阅读说明：本技术 双活塞黏滞阻尼器 (Double-piston viscous damper ) 是由 唐璐 沈卓 韩鹏飞 刘军 庾光忠 吴坚 于 2020-03-31 设计创作，主要内容包括：本发明提出了一种双活塞黏滞阻尼器,属于阻尼器装置领域,包括缸体,所述缸体内填充有阻尼介质；以及设置在所述缸体上的活塞装置,所述活塞装置包括活动插接在所述缸体上的活塞杆,所述活塞杆上设置有活塞主体,所述活塞主体上设置有恒定阻尼孔和可变阻尼孔；其中,当所述活塞装置的移动较低时,所述可变阻尼孔处于关闭状态,所述阻尼介质通过所述恒定阻尼孔流动；当所述活塞装置的速度达到开启速度时,所述可变阻尼孔开启,所述阻尼介质通过所述恒定阻尼孔和所述可变阻尼孔流动。本发明能够在阻尼力随速度增加的过程中逐渐扩大阻尼孔面积,降低阻尼力的增加幅度,从而达到实现低速度指数的目的。(The invention provides a double-piston viscous damper, which belongs to the field of damper devices and comprises a cylinder body, wherein damping media are filled in the cylinder body; the piston device comprises a piston rod movably inserted on the cylinder body, a piston main body is arranged on the piston rod, and a constant damping hole and a variable damping hole are arranged on the piston main body; wherein when the movement of the piston means is low, the variable orifice is in a closed state and the damping medium flows through the constant orifice; when the speed of the piston device reaches an opening speed, the variable orifice is opened, and the damping medium flows through the constant orifice and the variable orifice. The invention can gradually enlarge the area of the damping hole and reduce the increasing amplitude of the damping force in the process that the damping force increases along with the speed, thereby achieving the purpose of realizing low speed index.)

1. A dual piston viscous damper, comprising:

the cylinder body (1), the said cylinder body (1) is filled with the damping medium; and

the piston device is arranged on the cylinder body (1) and comprises a piston rod (2) movably inserted on the cylinder body (1), a piston main body (3) is arranged on the piston rod (2), and a constant damping hole (34) and a variable damping hole (35) are arranged on the piston main body (3);

wherein the variable orifice (35) is in a closed state when the movement of the piston means is low, the damping medium flowing through the constant orifice (34); when the speed of the piston means reaches an opening speed, the variable orifice (35) opens, and the damping medium flows through the constant orifice (34) and the variable orifice (35).

2. The dual piston viscous damper according to claim 1, wherein the piston main body (3) comprises a first piston block (31) and a second piston block (32), the first piston block (31) and the second piston block (32) having a certain distance therebetween and being connected by an elastic member (33);

wherein, when the moving speed of the piston device reaches the opening speed, the distance between the first piston block (31) and the second piston block (32) is reduced, the spring is compressed, and the variable orifice (35) is opened.

3. The dual piston viscous damper according to claim 2, wherein the greater the moving speed after the moving speed of the piston device reaches the opening speed, the higher the compression degree of the spring, the higher the opening degree of the variable orifice (35), and the greater the flow rate of the damping medium in the variable orifice (35).

4. The dual piston viscous damper of claim 3, wherein the variable damping orifice (35) is a tapered orifice, and the first piston block (31) and the second piston block (32) are provided with a tapered valve (36); the conical valve (36) is matched with the conical hole;

wherein the thinner end of the conical valve (36) of the first piston block (31) is connected to the first piston block (31), and the thicker end extends into the conical valve (36) of the second piston block (32);

the second piston block (32) has a thinner end of the conical valve (36) connected to the second piston block (32) and a thicker end extending into the conical valve (36) of the first piston block (31).

5. The dual piston viscous damper according to any one of claims 2 to 4, characterized in that the piston rod (2) is provided with two catches (21), and the two catches (21) are respectively provided at both ends of the piston main body (3) to define the moving positions of the first piston block (31) and the second piston block (32).

6. The dual piston viscous damper according to claim 5, characterized in that an outer guide belt (37) connected with the inner wall of the cylinder (1) in a sliding and sealing manner is provided on the outer side wall of the piston main body (3), and an inner guide belt (38) connected with the piston rod (2) in a sliding and sealing manner is provided on the inner wall of the piston main body (3).

7. The dual-piston viscous damper according to claim 6, characterized in that a sealing groove is provided in a position of the cylinder block (1) contacting the piston rod (2), and a sealing member is provided in the sealing groove.

8. The dual piston viscous damper according to any one of claims 2 to 7, characterized in that one end of the piston rod (2) is provided with a first earring (13), and the opposite end of the cylinder (1) from the first earring (13) is provided with a second earring (14).

9. The dual piston viscous damper according to claim 8, characterized in that the cylinder (1) comprises a cylindrical body (11), both ends of the cylindrical body (11) being provided with end caps (12); the end cover (12) is provided with a piston hole, and the piston rod (2) is arranged in the piston hole in a sliding and sealing manner;

one end of the cylinder body (1) is provided with a connecting cylinder (15), and the second earrings (14) are arranged on the connecting cylinder (15).

10. The dual piston viscous damper of any of claims 2 to 9, wherein the resilient member (33) is a spring.

Technical Field

The invention relates to a double-piston viscous damper, and belongs to the technical field of viscous dampers.

Background

A viscous damper is a speed-dependent damping device, and the relationship between damping force and speed is determined by a damping coefficient and a speed index, and is generally expressed by the formula F ═ CV α, where α is called the speed index, and it can be seen from the formula that the larger α, the more sensitive the damping force is to the change of the movement speed. From the analysis of energy consumption, the smaller alpha is, the better the energy consumption capability is, therefore, the speed index alpha of the viscous damper is less than 1 under the general condition. The early viscous damper adopts a valve to control damping force, and is relatively easy to realize low speed index, but the valve type structure has the defects of unstable performance, short service life, high cost and the like, and is gradually replaced by a small hole type structure. The principle of the small hole damping is that energy loss is generated when a damping medium passes through the damping small hole at a high speed, and kinetic energy input from the outside is converted into heat energy of the medium, so that the aim of damping is fulfilled. The lost energy forms a pressure difference at two ends to output damping force to the outside, the damping force is composed of a hole shrinkage force caused by local loss and a friction force caused by along-the-way loss, and the hole shrinkage force is very sensitive to the speed, and the speed index of the part is generally more than 2.0, so that the speed index of the viscous damper is very difficult to control within 0.3.

With the improvement of design and construction level, more large-span bridges and high-flexibility buildings appear, higher requirements are provided for the energy consumption capacity of the viscous damper, the speed index is gradually reduced, the speed index of about 0.3 becomes the mainstream, and the speed index of the viscous damper with a certain special structure even reaches 0.1.

For a small hole damping structure, the means for reducing the speed index is to reduce the proportion of the hole shrinkage ratio with high speed index in the damping force and increase the proportion of the friction force with low speed index.

Disclosure of Invention

Aiming at the technical problems in the prior art, the invention provides a viscous damper containing a piston, which can gradually enlarge the area of a damping hole and reduce the increase amplitude of the damping force in the process that the damping force increases along with the speed, thereby achieving the purpose of realizing a low speed index.

The invention provides a double-piston viscous damper, which comprises:

a cylinder filled with a damping medium; and

the piston device is arranged on the cylinder body and comprises a piston rod movably inserted on the cylinder body, a piston main body is arranged on the piston rod, and a constant damping hole and a variable damping hole are formed in the piston main body;

wherein when the movement of the piston means is low, the variable orifice is in a closed state and the damping medium flows through the constant orifice; when the speed of the piston device reaches an opening speed, the variable orifice is opened, and the damping medium flows through the constant orifice and the variable orifice.

A further improvement of the present invention is that the piston body includes a first piston block and a second piston block, the first piston block and the second piston block having a certain distance therebetween and being connected by an elastic member;

when the moving speed of the piston device reaches the opening speed, the distance between the first piston block and the second piston block is reduced, the spring is compressed, and then the variable damping hole is opened.

In a further improvement of the present invention, the greater the moving speed after the moving speed of the piston assembly reaches the opening speed, the higher the compression degree of the spring, the higher the opening degree of the variable orifice, and the greater the flow rate of the damping medium in the variable orifice.

The invention is further improved in that the variable damping hole is a tapered hole, and tapered valves are arranged on the first piston block and the second piston block; the conical valve is matched with the conical hole;

wherein the thinner end of the conical valve of the first piston block is connected to the first piston block, and the thicker end of the conical valve of the first piston block extends into the conical valve of the second piston block;

the thinner end of the conical valve of the second piston block is connected to the second piston block, and the thicker end of the conical valve of the second piston block extends into the conical valve of the first piston block.

The invention is further improved in that the piston rod is provided with two clamping keys which are respectively arranged at two ends of the piston main body so as to limit the moving positions of the first piston block and the second piston block.

The invention is further improved in that an outer guide belt connected with the inner wall of the cylinder body in a sliding and sealing manner is arranged on the outer side wall of the piston main body, and an inner guide belt connected with the piston rod in a sliding and sealing manner is arranged on the inner wall of the piston main body.

The invention is further improved in that a sealing groove is arranged at the position, which is in contact with the piston rod, on the cylinder body, and a sealing element is arranged in the sealing groove.

The invention is further improved in that one end of the piston rod is provided with a first lug ring, and one end of the cylinder body opposite to the first lug ring is provided with a second lug ring.

The invention is further improved in that the cylinder body comprises a cylindrical main body, and end covers are arranged at two ends of the cylindrical main body; the end cover is provided with a piston hole, and the piston rod is arranged in the piston hole in a sliding and sealing manner;

one end of the cylinder body is provided with a connecting cylinder, and the second earrings are arranged on the connecting cylinder.

A further development of the invention is that the elastic element is a spring.

Compared with the prior art, the invention has the advantages that:

the double-piston viscous damper can gradually enlarge the area of the damping hole in the process that the damping force increases along with the speed, and reduce the increasing amplitude of the damping force, thereby achieving the purpose of realizing low speed index. The variable damping hole adopts the mode of cone valve and bell mouth, and the mode of bell valve control damping hole area is compared, and the damping hole area enlarges along with pressure increase gradually, can not appear because of the condition of valve opening pressure sudden change, and the stability of damping force is better.

Drawings

Preferred embodiments of the present invention will be described in detail below with reference to the attached drawing figures, wherein:

FIG. 1 is a schematic structural diagram of a dual piston viscous damper according to an embodiment of the present invention;

FIG. 2 is a schematic structural view of a piston body of one embodiment of the present invention, showing an initial state;

fig. 3 is a schematic structural view of a piston body according to an embodiment of the present invention, showing a state in which an elastic member is compressed.

In the drawings, like parts are provided with like reference numerals. The figures are not drawn to scale.

The meaning of the reference symbols in the drawings is as follows: 1. the piston comprises a cylinder body, 2, a piston rod, 3, a piston body, 11, a cylindrical body, 12, an end cover, 13, a first lug ring, 14, a second lug ring, 15, a connecting cylinder, 21, a clamping key, 31, a first piston block, 32, a second piston block, 33, an elastic piece, 34, a constant damping hole, 35, a variable damping hole, 36, a cone valve, 37, an outer guide belt, 38 and an inner guide belt.

Detailed Description

In order to make the technical solutions and advantages of the present invention more apparent, exemplary embodiments of the present invention are described in further detail below with reference to the accompanying drawings. It is clear that the described embodiments are only a part of the embodiments of the invention, and not an exhaustive list of all embodiments. And the embodiments and features of the embodiments may be combined with each other without conflict.

Fig. 1 schematically shows a dual piston viscous damper according to an embodiment of the present invention, including a cylinder 1. The cylinder body 1 is of a cuboid box-shaped structure or a sealed barrel-shaped structure, and damping media are filled in the cylinder body. The middle part of the cylinder body 1 is provided with a piston hole in a penetrating way, and a piston device is arranged in the piston hole. The piston device is inserted in the piston hole of the cylinder body 1 and can move in the piston hole. The piston device comprises a piston rod 2 and a piston body 3. The piston rod 2 passes through the piston bore and is sealingly slidable therein. The piston body 3 is provided with a plurality of damping holes, which include a constant damping hole 34 and a variable damping hole 35. The constant orifice 34 is always in an open state, the variable orifice 35 is in a closed state when the piston device moves at a low speed, and is in an open state when the piston device moves at a high speed. When the piston device moves and stretches, the damping medium flows in the damping hole to generate damping force, and impact force generated when the piston moves and stretches can be offset.

In the case of using the dual piston viscous damper according to the present embodiment, the variable orifice 35 is in a closed state when the movement of the piston means is low during the telescopic movement of the piston means in the cylinder 1, and the damping medium flows through the constant orifice 34. When the speed of the piston means reaches the opening speed, the variable orifice 35 is opened, and the damping medium flows through the constant orifice 34 and the variable orifice 35. In the embodiment, the variable damping hole 35 is arranged in the double-piston viscous damper, so that the area of the damping hole can be enlarged when the speed is high, the increase range of the damping force is reduced, and the speed index is reduced.

In one embodiment, the piston body 3 includes two piston blocks, namely a first piston block 31 and a second piston block 32, and the first piston block 31 and the second piston block 32 are slidably disposed on the piston rod 2, and the outer side walls thereof abut against the inner wall of the cylinder 1. The first piston block 31 and the second piston block 32 have a certain distance therebetween and are connected by an elastic member 33. As shown in fig. 1, the space in the cylinder 1 is divided into three parts, the space on the left side of the first piston block 31 is a left chamber, the space on the right side of the second piston block 32 is a right chamber, and the part between the first piston block 31 and the second piston block is a middle chamber. Wherein, when the moving speed of the piston assembly reaches the opening speed, the distance between the first piston block 31 and the second piston block 32 is decreased, and the spring is compressed, when the variable orifice 35 is opened. The opening speed is influenced by the position of the catch 21, and the opening speed can be adjusted by the position of the catch 21. In a preferred embodiment, the elastic member 33 is a spring.

In the dual piston viscous damper according to the present embodiment, the constant damping hole 34 of the first piston block 31 communicates between the left and middle chambers, and the constant damping hole 34 of the second piston block 32 communicates between the right and middle chambers. In the present embodiment, the constant damping hole 34 is a thin through hole, and since the damping medium has a certain viscosity, a damping force is generated when the damping medium flows.

When the piston device extends, the piston rod 2 moves to the left, the left chamber is compressed, the pressure inside the left chamber increases, the damping medium in the left chamber flows into the middle chamber through the damping hole of the first piston block 31, and the damping medium in the middle chamber flows into the right chamber through the damping hole of the second piston block 32. When the rate of extension of the piston means increases to a certain value, i.e. reaches or exceeds the starting rate, the pressure in the left chamber increases to be greater than the spring force of the spring, which compresses the spring and opens the variable orifice 35 of the first piston block 31.

When the piston device contracts, the piston rod 2 moves rightwards, the right chamber is compressed, the pressure in the right chamber is increased, the damping medium in the right chamber flows into the middle chamber through the damping holes of the second piston block 32, and the damping medium in the middle chamber flows into the left chamber through the damping holes of the first piston block 31. When the rate of piston assembly contraction increases to a certain value, i.e., reaches or exceeds the start-up rate, the pressure in the right chamber increases to a value greater than the spring force of the spring, which compresses the spring and opens the variable orifice 35 of the second piston block 32.

In one embodiment, after the moving speed of the piston assembly reaches the opening speed, the greater the moving speed, the higher the compression degree of the spring, the higher the opening degree of the variable orifice 35, the greater the opening area of the variable orifice 35, and the greater the flow rate of the damping medium in the variable orifice 35.

In the dual-piston viscous damper according to the embodiment, after the opening speed is reached, the damping medium flows in the damping hole, the larger the speed is, the larger the damping force of the constant damping hole 34 is, and the higher the opening degree of the variable damping hole 35 is, so that the damping force of the constant damping hole 34 can be balanced, the increase amplitude of the damping force is reduced, and the speed index is reduced.

In one embodiment, as shown in fig. 1 and 2, the variable orifice 35 is a tapered orifice, and the first piston block 31 and the second piston block 32 are provided with tapered valves 36. Wherein the thinner end of the conical valve 36 of the first piston block 31 is connected to the first piston block 31, the thicker end extends to the position of the second piston block 32 and is inserted into the conical valve 36, and the conical valve 36 is matched with the conical hole. The second piston block 32 has a thinner end connected to the second piston block 32 and a thicker end extending into the first piston block 31 and inserted into the conical valve 36.

As shown in fig. 3, when the elastic member 33 between the first piston block 31 and the second piston block 32 is compressed and the distance between the two piston blocks is reduced, the tapered hole moves toward the tapered valve 36 relative to the tapered valve 36, a gap is generated between the tapered hole and the tapered valve 36, and as the first piston block 31 and the second piston block 32 get closer to each other, the position of the tapered valve 36 opposite to the tapered hole becomes thinner, and the gap between the tapered hole and the tapered valve 36 becomes larger. In this way, by the configuration of the conical valve 36 and the conical bore, it is achieved that the size of the opening of the variable orifice 35 increases with increasing speed of the piston device.

In a preferred embodiment, as shown in fig. 1, two locking keys 21 are disposed on the piston rod 2, and the two locking keys 21 are disposed at two ends of the piston body 3 respectively to define the moving positions of the first piston block 31 and the second piston block 32. In the present embodiment, the left click 21 is disposed on the left side of the first piston rod 2, and the right click 21 is disposed on the right side of the first piston rod 2.

In the dual piston viscous damper according to the present embodiment, the catch 21 can limit the distance between the first piston block 31 and the second piston block 32, the left catch 21 can limit the movement of the first piston block 31, and the right catch 21 can limit the movement of the second piston block 32. When the piston device extends, the piston rod 2 moves leftwards, the pressure in the left chamber increases, the pressure in the right chamber decreases, the first piston and the second piston both receive rightward thrust, the clamping key 21 on the right side can fix the second piston to be fixed, and the first piston moves rightwards so as to open the variable damping hole 35. When the piston device contracts, the piston rod 2 moves rightwards, the pressure in the right chamber increases, the pressure in the left chamber decreases, the first piston and the second piston are both pushed leftwards, the clamping key 21 on the left side can fix the first piston to be fixed, and the second piston moves leftwards to open the variable damping hole 35.

Further, in the present embodiment, the compression of the elastic member 33 in the initial state can be adjusted by adjusting the distance between the two catches 21, thereby adjusting the starting speed of the variable orifice 35.

In one embodiment, the outer side wall of the piston body 3 is provided with an outer guide belt 37, and the outer guide belt 37 enables the sliding sealing connection between the piston body 3 and the cylinder body 1, and always keeps a seal with the inner wall of the cylinder body 1 when the first piston block 31 and the second piston block 32 move. The inner side wall of the piston body 3 is provided with an inner guide strip 38, and the inner guide strip 38 enables the sliding sealing connection between the piston body 3 and the piston rod 2, and can maintain the sealing when the first piston block 31 or the second piston block 32 slides on the piston rod 2.

In a preferred embodiment, a sealing groove is arranged on the cylinder body 1 at a position contacting with the piston rod 2, and a sealing element is arranged in the sealing groove. The sealing element is arranged in the piston hole, so that the cylinder body 1 and the piston rod 2 are connected in a sliding and sealing mode.

In one embodiment, a first ear ring 13 is disposed at one end of the piston rod 2, and a second ear ring 14 is disposed at an end of the cylinder 1 opposite to the first ear ring 13. The dual piston viscous damper of the present embodiment can be connected to other components through the first earring 13 and the second earring 14.

In one embodiment, the cylinder body 1 includes a cylindrical body 11, and the cylindrical body 11 may be a cylinder, a rectangular cylinder, or a cylindrical structure with other shapes. End covers 12 are arranged at two ends of the cylindrical main body 11, piston holes are formed in the end covers 12, and the piston rods 2 are arranged in the piston holes in a sliding sealing mode. In this embodiment, one end of the cylinder 1 is provided with a connecting cylinder 15, the connecting cylinder 15 is connected with the cylindrical main body 11 through threads, a certain space is formed between the connecting cylinder 15 and the end cover 12 close to the connecting cylinder 15, the end part of the piston rod 2 can stretch and contract in the space when the piston rod 2 contracts, and the space can limit the position of the piston rod 2 when the piston rod 2 contracts. The connecting cylinder 15 is furthermore provided with said second ear ring 14 for connecting other components.

While preferred embodiments of the present invention have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. Therefore, the appended claims are intended to be construed to include preferred embodiments and all such changes and/or modifications as fall within the scope of the invention, and all such changes and/or modifications as are made to the embodiments of the present invention are intended to be covered by the scope of the invention.