CN104594953A - Circular cylinder axial isolation fluid mechanism and device comprising same - Google Patents

Abstract

The invention discloses a circular cylinder axial isolation fluid mechanism which comprises a circular cylinder and a non-full cylinder rotating body, wherein the non-full cylinder rotating body is arranged in the circular cylinder; a working medium inlet and a working medium outlet are formed in the circular cylinder; an isolation body seat mouth is formed in an end cover of the circular cylinder; an isolation body is arranged at the isolation body seat mouth; the isolation body is controlled by a reset elastic body, the non-full cylinder rotating body and another end cover of the circular cylinder. The circular cylinder axial isolation fluid mechanism is good in pressure-bearing capacity and small in volume.

Description

Circular cylinder axial isolation hydraulic mechanism and comprise its device

Technical field

The present invention relates to heat energy and dynamic field, particularly relate to a kind of circular cylinder axial isolation hydraulic mechanism, the invention still further relates to the motor and gas compressor that comprise described circular cylinder axial flow of fluid mechanism.

Background technique

In traditional rolling rotor hydraulic mechanism, slider is radially arranged, and so not only mechanism is huge, and has a strong impact on bearing capacity in cylinder, therefore, needs 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 circular cylinder axial isolation hydraulic mechanism, comprise circular cylinder and non-full cylinder solid of rotation, described non-full cylinder solid of rotation is arranged in described circular cylinder, described circular cylinder is established working medium entrance and sender property outlet, the end cap of described circular cylinder arranges slider seat mouth, arranges slider at described slider seat mouth place, described slider controls by another end cap of Flexible Reset body, described non-full cylinder solid of rotation and described circular cylinder.

Scheme 2, a kind of circular cylinder axial isolation hydraulic mechanism, comprise circular cylinder and non-full cylinder solid of rotation, described non-full cylinder solid of rotation is arranged in described circular cylinder, described circular cylinder is established working medium entrance and sender property outlet, the end cap of described circular cylinder arranges slider seat mouth, arranges slider at described slider seat mouth place, described slider controls by Flexible Reset body and described non-full cylinder solid of rotation.

Scheme 3, a kind of circular cylinder axial isolation hydraulic mechanism, comprise circular cylinder and non-full cylinder solid of rotation, described non-full cylinder solid of rotation is arranged in described circular cylinder, described circular cylinder is established working medium entrance and sender property outlet, the end cap of described circular cylinder arranges slider seat mouth, and arrange slider at described slider seat mouth place, described slider controls by reciprocal control gear.

Scheme 4, on the basis of scheme 3, two end caps of described circular cylinder arranges slider seat mouth respectively, and arrange slider at each described slider seat mouth place, each described slider controls by reciprocal control gear.

Scheme 5, a kind of circular cylinder axial isolation hydraulic mechanism, comprise circular cylinder and non-full cylinder solid of rotation, described non-full cylinder solid of rotation is arranged in described circular cylinder, described circular cylinder is established working medium entrance and sender property outlet, two end caps of described circular cylinder arrange slider seat mouth respectively, slider is set at each described slider seat mouth place; Each described slider controls by another end cap of Flexible Reset body, described non-full cylinder solid of rotation and described circular cylinder, or each described slider controls by Flexible Reset body, described non-full cylinder solid of rotation and the described slider be arranged on another end cap.

Scheme 6, a kind of circular cylinder axial isolation hydraulic mechanism, comprise circular cylinder and non-full cylinder solid of rotation, described non-full cylinder solid of rotation is arranged in described circular cylinder, described circular cylinder is established working medium entrance and sender property outlet, two end caps of described circular cylinder arrange slider seat mouth respectively, at each described slider seat mouth place, slider is set, slider described at least one controls by reciprocal control gear, and slider described at least one controls by Flexible Reset body and described non-full cylinder solid of rotation.

Scheme 7, in scheme 1 to 6 either a program basis on, described slider contacts with described non-full cylinder solid of rotation and is sealed and matched.

Scheme 8, in scheme 1 to 6 either a program basis on, described slider coordinates with described non-full cylinder solid of rotation non-contact seals.

Scheme 9, in scheme 3,4 or 6 either a program basis on, described reciprocal control gear is set to the cylinder outward turning having same profile line with described non-full cylinder solid of rotation and turns.

Scheme 10, in scheme 3,4 or 6 either a program basis on, described reciprocal control gear is set to crank-connecting rod control gear.

Scheme 11, on the basis of scheme 10, described crank-connecting rod control gear is set to crank-connecting rod reciprocating member mechanism.

Scheme 12, on the basis of scheme 10, described crank-connecting rod control gear is set to connecting rod.

Scheme 13, on the basis of scheme 10, described crank-connecting rod control gear is set to crank-connecting rod gear rack swing part mechanism.

Scheme 14, on the basis of scheme 10, described crank-connecting rod control gear is set to crank-connecting rod fork swing part mechanism.

Scheme 15, in scheme 3,4 or 6 either a program basis on, described reciprocal control gear is set to disc cam.

Scheme 16, in scheme 3,4 or 6 either a program basis on, described reciprocal control gear is set to cam control gear.

Scheme 17, in scheme 3,4 or 6 either a program basis on, described reciprocal control gear is set to eccentric rotary planet control mechanism.

Scheme 18, in scheme 3,4 or 6 either a program basis on, described reciprocal control gear be set to interval reciprocating control mechanism.

Scheme 19, in scheme 3,4 or 6 either a program basis on, described reciprocal control gear is set to swash plate control mechanism.

Scheme 20, in scheme 3,4 or 6 either a program basis on, described slider with the rest point of the described reciprocal control gear pericenter that is the heart and apocenter and described slider with the rest point of the described non-full cylinder solid of rotation pericenter that is the heart and apocenter corresponding respectively.

Scheme 21, in scheme 1 to 3 either a program basis on, two end caps of described circular cylinder arrange described slider seat mouth respectively, described slider are set at each described slider seat mouth place.

Scheme 22, in scheme 1 to 6 either a program basis on, described circular cylinder axial isolation hydraulic mechanism is set to liquor pump.

Scheme 23, in scheme 1 to 6 either a program basis on, described circular cylinder axial isolation hydraulic mechanism is set to fluid motor.

Scheme 24, a kind of motor comprising circular cylinder axial isolation hydraulic mechanism described in either a program in scheme 1 to 23, the described working medium entrance of described circular cylinder axial isolation hydraulic mechanism is communicated with high-pressure working medium source.

Scheme 25, on the basis of scheme 24, the communicating passage between described working medium entrance and described high-pressure working medium source arranges working medium control valve.

Scheme 26, on the basis of scheme 24 or 25, described high-pressure working medium source is set to intermittent combustion room or is set to continuous combustion chambers.

Scheme 27, comprise a motor for circular cylinder axial isolation hydraulic mechanism described in either a program in scheme 1 to 23, the described working medium entrance of described sender property outlet through firing chamber with other described circular cylinder axial isolation hydraulic mechanism of described circular cylinder axial isolation hydraulic mechanism is communicated with.

Scheme 28, on the basis of scheme 27, the described sender property outlet of described circular cylinder axial isolation hydraulic mechanism is communicated with through the described working medium entrance of working medium control valve again through firing chamber with other described circular cylinder axial isolation hydraulic mechanism.

Scheme 29, on the basis of scheme 27 or 28, described sender property outlet is communicated with the sender property outlet of velocity profile gas compressor with the described working medium entrance of the described circular cylinder axial isolation hydraulic mechanism of described combustion chamber, and the do work working medium entrance of mechanism of described sender property outlet and the velocity profile of described working medium entrance and the described circular cylinder axial isolation hydraulic mechanism of described combustion chamber is communicated with.

Scheme 30, on the basis of scheme 29, the described circular cylinder axial isolation hydraulic mechanism of described velocity profile acting mechanism and described sender property outlet and described combustion chamber links and arranges.

Scheme 31, on the basis of scheme 29, described velocity profile acting mechanism and the interlock of described velocity profile gas compressor are arranged.

Scheme 32, on the basis of scheme 29, the described circular cylinder axial isolation hydraulic mechanism of the described circular cylinder axial isolation hydraulic mechanism of described sender property outlet and described combustion chamber and described working medium entrance and described combustion chamber links and arranges.

Scheme 33, on the basis of scheme 32, the described circular cylinder axial isolation hydraulic mechanism of described sender property outlet and the described circular cylinder axial isolation hydraulic mechanism of described combustion chamber, described working medium entrance and described combustion chamber and the described velocity profile mechanism three that does work links and arranges.

Scheme 34, on the basis of scheme 29, described velocity profile gas compressor is set to multistage speed type gas compressor.

Scheme 35, on the basis of scheme 29, described velocity profile acting mechanism is set to multistage speed type acting mechanism.

Scheme 36, comprise a motor for circular cylinder axial isolation hydraulic mechanism described in either a program in scheme 1 to 23, the described sender property outlet of described circular cylinder axial isolation hydraulic mechanism through firing chamber therewith the described working medium entrance of described circular cylinder axial isolation hydraulic mechanism be communicated with.

Scheme 37, on the basis of scheme 36, the described sender property outlet of described circular cylinder axial isolation hydraulic mechanism through working medium control valve again through firing chamber therewith the described working medium entrance of described circular cylinder axial isolation hydraulic mechanism be communicated with.

Scheme 38, a kind of gas compressor comprising circular cylinder axial isolation hydraulic mechanism described in either a program in scheme 1 to 23, establishes gas exhausting valve at the described sender property outlet place of described circular cylinder axial isolation hydraulic mechanism.

In the present invention, so-called " described slider controls by reciprocal control gear " refers under the control of described reciprocal control gear, and described slider coordinates with another end bracket enclosed of described non-full cylinder solid of rotation and described circular cylinder.

In the present invention, so-called " cam control gear " comprises eccentric shaft control mechanism.

In the present invention, so-called " slider seat mouth " refers to the opening with described slider with matching relationship.

In the present invention, so-called " circular cylinder " refers to that at the nearside wheel profile of the plane inside cylinder perpendicular with cylinder centerline be all circular cylinders, comprise isometrical circular cylinder and non-isometrical circular cylinder, such as: cylindrical cylinder, conical cylinder, frustoconic shape cylinder, sphere circular cylinder.

In the present invention, can have any shape with the profile line that circular cylinder described in the PMPQ of the axis being parallel with described circular cylinder is formed.

In the present invention, so-called " non-full cylinder solid of rotation " refers to that outer contour is formed in the plane perpendicular with described circular cylinder center line area is less than described circular cylinder inner area and the solid of rotation that is sealed and matched mutually of at least one place and described circular cylinder madial wall, and namely this solid of rotation forms fitting area.

In the present invention, so-called " fitting area " refers to the structure that the inner side (comprising the inner side of the end cap of described circular cylinder) of described non-full cylinder solid of rotation and described circular cylinder is sealed and matched.

In the present invention, described fitting area can comprise at least one point of fitting area, a non-fitting area (when described point of fitting area only has one, the region removed outside point fitting area described in this forms described non-fitting area) is formed between point fitting area described in adjacent two.

In the present invention, described in one, point fitting area and a described non-fitting area form a working area.

In the present invention, can be arbitrary by the section size in the axial direction formed during non-full cylinder solid of rotation described in the plane cutting of the axis of described non-full cylinder solid of rotation, such as described section can be oval, circular, rectangle, also can be the increase shape etc. that increases of size in the axial direction with radius, thus described non-full cylinder solid of rotation can be dish type, spherical, elliposoidal, rugby shape etc.

In the present invention, so-called " being sealed and matched " is that abutment is sealed and matched and non-contact seals coordinates, such as: contact has oiling agent slipper seal to coordinate, contact that unlubricated dose of slipper seal coordinates, contact self-lubricating sliding is sealed and matched, contacted oiling agent rolling seal coordinates, contacts that unlubricated dose of rolling seal coordinates, contact self-lubricating is sealed and matched, non-contact seals coordinates.

In the present invention, so-called " non-contact seals cooperation " refers under discontiguous prerequisite, the matching relationship that both gaps are little as far as possible, the concrete size in gap should determine according to known technologies such as the impacts of the impact of machining accuracy, associated components stress, associated components temperature.

In the present invention, so-called " on described circular cylinder, establishing working medium entrance and sender property outlet " refers to and establish working medium entrance on the end face or side of described circular cylinder, and establishes sender property outlet on the end face or side of described circular cylinder.

In the present invention, a described circular cylinder can arrange working medium entrance described in one or more.

In the present invention, a described circular cylinder can arrange sender property outlet described in one or more.

In the present invention, optionally according to the number of described working area, the end cap of described circular cylinder arranges described slider seat mouth, arrange described slider at each described slider seat mouth place, each described working area at least arranges a described slider seat mouth, at least arranges a described slider, at least arranges a described working medium entrance and at least arrange a described sender property outlet.

In the present invention, working area described in two or more is optionally made to share same described slider, same described working medium entrance and same described sender property outlet.

In the present invention, so-called " working medium control valve " comprises check valve (one-way valve).

In the present invention, so-called " pericenter " refers to from certain a bit nearest position.

In the present invention, so-called " apocenter " refers to from certain some position farthest.

In the present invention, so-called " A and B link setting " refers to the set-up mode of A and B phase mutual driving effect, comprises coaxial set-up mode.

In the present invention, described velocity profile gas compressor comprises impeller type gas compressor.

In the present invention, described velocity profile acting mechanism comprises impeller type acting mechanism.

In the present invention, certain more than numerical value A and certain below numerical value A includes this number A.

The present inventor thinks according to thermodynamic (al) basic principle and on the observation of universe phenomenon: under the prerequisite affected not having external factor, and heat absolutely can not convert other any type of energy or material to.Only set forth in conventional heat second law under the prerequisite not having external factor to affect, heat can not absolutely be changed successfully, and this law is correct, but is unilateral.With popular language, heat can be defined as the minimum form of energy, or be the rubbish in universe referred to as this.By analysis, the present inventor also thinks: the growing process of any biology (animal, plant, microorganism, virus and bacterium) is all heat release.By analysis, the present inventor also thinks: any one process or any one circulation (are not limited to thermodynamic process, such as chemical reaction process, biochemical reaction process, photochemical reaction process, biological growth process, growing process are all included) its maximum acting ability conservation, the present inventor thinks does not have photosynthetic growing process can not improve its acting ability, that is, the acting ability of bean sprouts is the acting ability sum that impossible add its nutrient absorbed higher than the acting ability of bean or pea; Why the acting ability of one tree wood is greater than the acting ability of sapling, is because sunlight take part in by the growing process of sapling to trees with photosynthetic form.

The present inventor thinks: the basic logic of heat engine work restrain-be heated-is dispersed.So-called convergence is the increase process of the density of working medium, and such as condensation, compression all belong to convergence process, and under same pressure, the working medium degree of convergence that temperature is low is large; It is exactly the endothermic process of working medium that what is called is heated; What is called disperses the process referring to that the density of working medium reduces, such as, expand or spray.Any one disperses the reduction that process all can form acting ability, and such as, the acting ability of the air of gaseous state will well below the acting ability of liquid air; The heat that methanol plus water adds moderate temperature generates carbon monoxide and hydrogen, although the carbon monoxide generated and the ignition heat of hydrogen are greater than the ignition heat about 20% of methyl alcohol, but the ratio that its acting ability is greater than the acting ability of methyl alcohol is then very little, although its reason is that this process has inhaled the heat of about 20%, the degree of divergence of resultant carbon monoxide and hydrogen is far longer than methyl alcohol.Therefore, utilizing the not high physochlaina infudibularis of temperature to add chemical reaction is the acting ability having no idea effectively to improve resultant.

The present inventor thinks: it is the process that entropy increases that distance increases, and the distance between cold & heat source also affects efficiency, high apart from little efficiency, low apart from large efficiency.

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:

Circular cylinder axial isolation hydraulic mechanism disclosed in this invention and comprise its device, bearing capacity is good, volume is little.

Accompanying drawing explanation

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

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

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

Fig. 4 is the structural representation of the embodiment of the present invention 4;

Fig. 5 is the structural representation of the embodiment of the present invention 5;

Fig. 6 is the structural representation of the embodiment of the present invention 6;

Fig. 7 .1, Fig. 7 .2, Fig. 7 .3, Fig. 7 .4, Fig. 7 .5 are the structural representations of the embodiment of the present invention 7;

Fig. 8 .1, Fig. 8 .2, Fig. 8 .3, Fig. 8 .4 are the structural representations of the embodiment of the present invention 8;

Fig. 9 is the structural representation of the embodiment of the present invention 9;

Figure 10 is the structural representation of the embodiment of the present invention 10;

Figure 11 is the structural representation of the embodiment of the present invention 11;

Figure 12 is the structural representation of the embodiment of the present invention 12;

Figure 13 is the structural representation of the embodiment of the present invention 13;

Figure 14 is the structural representation of the embodiment of the present invention 14;

Figure 15 is the structural representation of the embodiment of the present invention 15;

In figure:

1 circular cylinder, the end cap of 101 circular cylinders, 2 non-full cylinder solid of rotation, the working medium entrance of 3 circular cylinder axial isolation hydraulic mechanism, the sender property outlet of 4 circular cylinder axial isolation hydraulic mechanism, 5 slider seat mouths, 6 sliders, 7 Flexible Reset bodies, 8 reciprocal control gear, 81 cylinder outward turnings are turned, 821 crank-connecting rod reciprocating member mechanisms, 822 connecting rods, 823 crank-connecting rod gear rack swing part mechanisms, 824 crank-connecting rod fork swing part mechanisms, 83 disc cams, 84 cam control gears, 85 eccentric rotary planet control mechanisms, 86 swash plate control mechanisms, 9 high-pressure working medium sources, 10 working medium control valves, 11 firing chambers, 12 velocity profile gas compressors, 13 velocity profile acting mechanisms.

Embodiment

Embodiment 1

Circular cylinder axial isolation hydraulic mechanism as shown in Figure 1, comprise circular cylinder 1 and non-full cylinder solid of rotation 2, described non-full cylinder solid of rotation 2 is arranged in described circular cylinder 1, described circular cylinder 1 is established working medium entrance 3 and sender property outlet 4, the end cap 101 of described circular cylinder 1 arranges slider seat mouth 5, arrange slider 6 at described slider seat mouth 5 place, described slider 6 controls by another end cap 101 of Flexible Reset body 7, described non-full cylinder solid of rotation 2 and described circular cylinder 1.

Embodiment 2

Circular cylinder axial isolation hydraulic mechanism as shown in Figure 2, comprise circular cylinder 1 and non-full cylinder solid of rotation 2, described non-full cylinder solid of rotation 2 is arranged in described circular cylinder 1, described circular cylinder 1 is established working medium entrance 3 and sender property outlet 4, the end cap 101 of described circular cylinder 1 arranges slider seat mouth 5, arrange slider 6 at described slider seat mouth 5 place, described slider 6 controls by Flexible Reset body 7 and described non-full cylinder solid of rotation 2.

Embodiment 3

Circular cylinder axial isolation hydraulic mechanism as shown in Figure 3, comprise circular cylinder 1 and non-full cylinder solid of rotation 2, described non-full cylinder solid of rotation 2 is arranged in described circular cylinder 1, described circular cylinder 1 is established working medium entrance 3 and sender property outlet 4, the end cap 101 of described circular cylinder 1 arranges slider seat mouth 5, arrange slider 6 at described slider seat mouth 5 place, described slider 6 controls by reciprocal control gear 8.

The present embodiment in the specific implementation, selectively, two end caps 101 of described circular cylinder 1 arranges slider seat mouth 5 respectively, arranges slider 6 at each described slider seat mouth 5 place, and each described slider 6 controls by reciprocal control gear 8.

Embodiment 4

Circular cylinder axial isolation hydraulic mechanism as shown in Figure 4, comprise circular cylinder 1 and non-full cylinder solid of rotation 2, described non-full cylinder solid of rotation 2 is arranged in described circular cylinder 1, described circular cylinder 1 is established working medium entrance 3 and sender property outlet 4, two end caps 101 of described circular cylinder 1 arrange slider seat mouth 5 respectively, slider 6 is set at each described slider seat mouth 5 place; Each described slider 6 controls by another end cap 101 of Flexible Reset body 7, described non-full cylinder solid of rotation 2 and described circular cylinder 1.

As the mode of execution that can convert, each described slider 6 controls by Flexible Reset body 7, described non-full cylinder solid of rotation 2 and the described slider 6 be arranged on another end cap 101.

Embodiment 5

Circular cylinder axial isolation hydraulic mechanism as shown in Figure 5, comprise circular cylinder 1 and non-full cylinder solid of rotation 2, described non-full cylinder solid of rotation 2 is arranged in described circular cylinder 1, described circular cylinder 1 is established working medium entrance 3 and sender property outlet 4, two end caps 101 of described circular cylinder 1 arrange slider seat mouth 5 respectively, at each described slider seat mouth 5 place, slider 6 is set, described at least one, slider 6 controls by reciprocal control gear 8, and described at least one, slider 6 controls by Flexible Reset body 7 and described non-full cylinder solid of rotation 2.

Embodiment 6

Circular cylinder axial isolation hydraulic mechanism as shown in Figure 6, it is with the difference of embodiment 2: described slider 6 coordinates with described non-full cylinder solid of rotation 2 non-contact seals.

Described circular cylinder axial isolation hydraulic mechanism in all replaceable the present embodiment of described circular cylinder axial isolation hydraulic mechanism in embodiment 1 and embodiment 3 to 5.

Embodiment 7

Circular cylinder axial isolation hydraulic mechanism as shown in Fig. 7 .1, the difference of itself and embodiment 3 is: described reciprocal control gear 8 is set to the cylinder outward turning having same profile line with described non-full cylinder solid of rotation 2 and turns 81.

As the mode of execution that can convert, as shown in Fig. 7 .2, described reciprocal control gear 8 is set to disc cam 83.

As the mode of execution that can convert, as shown in Fig. 7 .3, described reciprocal control gear 8 is set to cam control gear 84.

As the mode of execution that can convert, as shown in Fig. 7 .4, described reciprocal control gear 8 is set to eccentric rotary planet control mechanism 85 (the dotted line frame shown in Fig. 7 .4).

As the mode of execution that can convert, as shown in Fig. 7 .5, described reciprocal control gear 8 is set to swash plate control mechanism 86.

As the mode of execution that can convert, described reciprocal control gear 8 is set to interval reciprocating control mechanism.

Embodiment 8

A kind of circular cylinder axial isolation hydraulic mechanism, the difference of itself and embodiment 7 is: described reciprocal control gear 8 is set to crank-connecting rod control gear, during concrete enforcement, selectively, as shown in Fig. 8 .1, described crank-connecting rod control gear is set to crank-connecting rod reciprocating member mechanism 821 (the dotted line frame shown in Fig. 8 .1); Or selectively, as shown in Fig. 8 .2, described crank-connecting rod control gear is set to connecting rod 822 (the dotted line frame shown in Fig. 8 .2); Or selectively, as shown in Fig. 8 .3, described crank-connecting rod control gear is set to crank-connecting rod gear rack swing part mechanism 823 (the dotted line frame shown in Fig. 8 .3); Or selectively, as shown in Fig. 8 .4, described crank-connecting rod control gear is set to crank-connecting rod fork swing part mechanism 824 (the dotted line frame shown in Fig. 8 .4).

The described circular cylinder axial isolation hydraulic mechanism of described circular cylinder axial isolation hydraulic mechanism in embodiment 5 also in alternative embodiment 7 and embodiment 8.

Described circular cylinder axial isolation hydraulic mechanism above in all mode of executions, is all optionally set to liquor pump or is set to.

Embodiment 9

As shown in Figure 9, a kind of motor comprising circular cylinder axial isolation hydraulic mechanism described in embodiment 3, the described working medium entrance 3 of described circular cylinder axial isolation hydraulic mechanism is communicated with high-pressure working medium source 9, communicating passage between described working medium entrance 3 and described high-pressure working medium source 9 arranges working medium control valve 10, and described high-pressure working medium source 9 is set to intermittent combustion room or is set to continuous combustion chambers.

As the mode of execution that can convert, the described working medium control valve 10 in the present embodiment also can not be established.

Embodiment 10

As shown in Figure 10, comprise a motor for circular cylinder axial isolation hydraulic mechanism described in embodiment 3, the described sender property outlet 4 of described circular cylinder axial isolation hydraulic mechanism is communicated with through the described working medium entrance 3 of working medium control valve 10 again through firing chamber 11 with other described circular cylinder axial isolation hydraulic mechanism.

As the mode of execution that can convert, the described working medium control valve 10 in the present embodiment also can not be established.

Embodiment 11

Motor as shown in figure 11, it is with the difference of embodiment 10: the described working medium entrance 3 of the described circular cylinder axial isolation hydraulic mechanism that described sender property outlet 4 is communicated with described firing chamber 11 is communicated with the sender property outlet of velocity profile gas compressor 12, and the do work working medium entrance of mechanism 13 of described sender property outlet 4 and the velocity profile of the described circular cylinder axial isolation hydraulic mechanism that described working medium entrance 3 is communicated with described firing chamber 11 is communicated with.

Embodiment 12

Motor as shown in figure 12, it is with the difference of embodiment 11: do work described circular cylinder axial isolation hydraulic mechanism that mechanism 13 is communicated with described firing chamber 11 with described sender property outlet 4 of described velocity profile links and arranges.

Embodiment 13

Motor as shown in fig. 13 that, the difference of itself and embodiment 11 is: do work mechanism 13 and described velocity profile gas compressor 12 of described velocity profile links and arrange.

Embodiment 14

Motor as shown in figure 14, it is with the difference of embodiment 11: the described circular cylinder axial isolation hydraulic mechanism that the described circular cylinder axial isolation hydraulic mechanism that described sender property outlet 4 is communicated with described firing chamber 11 and described working medium entrance 3 are communicated with described firing chamber 11 links and arranges.

Embodiment 15

Motor as shown in figure 15, it is with the difference of embodiment 14: the described circular cylinder axial isolation hydraulic mechanism that the described circular cylinder axial isolation hydraulic mechanism that described sender property outlet 4 is communicated with described firing chamber 11, described working medium entrance 3 are communicated with described firing chamber 11 and described velocity profile mechanism 13 three that does work links and arranges.

In embodiment 11 to embodiment 15, all optionally, velocity profile gas compressor 12 will be stated and be set to multistage speed type gas compressor; Also all optionally, described velocity profile acting mechanism 13 is set to multistage speed type acting mechanism.

Embodiment 16

Comprise a motor for circular cylinder axial isolation hydraulic mechanism described in embodiment 1, the described sender property outlet 4 of described circular cylinder axial isolation hydraulic mechanism through working medium control valve 10 again through firing chamber 11 therewith the described working medium entrance 3 of described circular cylinder axial isolation hydraulic mechanism be communicated with.

As the mode of execution that can convert, the described working medium control valve 10 in the present embodiment also can not be established.

Embodiment 17

Comprise a gas compressor for circular cylinder axial isolation hydraulic mechanism described in embodiment 1, establish gas exhausting valve at described sender property outlet 4 place of described circular cylinder axial isolation hydraulic mechanism.

The described circular cylinder axial isolation hydraulic mechanism of described circular cylinder axial isolation hydraulic mechanism in embodiment 5 also in alternative embodiment 9 to embodiment 17.

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 circular cylinder axial isolation hydraulic mechanism, comprise circular cylinder (1) and non-full cylinder solid of rotation (2), it is characterized in that: described non-full cylinder solid of rotation (2) is arranged in described circular cylinder (1), described circular cylinder (1) is established working medium entrance (3) and sender property outlet (4), the end cap (101) of described circular cylinder (1) arranges slider seat mouth (5), at described slider seat mouth (5) place, slider (6) is set, described slider (6) is by Flexible Reset body (7), another end cap (101) of described non-full cylinder solid of rotation (2) and described circular cylinder (1) controls.

2. a circular cylinder axial isolation hydraulic mechanism, comprise circular cylinder (1) and non-full cylinder solid of rotation (2), it is characterized in that: described non-full cylinder solid of rotation (2) is arranged in described circular cylinder (1), described circular cylinder (1) is established working medium entrance (3) and sender property outlet (4), the end cap (101) of described circular cylinder (1) arranges slider seat mouth (5), at described slider seat mouth (5) place, slider (6) is set, described slider (6) controls by Flexible Reset body (7) and described non-full cylinder solid of rotation (2).

3. a circular cylinder axial isolation hydraulic mechanism, comprise circular cylinder (1) and non-full cylinder solid of rotation (2), it is characterized in that: described non-full cylinder solid of rotation (2) is arranged in described circular cylinder (1), described circular cylinder (1) is established working medium entrance (3) and sender property outlet (4), the end cap (101) of described circular cylinder (1) arranges slider seat mouth (5), arrange slider (6) at described slider seat mouth (5) place, described slider (6) controls by reciprocal control gear (8).

4. a circular cylinder axial isolation hydraulic mechanism, comprise circular cylinder (1) and non-full cylinder solid of rotation (2), it is characterized in that: described non-full cylinder solid of rotation (2) is arranged in described circular cylinder (1), described circular cylinder (1) is established working medium entrance (3) and sender property outlet (4), two end caps (101) of described circular cylinder (1) arrange slider seat mouth (5) respectively, slider (6) is set at each described slider seat mouth (5) place; Each described slider (6) controls by another end cap (101) of Flexible Reset body (7), described non-full cylinder solid of rotation (2) and described circular cylinder (1), or each described slider (6) is by Flexible Reset body (7), described non-full cylinder solid of rotation (2) and described slider (6) control that is arranged on another end cap (101).

5. a circular cylinder axial isolation hydraulic mechanism, comprise circular cylinder (1) and non-full cylinder solid of rotation (2), it is characterized in that: described non-full cylinder solid of rotation (2) is arranged in described circular cylinder (1), described circular cylinder (1) is established working medium entrance (3) and sender property outlet (4), two end caps (101) of described circular cylinder (1) arrange slider seat mouth (5) respectively, at each described slider seat mouth (5) place, slider (6) is set, slider described at least one (6) controls by reciprocal control gear (8), slider described at least one (6) controls by Flexible Reset body (7) and described non-full cylinder solid of rotation (2).

6. comprise a motor for circular cylinder axial isolation hydraulic mechanism according to any one of claim 1 to 5, it is characterized in that: the described working medium entrance (3) of described circular cylinder axial isolation hydraulic mechanism is communicated with high-pressure working medium source (9).

7. comprise a motor for circular cylinder axial isolation hydraulic mechanism according to any one of claim 1 to 5, it is characterized in that: the described working medium entrance (3) of described sender property outlet (4) through firing chamber (11) with other described circular cylinder axial isolation hydraulic mechanism of described circular cylinder axial isolation hydraulic mechanism is communicated with.

8. motor as claimed in claim 7, is characterized in that: the described sender property outlet (4) of described circular cylinder axial isolation hydraulic mechanism is communicated with through the described working medium entrance (3) of working medium control valve (10) again through firing chamber (11) with other described circular cylinder axial isolation hydraulic mechanism.

9. motor as described in claim 7 or 8, it is characterized in that: the described working medium entrance (3) of the described circular cylinder axial isolation hydraulic mechanism that described sender property outlet (4) is communicated with described firing chamber (11) is communicated with the sender property outlet of velocity profile gas compressor (12), the do work working medium entrance of mechanism (13) of described sender property outlet (4) and the velocity profile of the described circular cylinder axial isolation hydraulic mechanism that described working medium entrance (3) is communicated with described firing chamber (11) is communicated with.

10. comprise a gas compressor for circular cylinder axial isolation hydraulic mechanism according to any one of claim 1 to 5, it is characterized in that: establish gas exhausting valve at described sender property outlet (4) place of described circular cylinder axial isolation hydraulic mechanism.