hydraulic stroke and drive first connecting rod 302, be not subjected under the external force effect at piston 303, spring 301 can be pushed to piston 303 cavity 304 position that takes over.In addition, oil pump 305 can be moved to promote piston 303 by electro-control converter 704 controls to cavity 304 oilings or oil suction.

In addition, as shown in figure 10, the driver module of being introduced among Fig. 9 706 comprises second connecting rod 306, guide rail 310, slide block 311 and third connecting rod 312, one end of second connecting rod 306 is fixedly connected on a side of the slide block 311 of driver module 706, the other end is fixedly connected on piston 303, and slide block 311 is arranged in the guide rail 310, and slide block 311 can slide along guide rail 310, third connecting rod 312 1 ends and slide block 311 are hinged, and the swing arm 322 in the other end and the convertible inlet device 340 is hinged.By the gearing of third connecting rod 312, but slide block 311 move horizontally turn swing arm 322, thereby the upset face of making 324 upsets.

When oil pump 305 does not have to cavity 304 oilings, spring 301 promotes piston 303 to produce hydraulic stroke from the direction shown in the F1 by first connecting rod 302, hydraulic stroke is pushed to cavity 304 position that takes over piston 303, second connecting rod 306 can promote slide block 311 and move right to guide rail 310 position that takes over along guide rail 310 under the promotion of piston 303, at this moment, third connecting rod 312 may command swing arms 322 are positioned at primary importance, when swing arm 322 was positioned at primary importance, upset face 324 just was in first state that covers inlet duct 330 fully.

Figure 11 has shown the control system and the mechanical connection figure of convertible inlet device under second state of screw expansion motor of the present utility model.As shown in figure 11, when oil pump 305 during to cavity 304 oilings, can make piston 303 take over position moving plug 303 to produce hydraulic stroke to cavity 304, this hydraulic stroke is from spurring second connecting rod 306 in the opposite direction with the side shown in the F1, second connecting rod 306 can spur slide block 311 and be moved to the left guide rail 310 position of taking back along guide rail 310, slide block 311 pulling third connecting rods 312, thereby turn swing arm 322 make that upset face 324 can be according to the hydraulic stroke different angle of overturning.

When slide block 311 was in guide rail 310 and takes back the position, third connecting rod 312 control swing arms 322 were in the second place, and at this moment, upset face 324 just is arranged in second state of the cross-section area that open fully inlet duct 330 can pass through for working fluid.

It should be noted that, screw expansion motor of the present utility model and control system thereof can be controlled the rotating angle of swing arm 322 by the hydraulic stroke that oil engine 705 produces, the upset face of making 324 overturns between the 0-90 degree, thus the cross-section area size that can supply working fluid to pass through in the may command inlet duct 330.

Therefore, force value or flow value that the control system of screw expansion motor of the present utility model can obtain the working fluid in the convertible inlet device by the pressure or the flow of the working fluid in pressure measurement valve 711 or flow measurement valve 731 measuring channels, control module 700 obtains force value or flow value, and it carries out calculation process and controls in the inlet duct 330 the cross-section area size that can pass through for working fluid with the rotation angle of the upset face 324 that determines convertible inlet device, and then guaranteed that the screw expansion motor main body is not influenced by the flow of working fluid or fluctuating widely of pressure, thereby improved efficiency of utilization.

In the above-described embodiments, only the utility model has been carried out exemplary description, but those skilled in the art can carry out various modifications to the utility model after reading present patent application under the situation that does not break away from spirit and scope of the present utility model.

Claims (7)

1. a screw expansion motor is characterized in that, comprising:

Convertible inlet device is used to control the flow of the working fluid of input;

The screw expansion motor main body is communicated with described convertible inlet device, obtains described working fluid from described convertible inlet device, utilizes described working fluid acting with output mechanical energy;

Wherein, described convertible inlet device comprises:

Inlet duct, described working fluid inputs to described screw expansion motor main body through described inlet duct;

Flip piece, be arranged in the described inlet duct, comprise integrated rotating shaft, swing arm and upset face, described upset face is set to just cover described inlet duct, described rotating shaft comprises roller end, described roller end is along the inboard that radially is placed in described inlet duct of described inlet duct, described rotating shaft is by the radially rotation of described roller end around described inlet duct, described roller end is passed described inlet duct sidewall, and described swing arm passes described inlet duct wall portion with described roller end fixedlys connected.

2. screw expansion motor according to claim 1 is characterized in that, described working fluid is a waste vapour.

3. screw expansion motor according to claim 1 is characterized in that, described working fluid is a working medium.

4. a control system of controlling each described screw expansion motor of claim 1 to 3 is characterized in that, comprising:

The pressure measurement valve is used to measure the force value of described working fluid;

The flow measurement valve is used to measure the flow value of described working fluid;

The control module is controlled the rotating angle of the described swing arm of described convertible inlet device according to described force value or described flow value.

5. control system according to claim 4 is characterized in that, described control module comprises:

Oil engine produces hydraulic stroke according to hydraulic pressure signal;

Displacement transducer obtains the stroke detection signal according to described hydraulic stroke;

The digital electro-hydraulic control module is obtained described force value and flow value, exports servo setting value according to described force value or flow value;

Servo module receives described stroke detection signal and described servo setting value, according to stroke detection signal and described servo setting value output control signal;

Electro-control converter receives described control signal, described control signal is converted to hydraulic pressure signal exports described oil engine to;

Driver module is controlled the rotating angle of the described swing arm of described convertible inlet device according to described hydraulic stroke.

6. control system according to claim 5 is characterized in that, described oil engine comprises:

Piston is by the described hydraulic stroke of mobile generation of described piston;

Cavity, described piston are arranged in the described cavity, and described piston moves in described cavity;

Oil pump is moved to promote described piston described cavity oiling or oil suction by described electro-control converter control;

Spring produces elastic force to make described piston be positioned at described cavity sidepiece under the state that does not have oiling at described cavity;

First connecting rod, an end is fixedlyed connected with described piston, and the other end is fixedlyed connected with described spring, and described spring interacts by described first connecting rod and described piston.

7. control system according to claim 6 is characterized in that, described driver module comprises:

Second connecting rod, an end is fixedlyed connected with described piston;

Slide block, the other end of described second connecting rod is fixedlyed connected with described slide block one side;

Guide rail, described slide block are set to slide in described guide rail;

Third connecting rod, an end are articulated in described slide block opposite side, and the other end and described swing arm are hinged.

Images