CN211231392U - Novel return stroke self-decelerating nitrogen spring for inhibiting rebound of pressure plate - Google Patents
Novel return stroke self-decelerating nitrogen spring for inhibiting rebound of pressure plate Download PDFInfo
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- CN211231392U CN211231392U CN201922120934.XU CN201922120934U CN211231392U CN 211231392 U CN211231392 U CN 211231392U CN 201922120934 U CN201922120934 U CN 201922120934U CN 211231392 U CN211231392 U CN 211231392U
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Abstract
The utility model discloses a novel return self-decelerating nitrogen spring for inhibiting the rebound of a pressure plate, which comprises a cylinder body, a guide sleeve, a plunger rod and a piston, wherein a third chamber is formed between the piston and the cylinder body, and the lower end of the guide sleeve is provided with a first groove body; after a convex seat formed at the upper end of the piston extends into the first groove body, a first cavity is formed between the convex seat and the first groove body; a second cavity is formed between a second groove body on the periphery of the convex seat and the inner wall of the cylinder body; the piston is provided with a first channel penetrating through the second groove body and a second channel penetrating through the upper end surface of the convex seat along the upper end surface of the lower end surface of the piston, the bottom of the second groove body is provided with a damping channel penetrating through the second channel, and the lower end of the second channel is provided with a one-way valve; when the plunger rod rebounds, the convex seat stretches into the first groove body, the volume of the first cavity is continuously reduced, nitrogen in the first cavity flows in along the second channel, flows into the second cavity through the damping channel and finally flows into the third cavity from the first channel, and the nitrogen in the first cavity forms a gas cushion to reduce the rebounding speed of the plunger rod.
Description
The technical field is as follows:
the utility model relates to a nitrogen spring product technical field refers in particular to a novel backward stroke self-decelerating nitrogen spring that suppresses pressure flitch bounce-back.
Background art:
with the continuous progress of science and technology, the demand of the industrial field for elastic elements is higher and higher, and the elastic elements are required to meet various requirements of mechanical structures and also to be miniaturized and have high performance.
The conventional elastic elements used in the prior art, such as springs, elastic rubber, air cushions and the like, generate elastic force which is increased in proportion to the increase of the compression amount and cannot keep constant pressure in the working process, the telescopic stroke is small, a lot of processes need constant elastic change, the conventional elastic elements bring great influence and limitation to the process design requirements, the process requirements cannot be met, the product quality and the efficiency are directly influenced, and the production cost is greatly improved.
The nitrogen spring in the prior art can solve the problems, at present, the nitrogen spring used in various industries in China is mainly imported, the nitrogen spring (called die nitrogen spring or nitrogen cylinder for short) is a novel elastic element using high-pressure nitrogen as a working medium, and has the advantages of small volume, large elasticity, long stroke, stable work, precise manufacture, long service life, gentle elastic curve, no need of pre-tightening and the like, the nitrogen spring has the work which is difficult to complete by conventional elastic components such as metal springs, rubbers, air cushions and the like, the design and manufacture of a die are simplified, the installation and adjustment of the die are convenient, the service life of the die is prolonged, the stability of the product quality is ensured, and the nitrogen spring is a new generation of optimal elastic component with flexible performance.
The existing nitrogen spring on the market generally comprises a cylinder body, a guide sleeve fixed at the upper end of the cylinder body and a plunger rod penetrating through the guide sleeve, wherein a piston arranged at the lower end of the plunger rod is arranged in the cylinder body and can slide in the cylinder body.
When the nitrogen spring is used in a die, the upper end face of the plunger rod is in contact with the pressure plate, when the nitrogen spring rebounds, the plunger rod generates great movement inertia in the rising process, the longer the rising stroke of the plunger rod is, the greater the generated movement inertia is, and the pressure plate can generate great rebound when rising to the stroke end point under the action of the movement inertia, so that the pressure plate can be greatly damaged due to collision with an upper pressure head of the press; in order to avoid the damage of the pressure plate due to collision with the upper pressure head of the press, the height of the upper pressure head of the press is required to be increased, the stamping working efficiency can be reduced, the stamping charge is increased, the cost is increased, and the quality of a stamped workpiece is unstable due to rebound of the pressure plate.
In view of the above, the present inventors propose the following.
The utility model has the following contents:
an object of the utility model is to overcome prior art not enough, provide a novel backward stroke self-decelerating nitrogen spring that restraines the flitch bounce-back.
In order to solve the technical problem, the utility model discloses a following technical scheme: the novel return self-decelerating nitrogen spring for inhibiting the rebound of the pressure plate comprises a cylinder body, a guide sleeve fixed at the upper end of the cylinder body and a plunger rod penetrating through the guide sleeve, wherein a piston arranged at the lower end of the plunger rod is arranged in the cylinder body and can slide in the cylinder body, the outer part of the piston is in contact with the cylinder body, a third chamber is formed between the piston and the cylinder body, and the guide sleeve is upwards provided with a first groove body along the lower end surface of the guide sleeve; a convex seat capable of extending into the first groove body is formed at the upper end of the piston, a second groove body is arranged on the periphery of the middle part of the convex seat, and a closed first cavity is formed between the convex seat and the first groove body after the convex seat extends into the first groove body; a second cavity is formed between a second groove body on the periphery of the boss and the inner wall of the cylinder body; the piston is provided with a first channel which penetrates through the second groove body upwards along the lower end surface of the piston; the piston is provided with a second channel which runs through the upper end surface of the convex seat upwards along the lower end surface of the piston, the bottom of the second groove body is provided with a damping channel which runs through the second channel and has a hole diameter smaller than the hole diameter of the second channel, and the opening at the lower end of the second channel is provided with a one-way valve, so that gas can only flow upwards in a one-way from the opening at the lower end of the second channel; when the plunger rod rebounds, the convex seat at the upper end of the piston extends into the first groove body at the lower end of the guide sleeve, the volume of the first cavity is continuously reduced, nitrogen in the first cavity flows in along the second channel, flows into the second cavity after being damped by the damping channel, and finally flows into the third cavity from the first channel, so that the nitrogen in the first cavity forms a gas cushion, and the rebounding speed of the plunger rod is reduced.
Further, in the above technical solution, an inclined guide surface is provided at the opening of the first groove body.
Further, in the above technical solution, a first guide ring is disposed on the periphery of the piston, and the first guide ring is in contact with the inner wall of the cylinder body; and a second guide ring is arranged on the periphery of the convex seat and is used for contacting with the inner wall of the first groove body.
Furthermore, in the above technical scheme, a convex thread section is formed at the lower end of the plunger rod, the thread section is spirally fixed in a convex screw hole formed in the piston, and the thread section and the convex screw hole are sealed by a second sealing ring.
Further, in the above technical solution, the lower end of the threaded section further extends out of the lower end surface of the piston.
Further, in the above technical scheme, the guide sleeve is fixed at the upper end of the cylinder body through a snap spring, the inner wall of the guide sleeve is provided with a main sealing ring, a third guide ring and an inner dustproof seal, and the main sealing ring, the third guide ring and the inner dustproof seal are all in contact with the outer wall of the plunger rod; a first sealing ring and an outer dustproof seal are arranged between the outer wall of the guide sleeve and the inner wall of the cylinder body.
After the technical scheme is adopted, compared with the prior art, the utility model has following beneficial effect: in the process of the utility model, when the plunger rod is pressed down by external force, as shown in fig. 1, each channel and cavity are in the state of mutual communication, the external force is removed, the plunger rod can freely and rapidly rebound, when the plunger rod rebounds to the position shown in fig. 2, namely the plunger rod return stroke approaches the end point, the convex seat stretches into the first groove body, a closed first cavity is formed between the convex seat and the first groove body, and a second cavity is formed between the second groove body at the periphery of the convex seat and the inner wall of the cylinder body; the one-way valve is closed, so that nitrogen can only flow upwards in a one-way mode from the opening at the lower end of the second channel, nitrogen in the first cavity flows in along the second channel, flows into the second cavity after being damped by the damping channel, and finally flows into the third cavity from the first channel, the nitrogen in the first cavity forms a gas cushion due to the limitation of the aperture of the damping channel, the rebound speed of the plunger rod is slowly reduced along with the increase of the pressure of the gas cushion, when the position shown in figure 3 is reached, namely when the plunger rod returns to the end point, the rebound speed of the plunger rod is slowly reduced to 0, and the pressure plate in contact with the end face of the plunger rod is also slowly pushed to a required position, so that the inertia rebound of the pressure plate in the whole process is avoided, the working efficiency can be improved, the stamping cost can be reduced, a stamped workpiece can be protected, and.
Description of the drawings:
fig. 1 is a schematic structural diagram of a first state of the present invention;
FIG. 2 is a schematic structural view of a second state of the present invention;
fig. 3 is a schematic structural diagram of a third state of the present invention.
The specific implementation mode is as follows:
the present invention will be further described with reference to the following specific embodiments and accompanying drawings.
As shown in fig. 1-3, the novel return self-decelerating nitrogen spring for inhibiting the rebound of the pressure plate comprises a cylinder body 1, a guide sleeve 2 fixed at the upper end of the cylinder body 1, and a plunger rod 3 penetrating through the guide sleeve 2, wherein a piston 4 mounted at the lower end of the plunger rod 3 is arranged in the cylinder body and can slide in the cylinder body 1, wherein the outer part of the piston 4 is in contact with the cylinder body 1, a third chamber 103 is formed between the piston 4 and the cylinder body 1, and the guide sleeve 2 is provided with a first groove body 21 upwards along the lower end thereof; a boss 41 capable of extending into the first groove 21 is formed at the upper end of the piston 4, a second groove 411 is arranged at the periphery of the middle part of the boss 41, and a closed first cavity 101 is formed between the boss 41 and the first groove 21 after the boss 41 extends into the first groove 21; a second chamber 102 is formed between a second groove 411 on the periphery of the boss 41 and the inner wall of the cylinder body 1; the piston 4 is provided with a first channel 401 which penetrates through the second groove body 411 upwards along the lower end surface; the piston 4 is provided with a second channel 402 which runs through the upper end surface of the boss 41 upwards along the lower end surface thereof, the bottom of the second groove 411 is provided with a damping channel 403 which runs through the second channel 402 and has a smaller aperture than the aperture of the second channel 402, and the opening at the lower end of the second channel 402 is provided with a one-way valve 42, so that gas can only flow upwards in one way from the opening at the lower end of the second channel 402; when the plunger rod 3 rebounds, after the boss 41 at the upper end of the piston 4 extends into the first groove 21 at the lower end of the guide sleeve 2, the volume of the first chamber 101 is continuously reduced, nitrogen in the first chamber 101 flows in along the second channel 402, flows into the second chamber 102 after being damped by the damping channel 403, and finally flows into the third chamber 103 from the first channel 401, so that the nitrogen in the first chamber 101 forms a gas cushion to reduce the rebound speed of the plunger rod 3. In the process of the present invention, when the plunger rod 3 is pressed by external force, as shown in fig. 1, each channel and chamber are in the state of mutual communication, the external force is removed, the plunger rod 3 can freely and rapidly rebound, when the position shown in fig. 2 is rebounded, that is, the plunger rod 3 returns to the end point, the boss 41 extends into the first groove body 21, the first closed chamber 101 is formed between the boss 41 and the first groove body 21, and the second chamber 102 is formed between the second groove body 411 on the periphery of the boss 41 and the inner wall of the cylinder body 1; because the check valve 1 is closed, nitrogen can only flow upwards in a single direction from the lower end opening of the second channel 402, so that the nitrogen in the first chamber 101 flows in along the second channel 402, flows into the second chamber 102 after being damped by the damping channel 403, and finally flows into the third chamber 103 from the first channel 401, due to the restriction of the orifice diameter of the damping channel 3, so that the nitrogen in the first chamber 101 forms a gas cushion, the rebound velocity of the plunger rod is slowly reduced as the pressure of the gas cushion increases, and when the position shown in figure 3 is reached, namely, when the plunger rod 3 returns to the end point, the rebound speed of the plunger rod is slowly reduced to 0, and the pressure plate in contact with the end face of the plunger rod is also slowly jacked to a required position, so that the inertia rebound of the pressure plate which is quickly in place in the whole process is avoided, the working efficiency is improved, the stamping cost is reduced, a stamped workpiece can be protected, and the quality of the stamped workpiece is ensured. In the position shown in fig. 3, when the plunger rod is vertically pressed down by the action of external force, the one-way valve arranged in the plunger rod is opened, the plunger rod can move downwards quickly, negative pressure in the first chamber is avoided, gas in the third chamber quickly enters the first chamber through the second channel, after the third chamber moves downwards to the position shown in fig. 2, the whole space is communicated completely, and when the third chamber reaches the position shown in fig. 1, a working cycle is formed.
The aperture of the first channel 401 is larger than the aperture of the second channel 402, and the aperture of the second channel 402 is larger than the aperture of the damping channel 403. The ventilation cross-sectional area of the damping channel 403 is smaller than that of the aperture of the second channel 402, specifically, the diameter of the second channel is a hole of 6mm, the damping channel 403 is a small hole of 3mm, and the ventilation cross-sectional area of the second channel is far larger than that of the damping channel 403, so that the damping channel 403 has a good damping effect on flowing nitrogen.
The opening of the first groove 21 is provided with a guide surface 211 inclined so that the boss 41 can smoothly enter the first groove 21 along the guide surface 211.
A first guide ring 43 is arranged on the periphery of the piston 4, and the first guide ring 43 is in contact with the inner wall of the cylinder 1; the boss 41 is provided at an outer periphery thereof with a second guide ring 44, and the second guide ring 44 is adapted to contact with an inner wall of the first groove 21.
A convex thread section 31 is formed at the lower end of the plunger rod 3, the thread section 31 is spirally fixed in a convex screw hole 45 arranged on the piston 4, and the thread section 31 and the convex screw hole 45 are sealed by a second sealing ring 46. The lower end of the threaded section 31 also extends beyond the lower end surface of the piston 4.
The guide sleeve 2 is fixed at the upper end of the cylinder body 1 through a clamp spring 22, a main sealing ring 23, a third guide ring 24 and an inner dust seal 25 are arranged on the inner wall of the guide sleeve 2, and the main sealing ring 23, the third guide ring 24 and the inner dust seal 25 are all in contact with the outer wall of the plunger rod 3; a first sealing ring 26 and an outer dust seal 27 are arranged between the outer wall of the guide sleeve 2 and the inner wall of the cylinder body 1.
To sum up, the utility model discloses in-process, when external force depresses plunger rod 3, as shown in fig. 1, each passageway and cavity all are in the state of intercommunication each other, and external force is removed, and plunger rod 3 can freely kick-back fast, and when kick-backing to the position shown in fig. 2, when plunger rod 3 return stroke was close the terminal point promptly, boss 41 stretched into in this first cell body 21, formed inclosed first cavity 101 between this boss 41 and the first cell body 21, and was formed with second cavity 102 between the second cell body 411 of this boss 41 periphery and the cylinder body 1 inner wall; because the check valve 1 is closed, nitrogen can only flow upwards in a single direction from the lower end opening of the second channel 402, so that the nitrogen in the first chamber 101 flows in along the second channel 402, flows into the second chamber 102 after being damped by the damping channel 403, and finally flows into the third chamber 103 from the first channel 401, due to the restriction of the orifice diameter of the damping channel 3, so that the nitrogen in the first chamber 101 forms a gas cushion, the rebound velocity of the plunger rod is slowly reduced as the pressure of the gas cushion increases, and when the position shown in figure 3 is reached, namely, when the plunger rod 3 returns to the end point, the rebound speed of the plunger rod is slowly reduced to 0, and the pressure plate in contact with the end face of the plunger rod is also slowly jacked to a required position, so that the inertia rebound of the pressure plate which is quickly in place in the whole process is avoided, the working efficiency is improved, the stamping cost is reduced, a stamped workpiece can be protected, and the quality of the stamped workpiece is ensured. In the position shown in fig. 3, when the plunger rod is vertically pressed down by the action of external force, the one-way valve arranged in the plunger rod is opened, the plunger rod can move downwards quickly, negative pressure in the first chamber is avoided, gas in the third chamber quickly enters the first chamber through the second channel, after the third chamber moves downwards to the position shown in fig. 2, the whole space is communicated completely, and when the third chamber reaches the position shown in fig. 1, a working cycle is formed.
Of course, the above description is only an exemplary embodiment of the present invention, and not intended to limit the scope of the present invention, and all equivalent changes and modifications made by the constructions, features, and principles of the present invention in accordance with the claims of the present invention are intended to be included in the scope of the present invention.
Claims (6)
1. The utility model provides a novel return stroke self-decelerating nitrogen gas spring of suppression pressure flitch bounce, its includes cylinder body (1) and is fixed in uide bushing (2) of this cylinder body (1) upper end and wears to locate plunger rod (3) in this uide bushing (2), piston (4) of this plunger rod (3) lower extreme installation are arranged in this cylinder body to can slide in cylinder body (1), wherein, this piston (4) outside and cylinder body (1) contact make and be formed with third chamber (103) between this piston (4) and cylinder body (1), its characterized in that:
the guide sleeve (2) is provided with a first groove body (21) along the lower end surface upwards; a boss (41) capable of extending into the first groove body (21) is formed at the upper end of the piston (4), a second groove body (411) is arranged on the periphery of the middle part of the boss (41), and a closed first cavity (101) is formed between the boss (41) and the first groove body (21) after the boss (41) extends into the first groove body (21); a second cavity (102) is formed between a second groove body (411) on the periphery of the convex seat (41) and the inner wall of the cylinder body (1); the piston (4) is provided with a first channel (401) which penetrates through the second groove body (411) along the lower end surface of the piston upwards; the piston (4) is provided with a second channel (402) which penetrates through the upper end surface of the boss (41) upwards along the lower end surface of the piston, the bottom of the second groove body (411) is provided with a damping channel (403) which penetrates through the second channel (402) and has a hole diameter smaller than that of the second channel (402), and the opening at the lower end of the second channel (402) is provided with a one-way valve (42), so that gas can only flow upwards in a one-way mode through the opening at the lower end of the second channel (402); when the plunger rod (3) rebounds, the convex seat (41) at the upper end of the piston (4) extends into the first groove body (21) at the lower end of the guide sleeve (2), the volume of the first cavity (101) is continuously reduced, nitrogen in the first cavity (101) flows in along the second channel (402), flows into the second cavity (102) after being damped through the damping channel (403), and finally flows into the third cavity (103) from the first channel (401), so that the nitrogen in the first cavity (101) forms a gas cushion, and the rebounding speed of the plunger rod (3) is reduced.
2. The novel return self-decelerating nitrogen spring for inhibiting the rebound of the pressure plate as claimed in claim 1, is characterized in that: an inclined guide surface (211) is arranged at the opening of the first groove body (21).
3. The novel return self-decelerating nitrogen spring for inhibiting the rebound of a pressure plate as claimed in any one of claims 1 to 2, wherein: a first guide ring (43) is arranged on the periphery of the piston (4), and the first guide ring (43) is in contact with the inner wall of the cylinder body (1); and a second guide ring (44) is arranged on the periphery of the convex seat (41), and the second guide ring (44) is used for contacting with the inner wall of the first groove body (21).
4. The novel return self-decelerating nitrogen spring for inhibiting rebound of a pressure plate as claimed in claim 3, wherein: the lower end of the plunger rod (3) is formed with a convex thread section (31), the thread section (31) is spirally fixed in a convex screw hole (45) formed in the piston (4), and the thread section (31) and the convex screw hole (45) are sealed through a second sealing ring (46).
5. The novel return self-decelerating nitrogen spring for inhibiting the rebound of the pressure plate as claimed in claim 4, wherein: the lower end of the threaded section (31) also extends out of the lower end surface of the piston (4).
6. The novel return self-decelerating nitrogen spring for inhibiting rebound of a pressure plate as claimed in claim 3, wherein: the guide sleeve (2) is fixed at the upper end of the cylinder body (1) through a clamp spring (22), a main sealing ring (23), a third guide ring (24) and an inner dust seal (25) are arranged on the inner wall of the guide sleeve (2), and the main sealing ring (23), the third guide ring (24) and the inner dust seal (25) are all in contact with the outer wall of the plunger rod (3); a first sealing ring (26) and an outer dust seal (27) are arranged between the outer wall of the guide sleeve (2) and the inner wall of the cylinder body (1).
Priority Applications (1)
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CN201922120934.XU CN211231392U (en) | 2019-11-28 | 2019-11-28 | Novel return stroke self-decelerating nitrogen spring for inhibiting rebound of pressure plate |
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CN201922120934.XU CN211231392U (en) | 2019-11-28 | 2019-11-28 | Novel return stroke self-decelerating nitrogen spring for inhibiting rebound of pressure plate |
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CN211231392U true CN211231392U (en) | 2020-08-11 |
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CN201922120934.XU Active CN211231392U (en) | 2019-11-28 | 2019-11-28 | Novel return stroke self-decelerating nitrogen spring for inhibiting rebound of pressure plate |
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