CN104234826A - Triangular rotor fluid mechanism and engine adopting triangular rotor fluid mechanism - Google Patents
Triangular rotor fluid mechanism and engine adopting triangular rotor fluid mechanism Download PDFInfo
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- CN104234826A CN104234826A CN201410476114.3A CN201410476114A CN104234826A CN 104234826 A CN104234826 A CN 104234826A CN 201410476114 A CN201410476114 A CN 201410476114A CN 104234826 A CN104234826 A CN 104234826A
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- apexed rotor
- hydraulic mechanism
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02T—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
- Y02T10/00—Road transport of goods or passengers
- Y02T10/10—Internal combustion engine [ICE] based vehicles
- Y02T10/12—Improving ICE efficiencies
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Abstract
The invention discloses a triangular rotor fluid mechanism and an engine adopting the triangular rotor fluid mechanism. The triangular rotor fluid mechanism comprises a triangular rotor, wherein the triangular rotor is arranged in a double-arc tubular cavity, and more than two fluid inlets and more than two fluid outlets are totally and correspondingly formed in the double-arc tubular cavity and an end part sealing body of the double-arc tubular cavity. The triangular rotor fluid mechanism and the engine adopting the triangular rotor fluid mechanism disclosed by the invention have the advantages that the structure is simple and reliable, the manufacturing and production cost is low, and the efficiency is high. The triangular rotor fluid mechanism and the engine adopting the triangular rotor fluid mechanism disclosed by the invention have the advantages that the structure is simple and reliable, the manufacturing and production cost is low, and the efficiency is high.
Description
Technical field
The present invention relates to heat energy and dynamic field, especially a kind of three-apexed rotor hydraulic mechanism and apply its motor.
Background technique
Many types of traditional three-apexed rotor hydraulic mechanism are widely used, but there is the problem of sealing and wearing and tearing and processing difficulties, therefore, need to invent a kind of Novel triangle rotor fluid mechanism.
Summary of the invention
In order to solve the problem, the technological scheme that the present invention proposes is as follows:
Scheme 1, a kind of three-apexed rotor hydraulic mechanism, comprise three-apexed rotor, described three-apexed rotor is arranged in two arc cylindrical cavity, and on the end sealing body of described pair of arc cylindrical cavity and described pair of arc cylindrical cavity, correspondence arranges two or more fluid input and two or more fluid output altogether.
Scheme 2, on the basis of scheme 1, described fluid input and described fluid output correspondence are arranged on described pair of arc cylindrical cavity or correspondence is arranged on the end sealing body of described pair of arc cylindrical cavity.
Scheme 3, on the basis of scheme 1 or 2, the top, angle of described three-apexed rotor and the contact internal walls slipper seal of described pair of arc cylindrical cavity are equipped with.
Scheme 4, on the basis of scheme 1 or 2, the top, angle of described three-apexed rotor and the inwall non-contact slipper seal of described pair of arc cylindrical cavity are equipped with.
Scheme 5, in scheme 1 to 4 either a program basis on, described three-apexed rotor and eccentric shaft are connected, or described three-apexed rotor and described eccentric shaft integrated setting.
Scheme 6, in scheme 1 to 4 either a program basis on, described three-apexed rotor is established eccentric shaft axis hole, and described eccentric shaft axis hole and eccentric shaft are equipped with.
Scheme 7, in scheme 1 to 4 either a program basis on, described three-apexed rotor arranges internal gear, and described internal gear engages with static external gear.
Scheme 8, on the basis of scheme 1 or 2, the side of described three-apexed rotor and the described end sealing body non-contact slipper seal of described pair of arc cylindrical cavity are arranged.
Scheme 9, on the basis of scheme 1 or 2, the side of described three-apexed rotor and the described end sealing body contact slide of described pair of arc cylindrical cavity seal and arrange.
Scheme 10, in scheme 1 to 9 either a program basis on, establish at described fluid input place fluid import control valve.
Scheme 11, in scheme 1 to 10 either a program basis on, described fluid outlet establish fluid derive control valve.
Scheme 12, in scheme 1 to 9 either a program basis on, described fluid input is communicated with fluid entering channel, described fluid entering channel is established fluid import control valve.
Scheme 13, in scheme 1 to 10 or 12 either a program basis on, described fluid output is communicated with fluid outlet passage, described fluid outlet passage is established fluid derive control valve.
Scheme 14, on the basis of scheme 1 or 2, the top, angle of described three-apexed rotor is established sealing concavo-convex increasing resistance line.
Scheme 15, on the basis of scheme 1 or 2, the inwall of described end sealing body establishes concavo-convex the block structure.
Scheme 16, on the basis of scheme 1 or 2, the end face of described three-apexed rotor establishes concavo-convex the block structure.
Scheme 17, on the basis of scheme 1 or 2, the inwall of described end sealing body is established depression the block structure.
Scheme 18, on the basis of scheme 1 or 2, the end face of described three-apexed rotor is established depression the block structure.
Scheme 19, in scheme 1 to 18 either a program basis on, described fluid input is set to convergent jet pipe.
Scheme 20, the motor of three-apexed rotor hydraulic mechanism described in either a program, described fluid input and internal combustion combustion chamber in a kind of application scheme 1 to 19.
Scheme 21, the motor of three-apexed rotor hydraulic mechanism described in either a program in a kind of application scheme 1 to 19, described fluid input is communicated with compressed gas source.
Scheme 22, the motor of three-apexed rotor hydraulic mechanism described in either a program in a kind of application scheme 1 to 19, described fluid input is communicated with mixed-burned gas liquefaction source.
Scheme 23, the motor of three-apexed rotor hydraulic mechanism described in either a program in a kind of application scheme 1 to 19, described fluid input is communicated with power fluid body source.
Scheme 24, the motor of three-apexed rotor hydraulic mechanism described in either a program in a kind of application scheme 1 to 19, the described fluid input of described three-apexed rotor hydraulic mechanism and the pressurized gas outlet of piston gas compressor.
Scheme 25, the motor of three-apexed rotor hydraulic mechanism described in either a program in a kind of application scheme 1 to 19, the described fluid input of described three-apexed rotor hydraulic mechanism is through the pressurized gas outlet of internal combustion firing chamber and piston gas compressor.
Scheme 26, a motor for three-apexed rotor hydraulic mechanism described in either a program in application scheme 1 to 19, the described fluid output of the above three-apexed rotor hydraulic mechanism stands hot cell and is communicated with more than one the described fluid input of three-apexed rotor hydraulic mechanism described in other.
Scheme 27, a motor for three-apexed rotor hydraulic mechanism described in either a program in application scheme 1 to 19, the described fluid output of the above three-apexed rotor hydraulic mechanism is communicated with more than one the described fluid input of three-apexed rotor hydraulic mechanism described in other through internal combustion firing chamber.
Scheme 28, a motor for three-apexed rotor hydraulic mechanism described in either a program in application scheme 1 to 19, the described fluid output of the A runner of described three-apexed rotor hydraulic mechanism stands hot cell and is communicated with the described fluid input of the B runner of described three-apexed rotor hydraulic mechanism.
Scheme 29, the motor of three-apexed rotor hydraulic mechanism described in either a program in a kind of application scheme 1 to 19, the described fluid output of the A runner of described three-apexed rotor hydraulic mechanism stands hot cell and is communicated with the described fluid input of B runner, and the described fluid output of described B runner is communicated with through the described fluid input of cooler with described A runner.
Scheme 30, on the basis of scheme 29, described three-apexed rotor hydraulic mechanism, is describedly set to helium by the cycle fluid in hot cell and described cooler and communicating passage thereof.
Scheme 31, on the basis of scheme 29, described three-apexed rotor hydraulic mechanism, described being subject to, the working medium envelope of hot cell, described cooler and communicating passage thereof establishes carbon dioxide capture unit, described carbon dioxide capture unit catches the carbon dioxide in working medium, reduces carbon dioxide content in working medium.
Scheme 32, on the basis of scheme 29, is comprising described three-apexed rotor hydraulic mechanism, is describedly establishing working medium export mouth by the working medium envelope of hot cell and described cooler and communicating passage thereof.
Scheme 33, a motor for three-apexed rotor hydraulic mechanism described in either a program in application scheme 1 to 19, the described fluid input of described fluid output through internal combustion firing chamber with the B runner of described three-apexed rotor hydraulic mechanism of the A runner of described three-apexed rotor hydraulic mechanism is communicated with.
Scheme 34, the motor of three-apexed rotor hydraulic mechanism described in either a program in a kind of application scheme 1 to 19, the described fluid input of described fluid output through internal combustion firing chamber with the B runner of described three-apexed rotor hydraulic mechanism of the A runner of described three-apexed rotor hydraulic mechanism is communicated with, and the described fluid output of described B runner is communicated with through the described fluid input of cooler with described A runner.
Scheme 35, on the basis of scheme 34, cycle fluid in described three-apexed rotor hydraulic mechanism, described internal combustion firing chamber and described cooler and communicating passage thereof is set to helium, and the working medium envelope comprising described three-apexed rotor hydraulic mechanism, internal combustion firing chamber and described cooler and communicating passage thereof establishes working medium export mouth.
Scheme 36, on the basis of scheme 34 or 35, the working medium envelope of described three-apexed rotor hydraulic mechanism, internal combustion firing chamber, described cooler and communicating passage thereof establishes carbon dioxide capture unit, described carbon dioxide capture unit catches the carbon dioxide in working medium, reduces carbon dioxide content in working medium.
Scheme 37, the motor of three-apexed rotor hydraulic mechanism described in either a program in a kind of application scheme 1 to 19, it is characterized in that: the described fluid input of described fluid output through internal combustion firing chamber with the B runner of three-apexed rotor hydraulic mechanism described in first of the A runner of three-apexed rotor hydraulic mechanism described in first is communicated with, the described fluid output of the B runner of three-apexed rotor hydraulic mechanism described in first is communicated with the described fluid input of the B runner of three-apexed rotor hydraulic mechanism described in second, the described fluid output of the B runner of three-apexed rotor hydraulic mechanism described in second is communicated with through the described fluid input of cooler with the A runner of three-apexed rotor hydraulic mechanism described in second, the described fluid output of the A runner of three-apexed rotor hydraulic mechanism described in second is communicated with the described fluid input of the A runner of three-apexed rotor hydraulic mechanism described in first.
Scheme 38, on the basis of scheme 37, the cycle fluid in three-apexed rotor hydraulic mechanism, described internal combustion firing chamber and described cooler described in three-apexed rotor hydraulic mechanism, second described in first and communicating passage thereof is set to helium.
Scheme 39, on the basis of scheme 38, the working medium envelope comprising described in first three-apexed rotor hydraulic mechanism described in three-apexed rotor hydraulic mechanism, second, described internal combustion firing chamber and described cooler and communicating passage thereof establishes working medium export mouth.
Scheme 40, on the basis of scheme 38 or 39, the working medium envelope comprising described in first three-apexed rotor hydraulic mechanism described in three-apexed rotor hydraulic mechanism, second, described internal combustion firing chamber and described cooler and communicating passage thereof establishes carbon dioxide capture unit, described carbon dioxide capture unit catches the carbon dioxide in working medium, reduces carbon dioxide content in working medium.
Scheme 41, the motor of three-apexed rotor hydraulic mechanism described in either a program in a kind of application scheme 1 to 19, the described fluid output of the A runner of three-apexed rotor hydraulic mechanism described in first stands hot cell and is communicated with the described fluid input of the B runner of three-apexed rotor hydraulic mechanism described in first, the described fluid output of the B runner of three-apexed rotor hydraulic mechanism described in first is communicated with the described fluid input of the B runner of three-apexed rotor hydraulic mechanism described in second, the described fluid output of the B runner of three-apexed rotor hydraulic mechanism described in second is communicated with through the described fluid input of cooler with the A runner of three-apexed rotor hydraulic mechanism described in second, the described fluid output of the A runner of three-apexed rotor hydraulic mechanism described in second is communicated with the described fluid input of the A runner of three-apexed rotor hydraulic mechanism described in first, three-apexed rotor hydraulic mechanism described in first, three-apexed rotor hydraulic mechanism described in second, describedly be set to helium by the cycle fluid in hot cell and described cooler and communicating passage thereof.
Scheme 42, the motor of three-apexed rotor hydraulic mechanism described in either a program in a kind of application scheme 1 to 19, three the above three-apexed rotor hydraulic mechanism, an internal combustion firing chamber and at least one cooler are interconnected.
Scheme 43, the motor of three-apexed rotor hydraulic mechanism described in either a program in a kind of application scheme 1 to 19, three the above three-apexed rotor hydraulic mechanism, one is interconnected by hot cell and at least one cooler.
Scheme 44, the motor of three-apexed rotor hydraulic mechanism described in either a program in a kind of application scheme 1 to 19, the described fluid input of described fluid output through internal combustion firing chamber with the B runner of three-apexed rotor hydraulic mechanism described in first of the A runner of three-apexed rotor hydraulic mechanism described in first is communicated with, and the described fluid output of the B runner of three-apexed rotor hydraulic mechanism described in first is communicated with the described fluid input of the B runner of three-apexed rotor hydraulic mechanism described in second.
Scheme 45, the motor of three-apexed rotor hydraulic mechanism described in either a program in a kind of application scheme 1 to 19, the described fluid input of described three-apexed rotor hydraulic mechanism, through the pressurized gas outlet of internal combustion firing chamber and volume type rotor gas compressor structure, the communicating passage between described pressurized gas outlet with described internal combustion firing chamber is established in control valve and/or the communicating passage between described internal combustion firing chamber and the described fluid input of described three-apexed rotor hydraulic mechanism and is established control valve.
Scheme 46, on the basis of scheme 45, described control valve is set to timing control valve.
Scheme 47, the motor of three-apexed rotor hydraulic mechanism described in either a program in a kind of application scheme 1 to 19, the described fluid input of described three-apexed rotor hydraulic mechanism, through the pressurized gas outlet of internal combustion firing chamber and volume type rotor gas compressor structure, the communicating passage between described pressurized gas outlet with described internal combustion firing chamber is established in convergent jet pipe and/or the communicating passage between described internal combustion firing chamber and the described fluid input of described three-apexed rotor hydraulic mechanism and is established convergent jet pipe.
In the present invention, described timing control valve opens or closes by the rotatable phase of described volume rotor mechanism.
In the present invention, described convergent jet pipe utilizes congested effect to realize.
In the present invention, the rotation relationship of described three-apexed rotor is determined according to the three-apexed rotor rotation relationship of Wankel RC configuration and/or the three-apexed rotor rotation relationship of modified model Wankel RC configuration, such as: on described three-apexed rotor, establish gear; Described gear and stationary gear engagement, described three-apexed rotor and eccentric shaft are connected or are equipped with eccentric shaft, or with eccentric shaft integrated setting.
In the present invention, so-called " non-contact slipper seal is equipped with " refers to that both do not contact but gap is narrow and small as far as possible, leak to reduce fluid, its concrete size should according to the factor such as material property, machining accuracy, determine according to known technology, the object of this cooperation is the engineering problem avoided contacting with each other and cause, such as: the interference fit that the thermal strain of wear problem, lubrication problem and material and stress deformation cause and form that resistance is excessive, the problem such as excessive of wearing and tearing.
In the present invention, so-called " concavo-convex the block structure " refers to sealing in order to increase the surface that two are matched and the rough structure arranged, and this structure can form larger flow resistance on the direction that fluid may leak.
In the present invention, so-called " depression the block structure " refers to sealing in order to increase the surface that two are matched and the rough structure arranged, and this structure can form larger flow resistance on the direction that fluid may leak.
In the present invention, so-called " seal concavo-convex increasing and hinder line " refers to the sealing in order to increase the surface that two are matched, leak the concavo-convex line that the Vertical direction in direction is arranged at fluid, this structure can form larger flow resistance on the direction that fluid may leak.
In the present invention, so-called " two arc cylindrical cavity " refers to and comprises the cavity that shape line that inwall intersects setting is a part for epitrochoidal two cylindrical shells, and comprising shape line is epitrochoidal cone-shaped cavity.
In the present invention, so-called " two arc cylindrical cavity " is finger-type line is double arc length amplitude outer rotary wheeling line cavity, and comprising shape line is double arc length amplitude outer rotary wheeling line cone-shaped cavity.
In the present invention, so-called " end sealing body " refers to the object of described pair of arc cylindrical cavity end part seal, described end sealing body can be the object being packed in described pair of arc cylindrical cavity end, also can be the object with described pair of arc cylindrical cavity overall processing.
In the present invention, disclosed three-apexed rotor hydraulic mechanism can be used as gas compressor, liquor pump, fluid motor, also can be used as gas expansion for doing work mechanism, such as: motor etc.
In the present invention, so-called " slipper seal rotation " comprises contact slide and is sealed and matched and non-contact slipper seal cooperation, so-called non-contact slipper seal cooperation refers to that two cylndrical surface do not contact but both gaps are narrow and small as far as possible, leak to reduce fluid, its concrete size should according to material property, the factors such as machining accuracy, determine according to known technology, the object of this cooperation is the engineering problem avoided contacting with each other and cause, such as: wear problem, the interference fit that the thermal strain of lubrication problem and material and stress deformation cause and to form resistance excessive, the problem such as to wear and tear excessive.
In the present invention, described engagement comprises contact engagement and non-contact engagement.
In the present invention, so-calledly refer to the unit that working medium is heated by hot cell, comprising: heater, vaporizer etc.
In the present invention, described control valve comprises valve, and described valve comprises external-open valve and Nei Kai valve.
In the present invention, so-called " cooperation " comprises direct cooperation, also comprises the indirect cooperation through other object and/or fluid.
In the present invention, so-called " working medium envelope " refers to that working medium can arrive the set of the wall in space, the wall in the space of the accommodation gas working medium be such as made up of piston, cylinder and cylinder head.Such as, the wall of described vaporizer, also such as, the wall of described communicating passage.
In the present invention, the object arranging convergent jet pipe is the congested effect utilizing convergent jet pipe, and realize described three-apexed rotor hydraulic mechanism when using as power mechanism, the effect of gas working medium puffing in described pair of arc cylindrical cavity, raises the efficiency.
In the present invention, disclosed three-apexed rotor hydraulic mechanism, can use by two or more serial or parallel connections.
In the present invention, in disclosed three-apexed rotor hydraulic mechanism, under the state that described three-apexed rotor rotates, suppose that fluid to be entered in described three-apexed rotor hydraulic mechanism by a fluid input and rotates with described three-apexed rotor and flow, the fluid output run at first is defined as A fluid output, and so-called A runner refers to the runner be made up of A fluid input and A fluid output; In the present invention, so-called A runner and B runner are just defined to distinguish, and do not represent them and have different attribute.
In the present invention, according to the known technology of heat energy and dynamic field, necessary parts, unit or system etc. should be set in the place of necessity.
Beneficial effect of the present invention is as follows:
Structure is simple, reliable, manufacture cost of production is low, efficiency is high.
Accompanying drawing explanation
Shown in Fig. 1 .1 is the structural representation of the embodiment of the present invention 1;
Shown in Fig. 1 .2 is the structural representation of the embodiment of the present invention 1;
Shown in Fig. 2 is the structural representation of the embodiment of the present invention 2;
Shown in Fig. 3 is the structural representation of the embodiment of the present invention 3;
Shown in Fig. 4 is the structural representation of the embodiment of the present invention 4;
Shown in Fig. 5 is the structural representation of the embodiment of the present invention 5;
Shown in Fig. 6 is the structural representation of the embodiment of the present invention 6;
Shown in Fig. 7 is the structural representation of the embodiment of the present invention 7;
Shown in Fig. 8 is the structural representation of the embodiment of the present invention 8;
Shown in Fig. 9 is the structural representation of the embodiment of the present invention 9;
Shown in Figure 10 is the structural representation of the embodiment of the present invention 10;
Shown in Figure 11 is the structural representation of the embodiment of the present invention 11;
Shown in Figure 12 is the structural representation of the embodiment of the present invention 12;
Shown in Figure 13 is the structural representation of the embodiment of the present invention 13;
Shown in Figure 14 is the structural representation of the embodiment of the present invention 14;
Shown in Figure 15 is the structural representation of the embodiment of the present invention 15;
Shown in Figure 16 is the structural representation of the embodiment of the present invention 16;
Shown in Figure 17 is the structural representation of the embodiment of the present invention 17;
Shown in Figure 18 is the structural representation of the embodiment of the present invention 18;
Shown in Figure 19 is the structural representation of the embodiment of the present invention 19;
Shown in Figure 20 is the structural representation of the embodiment of the present invention 20;
Shown in Figure 21 is the structural representation of the embodiment of the present invention 21;
Shown in Figure 22 is the structural representation of the embodiment of the present invention 22;
Shown in Figure 23 is the structural representation of the embodiment of the present invention 23;
Shown in Figure 24 is the structural representation of the embodiment of the present invention 24;
Shown in Figure 25 is the structural representation of the embodiment of the present invention 25;
Shown in Figure 26 is the structural representation of the embodiment of the present invention 26;
Shown in Figure 27 is the structural representation of the embodiment of the present invention 27;
Shown in Figure 28 is the structural representation of the embodiment of the present invention 25;
Shown in Figure 29 is the structural representation of the embodiment of the present invention 26;
Shown in Figure 30 is the structural representation of the embodiment of the present invention 27;
In figure:
1 three-apexed rotor, 101 jiaos of tops, 2 pairs of arc cylindrical cavities, 3 end sealing bodies, 4 fluid inputs, 5 fluid outputs, 6 eccentric shafts, 7 eccentric shaft axis holes, 8 internal gears, 9 static external gears, 10 fluids import control valve, 11 fluids derive control valve, 12 fluid entering channel, 13 fluid outlet passage, 14 sealing concavo-convex increasing resistance line, 15 concavo-convex the block structures, 16 depression the block structures, 17 convergent jet pipes, 18 internal combustion firing chambers, 19 by hot cell, 20 piston gas compressors, 21A runner, 22B runner, 23 coolers, 24 carbon dioxide capture unit, 251 first three-apexed rotor hydraulic mechanism, 252 second three-apexed rotor hydraulic mechanism, 26 working medium export mouths, 27 control valves, 28 volume type rotor gas compressor structures.
Embodiment
Embodiment 1
A kind of three-apexed rotor hydraulic mechanism as shown in Fig. 1 .1, comprise three-apexed rotor 1, described three-apexed rotor 1 is arranged in two arc cylindrical cavity 2, and on the end sealing body 3 of described pair of arc cylindrical cavity 2 and described pair of arc cylindrical cavity 2, correspondence arranges two or more fluid input 4 and two or more fluid output 5 altogether.
The present embodiment in the specific implementation, can optionally be selected, and is arranged on described pair of arc cylindrical cavity 2 by described fluid input 4 and described fluid output 5 correspondence;
Also optionally can select, as are shown in figure 1.2, described fluid input 4 and described fluid output 5 correspondence are arranged on the end sealing body 3 of described pair of arc cylindrical cavity 2.
Embodiment 2
As shown in Figure 2, a kind of three-apexed rotor hydraulic mechanism, the difference of itself and embodiment 1 is, the top, angle 101 of described three-apexed rotor 1 is equipped with the inwall non-contact slipper seal of described pair of arc cylindrical cavity 2.
As the mode of execution that can convert, the top, angle 101 of described three-apexed rotor 1 is equipped with the contact internal walls slipper seal of described pair of arc cylindrical cavity 2.
Embodiment 3
As shown in Figure 3, a kind of three-apexed rotor hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, the side of described three-apexed rotor 1 and the described end sealing body 3 non-contact slipper seal of described pair of arc cylindrical cavity 2 are arranged;
As the mode of execution that can convert, the side of described three-apexed rotor 1 and described end sealing body 3 contact slide of described pair of arc cylindrical cavity 2 seal and arrange.
Embodiment 4
As shown in Figure 4, a kind of three-apexed rotor hydraulic mechanism, in itself and embodiment 1 to 3, the difference of any embodiment is, described three-apexed rotor 1 is connected with eccentric shaft 6, or described three-apexed rotor 1 and described eccentric shaft 6 integrated setting.
Embodiment 5
As shown in Figure 5, a kind of three-apexed rotor hydraulic mechanism, in itself and embodiment 1 to 3, the difference of any embodiment is, described three-apexed rotor 1 establishes eccentric shaft axis hole 7, and described eccentric shaft axis hole 7 is equipped with eccentric shaft 6.
Embodiment 6
As shown in Figure 6, a kind of three-apexed rotor hydraulic mechanism, in itself and embodiment 1 to 3, the difference of any embodiment is, described three-apexed rotor 1 arranges internal gear 8, and described internal gear 8 engages with static external gear 9.
Embodiment 7
As shown in Figure 7, a kind of three-apexed rotor hydraulic mechanism, in itself and embodiment 1 to 6, the difference of any embodiment is, establishes fluid to import control valve 10 at described fluid input 4 place.
Embodiment 8
As shown in Figure 8, a kind of three-apexed rotor hydraulic mechanism, in itself and embodiment 1 to 7, the difference of any embodiment is, establishes fluid to derive control valve 11 at described fluid output 5 place.
Embodiment 9
As shown in Figure 9, a kind of three-apexed rotor hydraulic mechanism, in itself and embodiment 1 to 6, the difference of any embodiment is, described fluid input 4 is communicated with fluid entering channel 12, described fluid entering channel 12 is established fluid import control valve 10.
Embodiment 10
As shown in Figure 10, a kind of three-apexed rotor hydraulic mechanism, in itself and embodiment 1 to 7 or 9, the difference of any embodiment is, described fluid output 5 is communicated with fluid outlet passage 13, described fluid outlet passage 13 is established fluid derive control valve 11.
Embodiment 11
As shown in figure 11, a kind of three-apexed rotor hydraulic mechanism, in itself and embodiment 1 to 10, the difference of any embodiment is, the top, angle 101 of described three-apexed rotor 1 is established concavo-convex increasings of sealing hinder line 14.
Embodiment 12
As shown in figure 12, a kind of three-apexed rotor hydraulic mechanism, in itself and embodiment 1 to 11, the difference of any embodiment is, the inwall of described end sealing body 3 is established concavo-convex the block structure 15.
Embodiment 13
As shown in figure 13, a kind of three-apexed rotor hydraulic mechanism, in itself and embodiment 1 to 11, the difference of any embodiment is, the inwall of described end sealing body 3 is established depression the block structure 16.
Embodiment 14
As shown in figure 14, a kind of three-apexed rotor hydraulic mechanism, in itself and embodiment 1 to 13, the difference of any embodiment is, the end face of described three-apexed rotor 1 is established concavo-convex the block structure 15.
Embodiment 15
As shown in figure 15, a kind of three-apexed rotor hydraulic mechanism, in itself and embodiment 1 to 13, the difference of any embodiment is, the end face of described three-apexed rotor 1 is established depression the block structure 16.
Embodiment 16
As shown in figure 16, the motor of three-apexed rotor hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 15, described fluid input 4 is communicated with internal combustion firing chamber 18.
As the mode of execution that can convert, described fluid input 4 is communicated with compressed gas source;
As the mode of execution that can convert, described fluid input 4 is communicated with mixed-burned gas liquefaction source.
As the mode of execution that can convert, described fluid input 4 is communicated with power fluid body source.
As the mode of execution that can convert, the described fluid input 4 of described three-apexed rotor hydraulic mechanism and the pressurized gas outlet of piston gas compressor 20.
Embodiment 17
As shown in figure 17, a motor for three-apexed rotor hydraulic mechanism described in any embodiment in Application Example 1 to 15, the pressurized gas outlet of described fluid input 4 through internal combustion firing chamber 18 with piston gas compressor 20 of described three-apexed rotor hydraulic mechanism.
Embodiment 18
As shown in figure 18, a motor for three-apexed rotor hydraulic mechanism described in any embodiment in Application Example 1 to 15, the described fluid output 5 of the above three-apexed rotor hydraulic mechanism stands hot cell 19 and is communicated with more than one the described fluid input 4 of three-apexed rotor hydraulic mechanism described in other.
As the mode of execution that can convert, the described fluid output 5 of the above three-apexed rotor hydraulic mechanism is communicated with more than one the described fluid input 4 of three-apexed rotor hydraulic mechanism described in other through internal combustion firing chamber 18.
Embodiment 19
As shown in figure 19, a motor for three-apexed rotor hydraulic mechanism described in any embodiment in Application Example 1 to 15, the described fluid input 4 of described fluid output 5 through internal combustion firing chamber 18 with the B runner 22 of described three-apexed rotor hydraulic mechanism of the A runner 21 of described three-apexed rotor hydraulic mechanism is communicated with.
As the mode of execution that can convert, the described fluid output 5 of the A runner 21 of described three-apexed rotor hydraulic mechanism stands hot cell 19 and is communicated with the described fluid input 4 of the B runner 22 of described three-apexed rotor hydraulic mechanism.
Embodiment 20
As shown in figure 20, the motor of three-apexed rotor hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 15, the described fluid input 4 of described fluid output 5 through internal combustion firing chamber 18 with the B runner 22 of described three-apexed rotor hydraulic mechanism of the A runner 21 of described three-apexed rotor hydraulic mechanism is communicated with, and the described fluid output 5 of described B runner 22 is communicated with through the described fluid input 4 of cooler 23 with described A runner 21.
In the present embodiment, optionally can select, the cycle fluid in described three-apexed rotor hydraulic mechanism, internal combustion firing chamber 18 and described cooler 23 and communicating passage thereof is set to helium.
As the mode of execution that can select, the described internal combustion firing chamber 18 in the present embodiment can be changed and be set to by hot cell 19.
Embodiment 21
As shown in figure 21, the motor of three-apexed rotor hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 15, the difference of itself and embodiment 20 is, the working medium envelope of described three-apexed rotor hydraulic mechanism, described internal combustion firing chamber 18, described cooler 23 and communicating passage thereof establishes carbon dioxide capture unit 24, described carbon dioxide capture unit 24 catches the carbon dioxide in working medium, reduces carbon dioxide content in working medium.
Embodiment 22
As shown in figure 22, the motor of three-apexed rotor hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 15, the difference of itself and embodiment 20 or 21 is, the working medium envelope comprising described three-apexed rotor hydraulic mechanism, internal combustion firing chamber 18 and described cooler 23 and communicating passage thereof establishes working medium export mouth 26.
Embodiment 23
As shown in figure 23, the motor of three-apexed rotor hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 15, the described fluid input 4 of described fluid output 5 through internal combustion firing chamber 18 with the B runner 22 of three-apexed rotor hydraulic mechanism 251 described in first of the A runner 21 of three-apexed rotor hydraulic mechanism 251 described in first is communicated with, the described fluid output 5 of the B runner 22 of three-apexed rotor hydraulic mechanism 251 described in first is communicated with the described fluid input 4 of the B runner 22 of three-apexed rotor hydraulic mechanism 252 described in second, the described fluid output 5 of the B runner 22 of three-apexed rotor hydraulic mechanism 252 described in second is communicated with through the described fluid input 4 of cooler 23 with the A runner 21 of three-apexed rotor hydraulic mechanism 252 described in second, the described fluid output 5 of the A runner 21 of three-apexed rotor hydraulic mechanism 252 described in second is communicated with the described fluid input 4 of the A runner 21 of three-apexed rotor hydraulic mechanism 251 described in first.
In the present embodiment, optionally can select, the cycle fluid in three-apexed rotor hydraulic mechanism 252, described internal combustion firing chamber 18 and described cooler 23 described in three-apexed rotor hydraulic mechanism described in first 251, second and communicating passage thereof is set to helium.
As the mode of execution that can convert, the described internal combustion firing chamber 18 in the present embodiment can be changed and be set to by hot cell 19.
Embodiment 24
As shown in figure 24, the motor of three-apexed rotor hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 15, the difference of itself and embodiment 23 is, the working medium envelope comprising described in first three-apexed rotor hydraulic mechanism 252 described in three-apexed rotor hydraulic mechanism 251, second, described internal combustion firing chamber 18 and described cooler 23 and communicating passage thereof establishes working medium export mouth 26.
Embodiment 25
As shown in figure 25, the motor of three-apexed rotor hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 15, the difference of itself and embodiment 23 or 24 is, the working medium envelope comprising described in first three-apexed rotor hydraulic mechanism 252 described in three-apexed rotor hydraulic mechanism 251, second, described internal combustion firing chamber 18 and described cooler 23 and communicating passage thereof establishes carbon dioxide capture unit 24, described carbon dioxide capture unit 24 catches the carbon dioxide in working medium, reduces carbon dioxide content in working medium.
Embodiment 26
As shown in figure 26, the motor of three-apexed rotor hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 15, three the above three-apexed rotor hydraulic mechanism, an internal combustion firing chamber 18 and at least one cooler 23 are interconnected.
Embodiment 27
As shown in figure 27, the motor of three-apexed rotor hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 15, three the above three-apexed rotor hydraulic mechanism, one is interconnected by hot cell 19 and at least one cooler 23.
Embodiment 28
As shown in figure 28, the motor of three-apexed rotor hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 15, the described fluid input 4 of described fluid output 5 through internal combustion firing chamber 18 with the B runner 22 of three-apexed rotor hydraulic mechanism 251 described in first of the A runner 21 of three-apexed rotor hydraulic mechanism 251 described in first is communicated with, and the described fluid output 5 of the B runner 22 of three-apexed rotor hydraulic mechanism 251 described in first is communicated with the described fluid input 4 of the B runner 22 of three-apexed rotor hydraulic mechanism 252 described in second.
Embodiment 29
As shown in figure 29, the motor of three-apexed rotor hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 15, the pressurized gas outlet of described fluid input 4 through internal combustion firing chamber 18 with volume type rotor gas compressor structure 28 of described three-apexed rotor hydraulic mechanism, the communicating passage between described pressurized gas outlet and described internal combustion firing chamber 28 is established in control valve 27 and/or the communicating passage between described internal combustion firing chamber 28 and the described fluid input 4 of described three-apexed rotor hydraulic mechanism and establishes control valve 27.
Optionally can select, described control valve 27 is set to timing control valve.
Embodiment 30
As shown in figure 30, the motor of three-apexed rotor hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 15, the described fluid input 4 of described three-apexed rotor hydraulic mechanism, through the pressurized gas outlet of internal combustion firing chamber and volume type rotor gas compressor structure 28, the communicating passage between described pressurized gas outlet with described internal combustion firing chamber is established in convergent jet pipe 17 and/or the communicating passage between described internal combustion firing chamber and the described fluid input 4 of described three-apexed rotor hydraulic mechanism and is established convergent jet pipe 17.
Described fluid input 4 in the specific implementation, is all optionally set to convergent jet pipe 17 by all mode of executions in the present invention.
Obviously, the invention is not restricted to above embodiment, according to known technology and the technological scheme disclosed in this invention of related domain, can to derive or association goes out many flexible programs, all these flexible programs, also should think protection scope of the present invention.
Claims (10)
1. a three-apexed rotor hydraulic mechanism, comprise three-apexed rotor (1), it is characterized in that: described three-apexed rotor (1) is arranged in two arc cylindrical cavity (2), on the end sealing body (3) of described pair of arc cylindrical cavity (2) and described pair of arc cylindrical cavity (2), correspondence arranges two or more fluid input (4) and two or more fluid output (5) altogether.
2. three-apexed rotor hydraulic mechanism as claimed in claim 1, is characterized in that: described fluid input (4) and described fluid output (5) correspondence are arranged on the upper or correspondence of described pair of arc cylindrical cavity (2) and are arranged on the end sealing body (3) of described pair of arc cylindrical cavity (2).
3. three-apexed rotor hydraulic mechanism as claimed in claim 1, is characterized in that: the top, angle (101) of described three-apexed rotor (1) and the contact internal walls slipper seal of described pair of arc cylindrical cavity (2) are equipped with.
4. three-apexed rotor hydraulic mechanism as claimed in claim 1, is characterized in that: the top, angle (101) of described three-apexed rotor (1) and the inwall non-contact slipper seal of described pair of arc cylindrical cavity (2) are equipped with.
5. three-apexed rotor hydraulic mechanism as claimed in claim 1, is characterized in that: described three-apexed rotor (1) and eccentric shaft (6) are connected, or described three-apexed rotor (1) and described eccentric shaft (6) integrated setting.
6. three-apexed rotor hydraulic mechanism as claimed in claim 1, is characterized in that: on described three-apexed rotor (1), establish eccentric shaft axis hole (7), and described eccentric shaft axis hole (7) and eccentric shaft (6) are equipped with.
7. three-apexed rotor hydraulic mechanism as claimed in claim 1, it is characterized in that: on described three-apexed rotor (1), arrange internal gear (8), described internal gear (8) engages with static external gear (9).
8. three-apexed rotor hydraulic mechanism as claimed in claim 1, is characterized in that: the side of described three-apexed rotor (1) and described end sealing body (3) the non-contact slipper seal of described pair of arc cylindrical cavity (2) are arranged.
9. three-apexed rotor hydraulic mechanism as claimed in claim 1, is characterized in that: the side of described three-apexed rotor (1) and described end sealing body (3) contact slide of described pair of arc cylindrical cavity (2) seal and arrange.
10. the motor of three-apexed rotor hydraulic mechanism according to any one of an application rights requirement 1 to 9, it is characterized in that: the described fluid input (4) of described fluid output (5) through internal combustion firing chamber (18) with the B runner (22) of described three-apexed rotor hydraulic mechanism of the A runner (21) of described three-apexed rotor hydraulic mechanism is communicated with, the described fluid output (5) of described B runner (22) is communicated with through the described fluid input (4) of cooler (23) with described A runner (21).
Priority Applications (1)
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CN201410476114.3A CN104234826A (en) | 2013-09-17 | 2014-09-17 | Triangular rotor fluid mechanism and engine adopting triangular rotor fluid mechanism |
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CN201310423812.2 | 2013-09-17 | ||
CN201310423812 | 2013-09-17 | ||
CN201310427132.8 | 2013-09-18 | ||
CN201310427132 | 2013-09-18 | ||
CN201310431512.9 | 2013-09-22 | ||
CN201310431512 | 2013-09-22 | ||
CN201310531436.9 | 2013-11-01 | ||
CN201310531436 | 2013-11-01 | ||
CN201410476114.3A CN104234826A (en) | 2013-09-17 | 2014-09-17 | Triangular rotor fluid mechanism and engine adopting triangular rotor fluid mechanism |
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CN104653233A (en) * | 2015-02-12 | 2015-05-27 | 梁运富 | Cylinder-type high-pressure gas engine |
CN105424892A (en) * | 2015-12-23 | 2016-03-23 | 山东大学 | Intelligent grouting test system based on triangle rotor grouting pump and test method thereof |
CN110282108A (en) * | 2019-07-02 | 2019-09-27 | 哈尔滨工程大学 | A kind of hydraulic jet propulsion system of three-apexed rotor |
CN114888627A (en) * | 2022-07-11 | 2022-08-12 | 江苏沛泽机械科技有限公司 | Machine tool cooling liquid circulating device |
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Application publication date: 20141224 |