CN104405448A - Fluid mechanism and engine using the same - Google Patents

Abstract

The invention discloses a fluid mechanism, including a gear A and a gear B. The gear A includes a tooth C and a tooth B, the gear B includes the tooth C and the tooth B, the top tooth is the radius of the circle of the tooth top C is larger than the radius of the circle of the tooth top B, the gear A and the gear B are arranged in a double cylindrical cavity, and the gear A and the gear B are mutually meshed rotating arrangement. The fluid mechanism disclosed by the invention and an engine using the same have the advanategs of simple structure, reliability, low manufacturing cost and high efficiency.

Description

Hydraulic mechanism and apply its motor

Technical field

The present invention relates to heat energy and dynamic field, especially a kind of hydraulic mechanism and apply its motor.

Background technique

Many types of traditional 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 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 hydraulic mechanism, comprise gear A and gear B, described gear A comprises C tooth and B tooth, described gear B comprises described C tooth and described B tooth, the tooth top place radius of a circle of described C tooth is greater than the tooth top place radius of a circle of described B tooth, and described gear A and described gear B are arranged in double cylinder-shaped cavity, and described gear A and described gear B engage each other rotary setting.

Scheme 2, a kind of hydraulic mechanism, comprise gear A and gear B, described gear A comprises C tooth and B tooth, described gear B comprises described C tooth and described B tooth, the tooth top place radius of a circle of described C tooth is greater than the tooth top place radius of a circle of described B tooth, described gear A and described gear B are arranged in double cylinder-shaped cavity, described gear A and described gear B engage each other rotary setting, the inwall slipper seal of the circular cylindrical chamber at gear A place described in the described C tooth of described gear A and described double cylinder-shaped cavity is equipped with, the inwall slipper seal of the circular cylindrical chamber at gear B place described in the described C tooth of described gear B and described double cylinder-shaped cavity is equipped with, the inner side rotary seal of the end sealing body of described gear A and described gear B and described double cylinder-shaped cavity is equipped with, fluid input is established on described double cylinder-shaped cavity and/or on described end sealing body, fluid output is established on described double cylinder-shaped cavity and/or on described end sealing body.

Scheme 3, on the basis of scheme 1 or 2, described gear A is adjoined and arranges C tooth described in two or more, described gear B is adjoined and arranges C tooth described in two or more.

Scheme 4, on the basis of scheme 1 or 2, in described gear A, non-contiguous arranges C tooth described in two or more, and in described gear B, non-contiguous arranges C tooth described in two or more.

Scheme 5, on the basis of scheme 1 or 2, in described gear A, angle is that at least two positions of 180 degree arrange described C tooth, and in described gear B, angle is that at least two positions of 180 degree arrange described C tooth.

Scheme 6, on the basis of scheme 1 or 2, in described gear A, angle is that at least two positions of 120 degree arrange described C tooth, and in described gear B, angle is that at least two positions of 120 degree arrange described C tooth.

Scheme 7, on the basis of scheme 1 or 2, in described gear A, angle is that at least two positions of 90 degree arrange described C tooth, and in described gear B, angle is that at least two positions of 90 degree arrange described C tooth.

Scheme 8, on the basis of scheme 1 or 2, in described gear A, angle is that at least two positions of 45 degree arrange described C tooth, and in described gear B, angle is that at least two positions of 45 degree arrange described C tooth.

Scheme 9, on the basis of scheme 1 or 2, in described gear A, angle is that at least two positions of 60 degree arrange described C tooth, and in described gear B, angle is that at least two positions of 60 degree arrange described C tooth.

Scheme 10, on the basis of scheme 1 or 2, the number of the described C tooth in described gear A is set to six, and the central angle between adjacent two described C teeth is 60 degree, the number of the described C tooth in described gear B is set to six, and the central angle between adjacent two described C teeth is 60 degree.

Scheme 11, on the basis of scheme 1 or 2, establishes fluid to import control valve at the fluid input place of described hydraulic mechanism.

Scheme 12, on the basis of scheme 1 or 2, establishes fluid to derive control valve at the fluid outlet of described hydraulic mechanism.

Scheme 13, on the basis of scheme 1 or 2, the fluid input of described hydraulic mechanism is communicated with fluid entering channel, described fluid entering channel is established fluid import control valve.

Scheme 14, on the basis of scheme 1 or 2, the fluid output of described hydraulic mechanism is communicated with fluid outlet passage, described fluid outlet passage is established fluid derive control valve.

Scheme 15, on the basis of scheme 1 or 2, along the pivotal axial direction of described C tooth being established sealing concavo-convex increasing resistance line on the tooth top of described C tooth.

Scheme 16, on the basis of scheme 2, the inwall of described end sealing body is established concavo-convex the block structure.

Scheme 17, on the basis of scheme 1 or 2, the end face of described gear A establishes concavo-convex the block structure.

Scheme 18, on the basis of scheme 1 or 2, the end face of described gear B establishes concavo-convex the block structure.

Scheme 19, on the basis of scheme 2, the inwall of described end sealing body is established depression the block structure.

Scheme 20, on the basis of scheme 1 or 2, the end face of described gear A is established depression the block structure.

Scheme 21, on the basis of scheme 1 or 2, the end face of described gear B is established depression the block structure.

Scheme 22, in scheme 1 to 21 either a program basis on, described gear A and gear A A is coaxial is connected, described gear B and gear B B is coaxial is connected, described gear A A and described gear B B contacts with each other engagement.

Scheme 23, in scheme 1 to 22 either a program basis on, the equal diameters of described gear A and described gear B or both become integral multiple relation.

Scheme 24, in scheme 1 to 22 either a program basis on, the equal diameters of described gear A and described gear B.

Scheme 25, in scheme 1 to 22 either a program basis on, the diameter of described gear A and described gear B is not etc.

Scheme 26, in scheme 1 to 25 either a program basis on, the fluid input of described hydraulic mechanism is set to convergent jet pipe.

Scheme 27, in scheme 1 to 26 either a program basis on, described hydraulic mechanism also comprises attached cylindrical body, described attached cylindrical body is crossing with described double cylinder-shaped cavity inner wall to be arranged, in described attached cylindrical body, attached gear is set, described attached gear arranges attached B tooth and attached C tooth, the tooth top place radius of a circle of described attached C tooth is greater than the tooth top place radius of a circle of described attached B tooth, described attached gear and described gear A and/or described gear B engage each other rotary setting, the tooth top of the described attached C tooth on described attached gear and the inwall slipper seal of described attached cylindrical body are equipped with.

Scheme 28, in scheme 1 to 27 either a program basis on, described gear A and/or described gear B establish D tooth, and the tooth top place radius of a circle of described D tooth is between described B tooth and described C tooth.

Scheme 29 1 kinds applies the motor of hydraulic mechanism described in either a program in such scheme 1 to 28, the fluid input of described hydraulic mechanism and combustion chamber.

Scheme 30 1 kinds applies the motor of hydraulic mechanism described in either a program in such scheme 1 to 28, and the fluid input of described hydraulic mechanism is communicated with compressed gas source.

Scheme 31 1 kinds applies the motor of hydraulic mechanism described in either a program in such scheme 1 to 28, and the fluid input of described hydraulic mechanism is communicated with mixed-burned gas liquefaction source.

Scheme 32 1 kinds applies the motor of hydraulic mechanism described in either a program in such scheme 1 to 28, and the fluid input of described hydraulic mechanism is communicated with power fluid body source.

Scheme 33 1 kinds applies the motor of hydraulic mechanism described in either a program in such scheme 1 to 28, and the fluid output of the above hydraulic mechanism stands hot cell and is communicated with more than one fluid input of hydraulic mechanism described in other.

Scheme 34 1 kinds applies the motor of hydraulic mechanism described in either a program in such scheme 1 to 28, the fluid input of described hydraulic mechanism and the pressurized gas outlet of piston gas compressor.

Scheme 35 1 kinds applies the motor of hydraulic mechanism described in either a program in such scheme 1 to 28, and the fluid input of described hydraulic mechanism is through the pressurized gas outlet of firing chamber and piston gas compressor.

Scheme 36 1 kinds applies the motor of hydraulic mechanism described in either a program in such scheme 1 to 28, the fluid input of described hydraulic mechanism, through the pressurized gas outlet of firing chamber and volume type rotor gas compressor structure, the communicating passage between described pressurized gas outlet with described firing chamber is established in control valve and/or the communicating passage between described firing chamber and the fluid input of described hydraulic mechanism and is established control valve.

Scheme 37, on the basis of scheme 36, described control valve is set to timing control valve.

Scheme 38 1 kinds applies the motor of hydraulic mechanism described in either a program in such scheme 1 to 28, the fluid input of described hydraulic mechanism, through the pressurized gas outlet of firing chamber and volume type rotor gas compressor structure, the communicating passage between described pressurized gas outlet with described firing chamber is established in convergent jet pipe and/or the communicating passage between described firing chamber and the fluid input of described hydraulic mechanism and is established convergent jet pipe.

In the present invention, so-called " being connected " refers to and is fixedly connected with setting, comprises the mode of structure of two or more parts through a componentization of global formation.

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, 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 " double cylinder-shaped cavity " refers to the cavity comprising inwall and intersect a part for two circular cylinder bodies of setting, and wherein, cylinder can be tapered cylinder.

In the present invention, so-called " double cylinder-shaped cavity " refers to and is arranged by the prerequisite downcrossings of two cylindrical cavities at axis being parallel, namely meeting is arranged on an A by the center of cylinder A, the center of cylinder B is arranged on a B, distance between A and B is less than the geometrical relationship of the radius of cylinder A and the radius sum of cylinder B, removes the cavity that interface portion is formed.

In the present invention, so-called " end sealing body " refers to the object of described double cylinder-shaped cavity end part seal, described end sealing body can be the object being packed in described double cylinder-shaped cavity end, also can be the object with described double cylinder-shaped cavity overall processing.

In the present invention, so-called " slipper seal cooperation " refers to and comprises traditional slipper seal (i.e. contact-type slipper seal) and non-contact suspending sealing, so-called non-contact suspending sealing 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 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, disclosed 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 " by hot cell " refers to the unit heated working medium, comprising: firing chamber, heater, vaporizer etc.

In the present invention, described engagement comprises contact engagement, non-contact engagement and plugs together, described plugging together refers to that non-profile of tooth does not contact, mismatches but the corresponding relation of all rotatable two solid of rotation more than 360 degree of mutual noninterference, in this corresponding relation, the sunk part on a solid of rotation is greater than the convex portion on another solid of rotation.

In the present invention, described engagement rotation comprises contact engagement, non-contact engagement and plugs together rotation, described plug together to rotate refer to that non-profile of tooth does not contact, mismatch but the corresponding relation of all rotatable two solid of rotation more than 360 degree of mutual noninterference, in this corresponding relation, the sunk part on a solid of rotation is greater than the convex portion on another solid of rotation.

In the present invention, so-called " contact engagement " can be directly contact engagement, also can be through the contact engagement of other gear.

In the present invention, described gear A and described gear B are the definition provided to distinguish two roulette wheels, and which does not represent, and large which is little, and which does not represent yet, and preferential which is delayed.

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, the object arranging convergent jet pipe is the congested effect utilizing convergent jet pipe, and realize described hydraulic mechanism when using as power mechanism, the effect of gas working medium puffing in described double cylinder-shaped cavity, raises the efficiency.

In the present invention, disclosed hydraulic mechanism, can use by two or more serial or parallel connections.

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 is the structural representation of the embodiment of the present invention 1;

Shown in Fig. 2 .1 is the structural representation of the embodiment of the present invention 2;

Shown in Fig. 2 .2 is the structural representation of the embodiment of the present invention 2;

Shown in Fig. 2 .3 is the structural representation of the embodiment of the present invention 2;

Shown in Fig. 2 .4 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;

In figure:

1 gear A, 101 gear A A, 2 gear B, 202 gear B B, 3 C teeth, 31 attached C teeth, 4 B teeth, 41 attached B teeth, 5 double cylinder-shaped cavitys, 51 attached cylindrical bodys, 6 end sealing bodies, 7 fluid inputs, 8 fluid outputs, 9 fluids import control valve, 10 fluids derive control valve, 11 fluid entering channel, 12 fluid outlet passage, 13 sealing concavo-convex increasing resistance line, 14 concavo-convex the block structures, 15 depression the block structures, 16 convergent jet pipes, 17 attached gears, 18 D teeth, 19 firing chambers, 20 by hot cell, 21 piston gas compressors, 22 volume type rotor gas compressor structures, 23 control valves.

Embodiment

Embodiment 1

As shown in Figure 1, a kind of hydraulic mechanism, comprise gear A 1 and gear B 2, described gear A 1 comprises C tooth 3 and B tooth 4, described gear B 2 comprises described C tooth 3 and described B tooth 4, the tooth top place radius of a circle of described C tooth 3 is greater than the tooth top place radius of a circle of described B tooth 4, and described gear A 1 and described gear B 2 are arranged in double cylinder-shaped cavity 5, and described gear A 1 and described gear B 2 engage each other rotary setting.

Embodiment 2

As shown in Fig. 2 .1 to Fig. 2 .4, a kind of hydraulic mechanism, comprise gear A 1 and gear B 2, described gear A 1 comprises C tooth 3 and B tooth 4, described gear B 2 comprises described C tooth 3 and described B tooth 4, the tooth top place radius of a circle of described C tooth 3 is greater than the tooth top place radius of a circle of described B tooth 4, described gear A 1 and described gear B 2 are arranged in double cylinder-shaped cavity 5, described gear A 1 and described gear B 2 engage each other rotary setting, the described C tooth 3 of described gear A 1 is equipped with the inwall slipper seal of the circular cylindrical chamber at gear A 1 place described in described double cylinder-shaped cavity 5, the described C tooth 3 of described gear B 2 is equipped with the inwall slipper seal of the circular cylindrical chamber at gear B 2 place described in described double cylinder-shaped cavity 5, described gear A 1 and described gear B 2 are equipped with the inner side rotary seal of the end sealing body 6 of described double cylinder-shaped cavity 5, fluid input 7 is established on described double cylinder-shaped cavity 5 and/or on described end sealing body 6, fluid output 8 is established on described double cylinder-shaped cavity 5 and/or on described end sealing body 6.

Embodiment 3

As shown in Figure 3, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, described gear A 1 is adjoined and arranges C tooth 3 described in two or more, described gear B 2 is adjoined and arranges C tooth 3 described in two or more.

In the present invention, all mode of executions in the specific implementation, all can refer to the present embodiment and adjoin in described gear A 1 and arrange C tooth 3 described in two or more, described gear B 2 is adjoined and arranges C tooth 3 described in two or more.

Embodiment 4

As shown in Figure 4, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, in described gear A 1, non-contiguous arranges C tooth 3 described in two or more, and in described gear B 2, non-contiguous arranges C tooth 3 described in two or more.

In the present invention, all mode of executions in the specific implementation, and all can refer to the present embodiment non-contiguous in described gear A 1 and arrange C tooth 3 described in two or more, in described gear B 2, non-contiguous arranges C tooth 3 described in two or more.

Embodiment 5

As shown in Figure 5, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, in described gear A 1, angle is that at least two positions of 180 degree arrange described C tooth 3, and in described gear B 2, angle is that at least two positions of 180 degree arrange described C tooth 3.

Embodiment 6

As shown in Figure 6, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, in described gear A 1, angle is that at least two positions of 120 degree arrange described C tooth 3, and in described gear B 2, angle is that at least two positions of 120 degree arrange described C tooth 3.

Embodiment 7

As shown in Figure 7, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, in described gear A 1, angle is that at least two positions of 90 degree arrange described C tooth 3, and in described gear B 2, angle is that at least two positions of 90 degree arrange described C tooth 3.

Embodiment 8

As shown in Figure 8, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, in described gear A 1, angle is that at least two positions of 45 degree arrange described C tooth, and in described gear B 2, angle is that at least two positions of 45 degree arrange described C tooth.

Embodiment 9

A kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, in described gear A 1, angle is that at least two positions of 60 degree arrange described C tooth, and in described gear B 2, angle is that at least two positions of 60 degree arrange described C tooth.

Preferably, as shown in Figure 9, the number of the described C tooth 3 in described gear A 1 is set to six, and the central angle between adjacent two described C teeth 3 is 60 degree, the number of the described C tooth 3 in described gear B 2 is set to six, and the central angle between adjacent two described C teeth 3 is 60 degree.

Embodiment 10

As shown in Figure 10, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, establishes fluid to import control valve 9 at fluid input 7 place of described hydraulic mechanism.

In the present invention, all mode of executions in the specific implementation, all can refer to the present embodiment, optionally select, and establish fluid to import control valve 9 at fluid input 7 place of described hydraulic mechanism.

Embodiment 11

As shown in figure 11, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, establishes fluid to derive control valve 10 at fluid output 8 place of described hydraulic mechanism.

In the present invention, all mode of executions in the specific implementation, all can refer to the present embodiment, optionally select, and establish fluid to derive control valve 10 at fluid output 8 place of described hydraulic mechanism.

Embodiment 12

As shown in figure 12, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, the fluid input 7 of described hydraulic mechanism is communicated with fluid entering channel 11, described fluid entering channel 11 is established fluid import control valve 9.

In the present invention, all mode of executions in the specific implementation, all can refer to the present embodiment, optionally select, and the fluid input 7 of described hydraulic mechanism is communicated with fluid entering channel 11, described fluid entering channel 11 are established fluid import control valve 9.

Embodiment 13

As shown in figure 13, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, the fluid output 8 of described hydraulic mechanism is communicated with fluid outlet passage 12, described fluid outlet passage 12 is established fluid derive control valve 10.

In the present invention, all mode of executions in the specific implementation, all can refer to the present embodiment, optionally select, and the fluid output 8 of described hydraulic mechanism is communicated with fluid outlet passage 12, described fluid outlet passage 12 are established fluid derive control valve 10.

Embodiment 14

As shown in figure 14, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, along the pivotal axial direction of described C tooth 3 being established concavo-convex increasings of sealing hinder line 13 on the tooth top of described C tooth 3.

In the present invention, all mode of executions in the specific implementation, all can refer to the present embodiment on the tooth top of described C tooth 3 along the pivotal axial direction of described C tooth 3 being established sealing concavo-convex increasing resistance line 13.

Embodiment 15

As shown in figure 15, a kind of hydraulic mechanism, the difference of itself and embodiment 2 is, the inwall of described end sealing body 6 is established concavo-convex the block structure 14.

Allly in the present invention be provided with in the mode of execution of end sealing body 6, all optionally select on the inwall of described end sealing body 6, establish concavo-convex the block structure 14.

Embodiment 16

As shown in figure 16, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, the end face of described gear A 1 is established concavo-convex the block structure 14.

As the mode of execution that can convert, optionally can select, on the end face of described gear A 1 and/or on the end face of described gear B 2, establish concavo-convex the block structure 14.

In the present invention, all mode of executions in the specific implementation, all can refer to the present embodiment, optionally select to establish concavo-convex the block structure 14 on the end face of described gear A 1 and/or on the end face of described gear B 2.

Embodiment 17

As shown in figure 17, a kind of hydraulic mechanism, the difference of itself and embodiment 2 is, the inwall of described end sealing body 6 is established depression the block structure 15.

Allly in the present invention be provided with in the mode of execution of end sealing body 6, all optionally select on the inwall of described end sealing body 6, establish depression the block structure 15.

Embodiment 18

As shown in figure 18, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, the end face of described gear A 1 is established depression the block structure 15.

As the mode of execution that can convert, optionally can select, on the end face of described gear A 1 and/or on the end face of described gear B 2, establish depression the block structure 15.

In the present invention, all mode of executions in the specific implementation, all can refer to the present embodiment, optionally select on the end face of described gear A 1 and/or on the end face of described gear B 2, establish depression the block structure 15.

Embodiment 19

As shown in figure 19, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, described gear A 1 is connected with gear A A101 is coaxial, and described gear B 2 is connected with gear B B202 is coaxial, and described gear A A101 and described gear B B202 contacts with each other engagement.

Embodiment 20

As shown in figure 20, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, described hydraulic mechanism also comprises attached cylindrical body 51, described attached cylindrical body 51 is crossing with described double cylinder-shaped cavity 5 inwall to be arranged, in described attached cylindrical body 51, attached gear 17 is set, described attached gear 17 arranges attached B tooth 41 and attached C tooth 31, the tooth top place radius of a circle of described attached C tooth 31 is greater than the tooth top place radius of a circle of described attached B tooth 41, described attached gear 17 engages each other rotary setting with described gear A 1 and/or described gear B 2, the tooth top of the described attached C tooth 31 on described attached gear 17 and the inwall slipper seal of described attached cylindrical body 51 are equipped with.

Embodiment 21

As shown in figure 21, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, described gear A 1 and/or described gear B 2 establish D tooth 18, and the tooth top place radius of a circle of described D tooth 18 is between described B tooth 4 and described C tooth 3.

In the present invention, all mode of executions in the specific implementation, all can refer to the present embodiment, and described gear A 1 and/or described gear B 2 establish D tooth 18, and the tooth top place radius of a circle of described D tooth 18 is between described B tooth 4 and described C tooth 3.

Embodiment 22

As shown in figure 22, a kind of hydraulic mechanism, the difference of itself and embodiment 1 or 2 is, the fluid input 7 of described hydraulic mechanism is set to convergent jet pipe 16.

Embodiment 23

As shown in figure 23, the motor of hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 22, the fluid input 7 of described hydraulic mechanism is communicated with firing chamber 19;

As the mode of execution that can convert, the fluid input 7 of described hydraulic mechanism is communicated with compressed gas source;

As the mode of execution that can convert, the fluid input 7 of described hydraulic mechanism is communicated with mixed-burned gas liquefaction source;

As the mode of execution that can convert, the fluid input 7 of described hydraulic mechanism is communicated with power fluid body source;

As the mode of execution that can convert, the fluid input 7 of described hydraulic mechanism and the pressurized gas outlet of piston gas compressor.

Embodiment 24

As shown in figure 24, the motor of hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 22, the fluid output 8 of the above hydraulic mechanism stands hot cell 20 and is communicated with more than one fluid input 7 of hydraulic mechanism described in other.

Embodiment 25

As shown in figure 25, the motor of hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 22, the pressurized gas outlet of fluid input 7 through firing chamber 19 with piston gas compressor 21 of described hydraulic mechanism.

Embodiment 26

As shown in figure 26, the motor of hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 22, the pressurized gas outlet of fluid input 7 through firing chamber 19 with volume type rotor gas compressor structure 22 of described hydraulic mechanism, communicating passage between the outlet of described pressurized gas with described firing chamber 19 establishes control valve 23, and/or communicating passage between described firing chamber 19 and the fluid input 7 of described hydraulic mechanism establishes control valve 23.

Optionally select in the present embodiment, described control valve 23 is set to timing control valve.

Embodiment 27

As shown in figure 27, the motor of hydraulic mechanism described in any embodiment in a kind of Application Example 1 to 22, the pressurized gas outlet of fluid input 7 through firing chamber 19 with volume type rotor gas compressor structure 22 of described hydraulic mechanism, the communicating passage between described pressurized gas outlet and described firing chamber is established in convergent jet pipe 16 and/or the communicating passage between described firing chamber and the described fluid input 7 of described hydraulic mechanism and establishes convergent jet pipe 16.

In the present invention, all mode of executions in the specific implementation, are all optionally arranged, and make the equal diameters of described gear A 1 and described gear B 2 or make both become integral multiple relation; Or the diameter making described gear A 1 and described gear B 2 is not etc.

In the present invention, all mode of executions in the specific implementation, all optionally, the fluid input 7 of described hydraulic mechanism is set to convergent jet pipe.

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 hydraulic mechanism, comprise gear A (1) and gear B (2), it is characterized in that: described gear A (1) comprises C tooth (3) and B tooth (4), described gear B (2) comprises described C tooth (3) and described B tooth (4), the tooth top place radius of a circle of described C tooth (3) is greater than the tooth top place radius of a circle of described B tooth (4), described gear A (1) and described gear B (2) are arranged in double cylinder-shaped cavity (5), and described gear A (1) and described gear B (2) engage each other rotary setting.

2. a hydraulic mechanism, comprise gear A (1) and gear B (2), it is characterized in that: described gear A (1) comprises C tooth (3) and B tooth (4), described gear B (2) comprises described C tooth (3) and described B tooth (4), the tooth top place radius of a circle of described C tooth (3) is greater than the tooth top place radius of a circle of described B tooth (4), described gear A (1) and described gear B (2) are arranged in double cylinder-shaped cavity (5), described gear A (1) and described gear B (2) engage each other rotary setting, the described C tooth (3) of described gear A (1) is equipped with the inwall slipper seal of the circular cylindrical chamber at gear A (1) place described in described double cylinder-shaped cavity (5), the described C tooth (3) of described gear B (2) is equipped with the inwall slipper seal of the circular cylindrical chamber at gear B (2) place described in described double cylinder-shaped cavity (5), described gear A (1) and described gear B (2) are equipped with the inner side rotary seal of the end sealing body (6) of described double cylinder-shaped cavity (5), go up described double cylinder-shaped cavity (5) and/or establish fluid input (7) on described end sealing body (6), go up described double cylinder-shaped cavity (5) and/or establish fluid output (8) on described end sealing body (6).

3. hydraulic mechanism as claimed in claim 1 or 2, it is characterized in that: adjoin in described gear A (1) and C tooth (3) described in two or more is set, described gear B (2) is adjoined C tooth (3) described in two or more is set.

4. hydraulic mechanism as claimed in claim 1 or 2, it is characterized in that: C tooth (3) described in two or more is set in described gear A (1) upper non-contiguous, C tooth (3) described in two or more is set in described gear B (2) upper non-contiguous.

5. hydraulic mechanism as claimed in claim 1 or 2, it is characterized in that: be that at least two positions of 180 degree arrange described C tooth (3) at the upper angle of described gear A (1), is that at least two positions of 180 degree arrange described C tooth (3) at the upper angle of described gear B (2).

6. hydraulic mechanism as claimed in claim 1 or 2, it is characterized in that: be that at least two positions of 120 degree arrange described C tooth (3) at the upper angle of described gear A (1), is that at least two positions of 120 degree arrange described C tooth (3) at the upper angle of described gear B (2).

7. hydraulic mechanism as claimed in claim 1 or 2, it is characterized in that: be that at least two positions of 90 degree arrange described C tooth (3) at the upper angle of described gear A (1), is that at least two positions of 90 degree arrange described C tooth (3) at the upper angle of described gear B (2).

8. hydraulic mechanism as claimed in claim 1 or 2, it is characterized in that: be that at least two positions of 45 degree arrange described C tooth at the upper angle of described gear A (1), is that at least two positions of 45 degree arrange described C tooth at the upper angle of described gear B (2).

9. hydraulic mechanism as claimed in claim 1 or 2, it is characterized in that: be that at least two positions of 60 degree arrange described C tooth at the upper angle of described gear A (1), is that at least two positions of 60 degree arrange described C tooth at the upper angle of described gear B (2).

10. the motor of hydraulic mechanism according to any one of an application rights requirement 1 to 9, it is characterized in that: the pressurized gas outlet of fluid input (7) through firing chamber (19) with volume type rotor gas compressor structure (22) of described hydraulic mechanism, the communicating passage between described pressurized gas outlet and described firing chamber is established in convergent jet pipe (16) and/or the communicating passage between described firing chamber and the fluid input (7) of described hydraulic mechanism and establishes convergent jet pipe (16).