CN107052641A - Power distributor - Google Patents
Power distributor Download PDFInfo
- Publication number
- CN107052641A CN107052641A CN201710418016.8A CN201710418016A CN107052641A CN 107052641 A CN107052641 A CN 107052641A CN 201710418016 A CN201710418016 A CN 201710418016A CN 107052641 A CN107052641 A CN 107052641A
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- China
- Prior art keywords
- power
- point
- lever
- force
- arm
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Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23K—SOLDERING OR UNSOLDERING; WELDING; CLADDING OR PLATING BY SOLDERING OR WELDING; CUTTING BY APPLYING HEAT LOCALLY, e.g. FLAME CUTTING; WORKING BY LASER BEAM
- B23K37/00—Auxiliary devices or processes, not specially adapted to a procedure covered by only one of the preceding main groups
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23P—METAL-WORKING NOT OTHERWISE PROVIDED FOR; COMBINED OPERATIONS; UNIVERSAL MACHINE TOOLS
- B23P19/00—Machines for simply fitting together or separating metal parts or objects, or metal and non-metal parts, whether or not involving some deformation; Tools or devices therefor so far as not provided for in other classes
- B23P19/02—Machines for simply fitting together or separating metal parts or objects, or metal and non-metal parts, whether or not involving some deformation; Tools or devices therefor so far as not provided for in other classes for connecting objects by press fit or for detaching same
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01L—MEASURING FORCE, STRESS, TORQUE, WORK, MECHANICAL POWER, MECHANICAL EFFICIENCY, OR FLUID PRESSURE
- G01L5/00—Apparatus for, or methods of, measuring force, work, mechanical power, or torque, specially adapted for specific purposes
- G01L5/0028—Force sensors associated with force applying means
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- Physics & Mathematics (AREA)
- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Chemical & Material Sciences (AREA)
- Analytical Chemistry (AREA)
- General Physics & Mathematics (AREA)
- Optics & Photonics (AREA)
- Vehicle Body Suspensions (AREA)
Abstract
Present invention is disclosed a kind of power distributor, including:Power distributes lever and power transmission axle.Power distribution lever includes a stress point, several point of applications and several arm of forces, is connected between stress point and each point of application by an arm of force, the length of each arm of force meets predetermined ratio.Power transmission axle is connected to the stress point and the point of application that power distributes lever, and the power that lever force or transmission power distribution lever are applied is distributed to power.The power that the power distributor of the present invention is connected using spherical structure distributes lever and power transmission axle to carry out power distribution, solve point of application adaptability, exert a force it is uneven the problems such as and design, so that weld, press-fit, push-and-pull test when multiple stress points power pass through device transmission, according to the pro rate needed for user, and extra energy consumption is not produced, and can be realized in less space.
Description
Technical field
The present invention relates to mechanical production devices field, more specifically to a kind of transmission of power and assigned unit.
Background technology
During machine-building and processing, it is often necessary to apply pressure to part.For example rubbed in hot plate welding/vibrations
Welding field is wiped, be soldered object needs just to be had by certain pressure good welding penetration and welding matter in multiple regions
Amount.In actual applications, it is necessary to be pressed to multiple spot on multiple regions or multiple planes simultaneously.In the prior art, generally
Mould can be made based on object to be pressed, such as based on being soldered object, the cavity plate carrying for making profiling is welded
Object is connect, i.e., has the mould support of adhered shape therewith at the soldered object back side, then makes mould and (or left and right) above and below object
Merge.When being exerted a force, force applying device is pressed to mould, conducted power to soldered object by mould.Fig. 6 discloses existing
There is the schematic diagram of the auxiliary force-supplying device used in technology.As shown in fig. 6, it is the and of workpiece 601,602,603 to be soldered object
604.The moulding of mould 605 matches with workpiece 601,602,603 and 604, when in use, by workpiece 601 and 602,603 Hes
604 difference consistencies from top to bottom, mould 605 is placed on the top of workpiece 601 and workpiece 603 so that workpiece 601 and 602,603 and 604
It is compacted, then proceeds by welding.
The power source pressed to mould is single pressure source or many pressure sources.Single pressure source (such as cylinder) acts on mould
A point on tool, because mould is regid mechanism, mould can conduct power to by force application object.Single pressure source is by rigid body knot
Structure precision, the modulus of elasticity limitation by force application object diverse location, it is impossible to power is uniformly applied, can not be applied in varing proportions
Plus.In extreme circumstances, it is uneven due to power, it may damage by force application object or equipment in itself.Another is many pressure
Source (such as servomotor or cylinder), respectively in the diverse location applying power of mould.Many pressure sources are due to needing to use many sets
Force applying device, space-consuming is larger, and control is complicated, because the Synchronization Control difficulty between many complete equipments is larger, therefore force ratio
The precision of example control is low, high energy consumption.
In general, this rigid mould is showed preferably when the welding object to simple structure is welded, but
During comprising curved surface, the structure of multiaspect, often because being soldered the problems such as object precision, welding equipment precision, equipment are using abrasion,
And cause force uneven, reduce welding quality.Because the adaptability of rigid die is poor, with the increase of use time, mould
When tool appearance is worn and torn or deformed, the continuous decrease of welding quality can be caused.Welded in addition, a mould may be only available for one kind
Connect object so that the convenience used is poor, and use cost is also higher.
The content of the invention
The present invention is directed to propose carrying out power transmission and assigned unit.
According to one embodiment of the invention, a kind of power distributor is proposed, including:Power distributes lever and power transmission axle.Power
Distributing lever includes a stress point, several point of applications and several arm of forces, passes through one between stress point and each point of application
The arm of force is connected, and the length of each arm of force meets predetermined ratio.Power transmission axle is connected to the stress point and force of power distribution lever
Point, the power that lever force or transmission power distribution lever are applied is distributed to power.
In one embodiment, the stress point of power distribution lever and point of application formation spherical structure.The two ends of power transmission axle
For spheroid, spheroid is matched with spherical structure, and spheroid is placed in spherical structure.
According to one embodiment of the invention, a kind of power distributor is proposed, including:Power distribution lever, power transmission axle and
Dividing plate.Power distribution lever includes a stress point, several point of applications and several arm of forces, leads between stress point and each point of application
Cross an arm of force to be connected, the length of each arm of force meets predetermined ratio.Power transmission axle is connected to the stress point that power distributes lever
And the point of application, distribute the power that lever force or transmission power distribution lever are applied to power.There is perforate on space bar, perforate
Size and the diameter of the body of power transmission axle match.
In one embodiment, the stress point of power distribution lever and point of application formation spherical structure.The two ends of power transmission axle
For spheroid, spheroid is matched with spherical structure, and spheroid is placed in spherical structure.
In one embodiment, power distributor formation sandwich construction:The stress point of next layer of power distribution lever passes through
Power transmission axle is connected to the point of application of the power distribution lever of last layer.Space bar is set between different layers, and power transmission axle is passed through
Space bar.
According to one embodiment of the invention, a kind of power distributor is proposed, including:Power distributes lever and power transmission axle.Power
Distributing lever includes a stress point, several point of applications and several arm of forces, passes through one between stress point and each point of application
The arm of force is connected, and the length of each arm of force meets predetermined ratio, and the different arm of forces are located in different planes.Power transmission axle, even
Stress point and the point of application that power distributes lever are connected to, the power that lever force or transmission power distribution lever are applied is distributed to power.
In one embodiment, the stress point of power distribution lever and point of application formation spherical structure.Power transmission axle is at least
One end is spheroid, and spheroid is matched with spherical structure, and spheroid is placed in spherical structure.
According to one embodiment of the invention, a kind of power distributor is proposed, including:First power distribution lever, the second power point
With lever and power transmission axle.First power distribution lever includes stress point, several point of applications and several arm of forces, stress point and every
It is connected between one point of application by an arm of force, the length of each arm of force meets predetermined ratio, each arm of force is located at same
In plane.Second power distribution lever includes a stress point, several point of applications and several arm of forces, stress point and each point of application
Between be connected by an arm of force, the length of each arm of force meets predetermined ratio, and the different arm of forces are located in different planes.
Power transmission axle is connected to the stress point and the point of application that power distributes lever, to power distribution lever force or transmission power distribution lever institute
The power of application.
In one embodiment, the stress point of power distribution lever and point of application formation spherical structure.Power transmission axle is at least
One end is spheroid, and spheroid is matched with spherical structure, and spheroid is placed in spherical structure.
In one embodiment, power distributor formation sandwich construction:The stress point of next layer of power distribution lever passes through
Power transmission axle is connected to the point of application of the power distribution lever of last layer.At least the power feed rod of the bottom is the second power feed rod,
Second power feed rod distributes power to the point in the multiple planes being not parallel to each other.
The power that the power distributor of the present invention is connected using spherical structure distributes lever and power transmission axle to carry out power distribution,
Solve point of application adaptability, exert a force it is uneven the problems such as and design so that weld, press-fit, push-and-pull test when multiple stress points
Power pass through the transmission of device, according to the pro rate needed for user, and do not produce extra energy consumption, and can be less
Realized in space.
Brief description of the drawings
The above and other feature of the present invention, property and advantage will pass through description with reference to the accompanying drawings and examples
And become apparent, identical reference represents identical feature all the time in the accompanying drawings, wherein:
Fig. 1 discloses the structural representation of the power distributor according to one embodiment of the invention.
Fig. 2 discloses the partial cross section structural representation of the power distributor shown in Fig. 1.
Fig. 3 a and Fig. 3 b disclose the structural representation of power distributor according to another embodiment of the present invention.
Fig. 4 discloses an example of the power distributor using the present invention.
Fig. 5 discloses another example of the power distributor using the present invention.
Fig. 6 discloses the schematic diagram of the auxiliary force-supplying device used in the prior art.
Embodiment
The present invention proposes a kind of power distributor, including:Power distributes lever and power transmission axle.Power distribution lever includes one
Stress point, several point of applications and several arm of forces, are connected between stress point and each point of application by an arm of force, each arm of force
Length meet predetermined ratio.Power transmission axle is connected to the stress point and the point of application that power distributes lever, is applied to power distribution lever
The power that power or transmission power distribution lever are applied.The stress point and point of application formation spherical structure of power distribution lever.Power is transmitted
The two ends of axle are spheroid, and spheroid is matched with spherical structure, and spheroid is placed in spherical structure.
With reference to Fig. 1 and Fig. 2, Fig. 1 discloses the structural representation of the power distributor according to one embodiment of the invention, its
Middle Fig. 2 discloses the partial cross section structural representation of the power distributor shown in Fig. 1.With reference to shown in Fig. 1, power distribution lever 102
Including a stress point 121, two point of applications 122 and two arm of forces 123.Lead between stress point 121 and each point of application 122
An arm of force 123 is crossed to be connected.The length of each arm of force meets predetermined ratio.In the illustrated embodiment, the length of two arm of forces
Degree is respectively a and b.Power transmission axle 104 is by the way that power to be distributed to the power of the stress point 121 of lever 102, the arm of force 123 and the point of application 122
Power is passed out in the way of FA or/and FB transmission power after transmission.Power distributes the stress point 121 and the point of application of lever 102
122 form spherical structure.The two ends of power transmission axle 104 are spheroid, and spheroid is matched with spherical structure.Part with reference to shown in Fig. 2
Cross section structure, spheroid is placed in spherical structure.The connection of spheroid and spherical structure can pass capable distribution lever 102 and power
Passing the connection between axle 104 has sufficient rotary freedom, and power transmission axle 104 can be with very big free rotational angle
All the time good ball is kept to be connected with power distribution lever 102.Also, spheroid to contact more equal with the connection of spherical structure
Uniform stabilization.The power and the length of the arm of force distributed in the power transmission axle of each point of application 122 are inversely proportional.With shown in Fig. 1
Embodiment exemplified by, the torque arm length of the point of application in left side is that the power distributed in a, its power transmission axle is FA;The point of application on right side
Torque arm length be b, the power distributed in its power transmission axle is FB.FA:FB=b:The power and the arm of force distributed in a, power transmission axle
Length be inversely proportional.
Fig. 3 a and Fig. 3 b disclose the structural representation of power distributor according to another embodiment of the present invention.With reference to figure
Shown in 3a, power distribution lever 302 includes a stress point 321, three point of applications 322 and three arm of forces 323.The He of stress point 321
It is connected between each point of application 322 by an arm of force 323.The length of each arm of force meets predetermined ratio.Power transmission axle
304 are connected by distributing the point of application 322, the arm of force 323 and stress point 321 of lever.Meanwhile, power transmission axle 304 is by the way that power is divided
Transmission power is passed out after the power transmission of stress point 321, the arm of force 323 and the point of application 322 with lever 302,.Power distributes lever
302 stress point 321 and the point of application 322 formation spherical structure.The two ends of power transmission axle 304 are spheroid, spheroid and spherical structure
Matching.Fig. 3 b disclose the relation of the length of the power and respective arm of force distributed in the embodiment in each power transmission axle.Such as
Shown in Fig. 3 b, the relation between power Fx, Fy and Fz at each point of application meets Fx:Fy:Fz=x:y:Z, wherein x, y and z are
Each length shown in Fig. 3 b, three fixed points of triangle are the point of application, and the circle position of triangle center is stress
Point.The difference of embodiment shown in Fig. 3 a and Fig. 3 b and the embodiment shown in Fig. 1 is the quantity for adding the point of application.Need
It is bright, according to the actual requirements, can further increase the quantity of the point of application so that formed one-to-two, one point three or even one points
Four power distribution structure.
When using single power distributor, common power distribution structure is one-to-two or one point three, if desired
The point of application of distribution is more, such as when more than five, can use the power distribution structure of multilayer.Multilayer power distribution structure is by several one
Point of two or one point three combination is formed, and compared with the structure of direct one point five or more overabsorption, multilayer power distribution structure is more
Plus stably, be also more prone to realize.
Fig. 4 discloses an example of the power distributor using the present invention, and Fig. 4 discloses a kind of multilayer power that formed and distributed
The power distributor of structure.As shown in figure 4, the power distributor includes:Power distribution lever, power transmission axle and space bar.Power point
Include a stress point, several point of applications and several arm of forces with lever.Pass through a power between stress point and each point of application
Arm is connected, and the length of each arm of force meets predetermined ratio.Power transmission axle is connected to the stress point and the point of application that power distributes lever,
Power (the position that power transmission axial force distribution lever force (the power transmission axle for being located at stress point) or transmission power distribution lever are applied
In the power transmission axle of the point of application).The stress point and point of application formation spherical structure of power distribution lever.The two ends of power transmission axle are ball
Body, spheroid is matched with spherical structure, and spheroid is placed in spherical structure.There is perforate, size and the power of perforate are passed on space bar
The diameter for passing the body of axle matches.In the embodiment shown in fig. 4, two layers of power distribution structure of power distributor formation:Power point
Stress point with lever 421 is the stress point of whole power distributor, and power distribution lever 421 has two point of applications and two power
Arm.The stress point that power transmission axle 441 distributes lever 421 by distributing the point of application, the arm of force and power of lever 421 is connected, power transmission
Axle 441 is used to exert a force to whole power distributor.Power distribution lever 421 is also referred to as second order force distribution lever.Power transmission axle 441
In the top of whole multilayer force transfer mechanism, also referred to as three-level power transmission axle.Power transmission axle 442 and power transmission axle 443 are distinguished
It is connected to two point of applications that power distributes lever 421.Power transmission axle 442 and power transmission axle 443 are also referred to as second order force transmission axle.Power
Transmission axle 442 and power transmission axle 443 pass through space bar 461, and space bar 461 is also referred to as two interstage diaphragms.Power distribution lever 422
Stress point is connected to power transmission axle 442.The stress point of power distribution lever 423 is connected to power transmission axle 443.Power distributes lever 422
With two point of applications and two arm of forces, and power distribution lever 423 has three point of applications and three arm of forces.Power distributes lever
422 and power distribution lever 423 be also referred to as primary power distribution lever.Power transmission axle 444 and power transmission axle 445 are connected respectively to power point
Two point of applications with lever 422.Power transmission axle 446, power transmission axle 447 and power transmission axle 448 are connected respectively to power distribution thick stick
Three point of applications of bar 423.Power transmission axle 444, power transmission axle 445, power transmission axle 446, power transmission axle 447 and power transmission axle
448 form five final point of applications, therefore power transmission axle 444, power transmission axle 445, power transmission axle 446, power transmission axle 447 and power
Transmission axle 448 is also referred to as primary transmission axle.Transmission axle 444, power transmission axle 445, power transmission axle 446, power transmission axle 447 and power are passed
Axle 448 is passed through space bar 462, the also referred to as first interstage diaphragm of space bar 462.By two layers above-mentioned of power distribution structure, finally
Single force is divided into five point of applications, realizes power distribution.Although the power that the power distributor of diagram has two layers is distributed
Structure, but those skilled in the art can understand, and the power distributor can form the structure of other numbers of plies as needed, and
It is not limited to double-layer structure.The power distributor can form sandwich construction:The stress point of next layer of power distribution lever passes through
Power transmission axle is connected to the point of application of the power distribution lever of last layer.Space bar is set between different layers, and power transmission axle is passed through
Space bar.
In foregoing embodiment, the final point of application is located in a plane, so foregoing embodiment is same
The power distribution of multiple spot is realized in individual plane.Fig. 5 discloses another example of the power distributor using the present invention.Shown in Fig. 5
Example be realized in different planes multiple spot power distribute.In Figure 5, shown in workpiece to be exerted a force and Fig. 6 in the prior art
The same phase of workpiece to be exerted a force used, the workpiece needs the point exerted a force to be distributed in several planes being not parallel to each other.Power distribution dress
Put including:First power distribution lever, the second power distribution lever and power transmission axle.First power distribution lever include stress point,
Several point of applications and several arm of forces, are connected between stress point and each point of application by an arm of force, the length of each arm of force
Meet predetermined ratio, each arm of force is generally aligned in the same plane interior.First power distributes lever and the power used in foregoing embodiment
Distribute lever similar.Second power distribution lever includes stress point, several point of applications and several arm of forces, stress point and each
It is connected between the point of application by an arm of force, the length of each arm of force meets predetermined ratio, and the different arm of forces is located at different
In plane.Each arm of force of second power distribution lever can be located in the plane being not parallel to each other, to adapt to treat the distribution of the point of application.
Power transmission axle is connected to the stress point and the point of application that power distributes lever, to power distribution lever force or transmission power distribution lever institute
The power of application.The stress point and point of application formation spherical structure of power distribution lever.At least one end of power transmission axle is spheroid, spheroid
Matched with the spherical structure, spheroid is placed in spherical structure.
With continued reference to shown in Fig. 5, power distributor forms two layers of structure:Power distribution lever 521 is first layer, power distribution
Lever 521 is that the first power distributes lever, with a stress point and three point of applications.Three arm of forces of power distribution lever 521 exist
In same plane.Power transmission axle 561 is connected to the stress point that power distributes lever 521.Power transmission axle 562,563 and 564 connects respectively
It is connected to three point of applications that power distributes lever 521.The two ends of power transmission axle 562,563 are spherical.Power transmission axle 562,563 after
The continuous power distribution lever for being connected to next layer.One end of power transmission axle 564 is that lever 521 is distributed in spherical, spherical one end with power
Connection.The other end of power transmission axle 564 is cylinder, forms force side, force side, which is directly acted on, treats force application part.Power is distributed
Lever 522 and 523 is first layer, and power distribution lever 522 and 523 is that the second power distributes lever, each have stress point and
Two point of applications.Power distributes respective two arm of forces of lever 522 and 523 in different planes.As illustrated, power distributes lever
522 and 523 is each inclined by an arm of force.The direction of the arm of force of power distribution lever 522 and 523 is with treating force application part
Shape it is corresponding.In the illustrated embodiment, force application part one plane of formation and the structure on two inclined-planes are treated, accordingly,
The arm of force of power distribution lever 522 and 523 is distributed in corresponding plane and inclined-plane.Power transmission axle 565,566,567 and 568 is distinguished
Be connected to the point of application that power distributes lever 522 and 523, one end of power transmission axle 565,566,567 and 568 be it is spherical, it is spherical
One end is connected with power distribution lever 522 or 523.The other end of power transmission axle 565,566,567 and 568 is cylinder, is formed
Force side, force side, which is directly acted on, treats force application part.By two layers above-mentioned of power distribution structure, final single force is divided
For five point of applications, and five point of applications are distributed in the Different Plane being not parallel to each other, and realize the power distribution in Different Plane.
Although the power distributor of diagram has two layers of power distribution structure, those skilled in the art can understand, power distribution
Device can form the structure of other numbers of plies as needed, it is not limited to double-layer structure.The power distributor can form many
Rotating fields:The power that the stress point of next layer of power distribution lever is connected to last layer by power transmission axle distributes the force of lever
Point.At least the power feed rod of the bottom is the second power feed rod, and the second power feed rod is in the multiple planes being not parallel to each other
Point distribution power.
The second power distribution lever in embodiment shown in Fig. 5, i.e., the different arm of force is located at the power point in different planes
It can also be used alone with lever, the point of application to negligible amounts and in Different Plane carries out power distribution.This kind of power distribution
Device includes:Power distributes lever and power transmission axle.Power distribution lever includes a stress point, several point of applications and several arm of forces,
It is connected between stress point and each point of application by an arm of force, the length of each arm of force meets predetermined ratio, different
The arm of force is located in different planes.Power transmission axle is connected to the stress point and the point of application that power distributes lever, is applied to power distribution lever
The power that power or transmission power distribution lever are applied.The stress point and point of application formation spherical structure of power distribution lever.Power is transmitted
At least one end of axle is spheroid, and spheroid is matched with spherical structure, and spheroid is placed in spherical structure.
The power that the power distributor of the present invention is connected using spherical structure distributes lever and power transmission axle to carry out power distribution,
Solve point of application adaptability, exert a force it is uneven the problems such as and design so that weld, press-fit, push-and-pull test when multiple stress points
Power pass through the transmission of device, according to the pro rate needed for user, and do not produce extra energy consumption, and can be less
Realized in space.
Above-described embodiment, which is available to, to be familiar with person in the art to realize or using the present invention, be familiar with this area
Personnel can make various modifications or change, thus this to above-described embodiment without departing from the present invention in the case of the inventive idea
The protection domain of invention is not limited by above-described embodiment, and should meet inventive features that claims mention most
On a large scale.
Claims (10)
1. a kind of power distributor, it is characterised in that including:
Power distributes lever, and power distribution lever includes a stress point, several point of applications and several arm of forces, and stress point is applied with each
It is connected between force by an arm of force, the length of each arm of force meets predetermined ratio;
Power transmission axle, is connected to stress point and the point of application that power distributes lever, to power distribution lever force or transmission power distribution
The power that lever is applied.
2. power distributor as claimed in claim 1, it is characterised in that
The stress point and point of application formation spherical structure of power distribution lever;
The two ends of power transmission axle are spheroid, and the spheroid is matched with the spherical structure, and spheroid is placed in spherical structure.
3. a kind of power distributor, it is characterised in that including:
Power distributes lever, and power distribution lever includes a stress point, several point of applications and several arm of forces, and stress point is applied with each
It is connected between force by an arm of force, the length of each arm of force meets predetermined ratio;
Power transmission axle, is connected to stress point and the point of application that power distributes lever, to power distribution lever force or transmission power distribution
The power that lever is applied;
There is perforate, the size and the diameter of the body of power transmission axle of the perforate match on space bar, space bar.
4. power distributor as claimed in claim 3, it is characterised in that
The stress point and point of application formation spherical structure of power distribution lever;
The two ends of power transmission axle are spheroid, and the spheroid is matched with the spherical structure, and spheroid is placed in spherical structure.
5. power distributor as claimed in claim 4, it is characterised in that the power distributor formation sandwich construction:
The power that the stress point of next layer of power distribution lever is connected to last layer by power transmission axle distributes the point of application of lever;
Space bar is set between different layers, and power transmission axle passes through space bar.
6. a kind of power distributor, it is characterised in that including:
Power distributes lever, and power distribution lever includes a stress point, several point of applications and several arm of forces, and stress point is applied with each
It is connected between force by an arm of force, the length of each arm of force meets predetermined ratio, and the different arm of forces is located at different put down
In face;
Power transmission axle, is connected to stress point and the point of application that power distributes lever, to power distribution lever force or transmission power distribution
The power that lever is applied.
7. power distributor as claimed in claim 6, it is characterised in that
The stress point and point of application formation spherical structure of power distribution lever;
At least one end of power transmission axle is spheroid, and the spheroid is matched with the spherical structure, and spheroid is placed in spherical structure.
8. a kind of power distributor, it is characterised in that including:
First power distributes lever, and the first power distribution lever includes stress point, several point of applications and several arm of forces, stress point and
It is connected between each point of application by an arm of force, the length of each arm of force meets predetermined ratio, each arm of force is located at same
In one plane;
Second power distributes lever, and the second power distribution lever includes stress point, several point of applications and several arm of forces, stress point and
It is connected between each point of application by an arm of force, the length of each arm of force meets predetermined ratio, and the different arm of forces are located at
In different planes;
Power transmission axle, is connected to stress point and the point of application that power distributes lever, to power distribution lever force or transmission power distribution
The power that lever is applied.
9. power distributor as claimed in claim 8, it is characterised in that
The stress point and point of application formation spherical structure of power distribution lever;
At least one end of power transmission axle is spheroid, and the spheroid is matched with the spherical structure, and spheroid is placed in spherical structure.
10. power distributor as claimed in claim 9, it is characterised in that the power distributor formation sandwich construction:
The power that the stress point of next layer of power distribution lever is connected to last layer by power transmission axle distributes the point of application of lever;
At least the power feed rod of the bottom is the second power feed rod, and the second power feed rod is in the multiple planes being not parallel to each other
Point distribution power.
Priority Applications (1)
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CN201710418016.8A CN107052641A (en) | 2017-06-06 | 2017-06-06 | Power distributor |
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CN201710418016.8A CN107052641A (en) | 2017-06-06 | 2017-06-06 | Power distributor |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN110948929A (en) * | 2019-12-31 | 2020-04-03 | 福州大学 | Plane distribution load-sharing pressure device and use method thereof |
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CN203768952U (en) * | 2014-01-27 | 2014-08-13 | 广东省建筑科学研究院 | Stress wave multipoint shock excitation device for foundation pile quality detection |
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CN110948929A (en) * | 2019-12-31 | 2020-04-03 | 福州大学 | Plane distribution load-sharing pressure device and use method thereof |
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