CN114589436A

CN114589436A - Continuous welding equipment of syntonizer

Info

Publication number: CN114589436A
Application number: CN202210251838.2A
Authority: CN
Inventors: 陈康; 徐兴华; 伊利平; 鲍旭伟
Original assignee: Jinhua Troq Electronic Co ltd
Current assignee: Jinhua Troq Electronic Co ltd
Priority date: 2022-03-15
Filing date: 2022-03-15
Publication date: 2022-06-07
Anticipated expiration: 2042-03-15
Also published as: CN114589436B

Abstract

The invention discloses continuous welding equipment for a resonator, which comprises a circulating assembly line and an automatic clamping device, wherein the circulating assembly line comprises a circulating belt, a plurality of discharging holes are formed in the circulating belt, rotating convex blocks are arranged on the circulating belt and positioned on two sides of the discharging holes, the automatic clamping device comprises a base, a rotating shaft is arranged on the base, the bottom surface of the automatic clamping device is pressed and contacted on the belt surface of the circulating assembly line, and the automatic clamping device is rotatably arranged on the rotating convex blocks through the rotating shaft. The invention provides an automatic-circulation resonator welding device which can realize automatic positioning and clamping of resonator parts, weld the resonator parts after clamping, automatically drop the resonator parts after welding is completed, and cannot touch each other in the dropping process, so that the quality problem of pin bending caused by mutual touch is reduced, the overall production efficiency is improved, and the equipment investment cost is reduced.

Description

Continuous welding equipment for resonator

Technical Field

The invention relates to the technical field of resonator manufacturing, in particular to continuous welding equipment for a resonator.

Background

Along with the improvement of life quality, electrical appliances in daily life are more and more, and the manufacturing of a plurality of electrical appliances can not leave the parts of the resonator, so the demand of the resonator is increased sharply, and in the welding manufacturing process of the resonator, the used clamp can not be automatically recycled, the automatic recycling function can be completed by manpower or a mechanical arm, and the automatic blanking function can not be realized in the using process.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides continuous welding equipment for a resonator.

In order to solve the technical problems, the invention is solved by the following technical scheme: a continuous welding device of a resonator comprises a circulating assembly line and an automatic clamping device, wherein the circulating assembly line comprises a circulating belt, a plurality of blanking holes are formed in the circulating belt, a rotating lug is arranged on the circulating belt and positioned on two sides of the blanking holes, the automatic clamping device comprises a base, a rotating shaft is arranged on the base, the bottom surface of the automatic clamping device is pressed on the belt surface of the circulating assembly line and is rotatably arranged on the rotating lug through the rotating shaft, the automatic clamping device further comprises a sliding bottom plate, a downward pressing sliding block and a clamping device, a base blanking hole is formed in the base, the sliding bottom plate is slidably arranged on the base and used for plugging the base blanking hole, the clamping device comprises a left clamping shaft, a right clamping shaft and a first elastic piece, the left clamping shaft and the right clamping shaft are oppositely arranged left and right and are slidably arranged above the base, the outer ends of the left clamping shaft and the right clamping shaft are provided with press-contact inclined blocks, the two ends of the first elastic piece are pressed against the press-contact inclined blocks and the base, the press-down sliding block is arranged on the base in a vertically sliding mode, a press-contact shaft is arranged on the press-down sliding block, the press-contact shaft and the press-contact inclined blocks are arranged in a matched mode, when the press-down sliding block is pressed down, the press-down sliding block slides downwards to drive the left clamping shaft and the right clamping shaft to slide inwards, and therefore workpieces clamped between the left clamping shaft and the right clamping shaft are clamped tightly.

Its beneficial effect lies in, when pushing down and touching down the slider, can drive the lower inclined plane pressure on the ramp board and touch on the slope of pushing down the slider, make its lapse, thereby it is interior to drive left clamp shaft and right clamp shaft, thereby it is tight to press from both sides the resonator stitch location that the station fell into tightly to go up, the base rotates to be connected on the circulation belt simultaneously, can realize that the base follows the rotation of circulation belt, make its gyro wheel arc surface that can pass through the circulation belt, thereby realize automatic clamping device and circulate the operation on the circulation belt.

In the above scheme, preferably, still be provided with second elastic component and bottom plate locking piece in the base, the second elastic component top is touched on sliding bottom plate for outwards pop out sliding bottom plate, open base blanking hole, bottom plate locking piece slides and sets up on the preceding terminal surface of base, and it is used for locking sliding bottom plate, and when it slided upwards, its locking inefficacy to sliding bottom plate.

In the above scheme, preferably, the left side and the right side of the downward pressing sliding block are provided with slopes, the guide shaft on the downward pressing sliding block is further provided with a third elastic piece in a sliding manner for upward returning, and the bottom plate locking piece is provided with an arc-shaped convex block.

The automatic unlocking device has the beneficial effects that the sliding bottom plate is pushed inwards, the bottom plate locking piece can automatically slide downwards after being pushed to the position, the sliding bottom plate is locked, the sliding bottom plate locking piece can be automatically unlocked when being lifted upwards, the sliding bottom plate is made to pop out outwards, and the base blanking hole is opened.

Among the above-mentioned scheme, preferred, still include feeding welding set and equipment platform, the equipment platform sets up on the circulating line edge, and is provided with the ramp plate on it, the ramp plate sets up with the cooperation of pushing down the slider, and when automatic clamping device passed through the ramp plate under the drive of circulating line, lower inclined plane pressure on it touched on the slope of pushing down the slider, made its lapse.

The automatic pin locking device has the beneficial effects that when the circulating belt drives the automatic clamping device to enter the station, the pins are automatically locked.

In the above scheme, preferably, the equipment platform is further provided with an inclined lifting plate, the inclined lifting plate is matched with the arc-shaped convex block, the automatic clamping device is driven by the circulating assembly line to pass through the inclined lifting plate, and an upper inclined surface of the automatic clamping device is abutted to the arc-shaped convex block, so that the bottom plate locking piece slides upwards.

The automatic unlocking device has the beneficial effects that when the device passes through the station, the sliding bottom plate is automatically unlocked and is outwards popped, so that the welded resonator automatically falls off.

In the above scheme, it is preferred, feeding welding set sets up on the equipment platform, feeding welding set includes electric putter, propulsion board, welding assembly and propulsion assembly, the propulsion board slides and sets up on the equipment platform, and the propulsion board is connected on electric putter's telescopic link, and electric putter sets up on the equipment platform, the welding assembly sets up on the propulsion board, is provided with welder on it for with resonator base and stitch welding together, the propulsion assembly includes feeding push pedal and bottom plate thimble, the feeding push pedal is used for pushing the resonator base in the base, the bottom plate thimble is used for promoting the sliding bottom plate and inwards slides, blocks up base blanking hole.

The self-locking device has the beneficial effects that the sliding bottom plate is pushed while the resonator base is pushed, so that the automatic locking is realized.

In the above scheme, preferably, a sliding inclined block is further slidably arranged on the base, a fourth elastic element is further pressed and contacted on the bottom surface, an outer edge of the sliding inclined block is an inclined edge, when the resonator base is pushed in, the resonator base is pressed and contacted on the sliding inclined block, so that the sliding inclined block slides inwards, and when the resonator base is in place, the sliding inclined block is ejected outwards to lock the resonator base.

The resonator base locking device has the beneficial effects that when the resonator base is in place, the sliding inclined block is outwards popped out to lock the resonator base.

The invention has the beneficial effects that: the invention provides an automatic-circulation resonator welding device which can realize automatic positioning and clamping of resonator parts, weld the resonator parts after clamping, automatically drop the resonator parts after welding is completed, and cannot touch each other in the dropping process, so that the quality problem of pin bending caused by mutual touch is reduced, the overall production efficiency is improved, and the equipment investment cost is reduced.

Drawings

FIG. 1 is a schematic view of the present invention.

FIG. 2 is a partial schematic view of the present invention.

FIG. 3 is a schematic view of the automatic clamping apparatus of the present invention.

Fig. 4 is a transverse sectional view of the automatic clamping device of the present invention.

Fig. 5 is a longitudinal sectional view of the automatic clamping device of the present invention.

FIG. 6 is a cross-sectional plan view of the automatic clamping apparatus of the present invention.

Fig. 7 is a partial sectional view of the automatic clamping device of the present invention.

Detailed Description

The invention is described in further detail below with reference to the following detailed description and accompanying drawings: with reference to figures 1-7 of the drawings,

the utility model provides a continuous welding equipment of syntonizer, is including installation assembly line 1, self-holding device 2, feeding welding set 3 and equipment platform 4, installation assembly line 1 includes circulation belt 11, rotates lug 12, rotates motor 13, ejection of compact belt 15 and drive belt 14, a plurality of unloading holes 111 have evenly been seted up on circulation belt 11, and are provided with on the both sides of unloading holes 111 and rotate lug 12, it connects on circulation belt 11 to rotate motor 13 for provide power, ejection of compact belt 15 is located the below of circulation belt 11 side, and realizes power transmission through drive belt 14 between the two, in circulation belt 11 pivoted, drives ejection of compact belt 15 and rotates.

Automatic clamping device 2 includes base 21, sliding bottom plate 22, bottom plate locking piece 23, pushes down slider 24, clamping device 25, second elastic component 26, third elastic component 27, slip sloping block 28 and fourth elastic component 29, base 21 both sides are provided with axis of rotation 211, base 21 bottom surface pressure is touched on circulating belt 11, has still seted up base blanking hole 212 on the base 21, and it aligns with blanking hole 111 on circulating belt 11, and wherein base 21 rotates to be connected on circulating belt 11, can realize that base 21 follows circulating belt 11 and rotates, makes its gyro wheel arc surface that can pass through circulating belt 11.

The sliding bottom plate 22 is arranged on the base 21 in a sliding mode and used for plugging the base blanking hole 212, the second elastic piece 26 is arranged on the rear end face of the sliding bottom plate 22 in the base 21 in a jacking mode, the second elastic piece 26 is located in the sliding hole of the sliding bottom plate 22 in the base 21, the bottom plate locking piece 23 is further arranged on the front end face of the base 21 in a sliding mode, when the sliding bottom plate 22 is plugged in the base blanking hole 212, the front end of the sliding bottom plate 22 is in jacking mode on the bottom plate locking piece 23, the circular arc-shaped protruding block 231 is arranged on the bottom plate locking piece 23, when the two pieces are in jacking mode from the side faces, the circular arc-shaped protruding block 231 can drive the bottom plate locking piece 23 to slide upwards, and therefore the sliding bottom plate 22 is unlocked and made to pop up outwards under the effect of the second elastic piece 26, and therefore the base blanking hole 212 is made to be through, and parts in the base 21 fall from the hole.

The clamping device 25 comprises a left clamping shaft 251, a right clamping shaft 252 and a first elastic member 254, the front ends of the left clamping shaft 251 and the right clamping shaft 252 are respectively provided with a clamping opening, the rear ends of the left clamping shaft 251 and the right clamping shaft 252 are respectively provided with a pressure-contact inclined block 253, the two pressure-contact inclined blocks are oppositely and slidably arranged on the base 21, the inclined planes of the pressure-contact inclined blocks 253 face upwards, the left clamping shaft 251 and the right clamping shaft 252 are respectively and slidably provided with a first elastic member 254, the two ends of the first elastic member respectively abut against the pressure-contact inclined block 253 and the base 21, the first elastic member is used for driving the left clamping shaft 251 and the right clamping shaft 252 to outwards open when the pressure-contact inclined block 253 is not stressed, the press-down sliding block 24 is provided with a pressure-contact shaft 241, a guide shaft 243 and a slope 242, the press-down sliding block 24 is slidably arranged on the base 21 through the guide shaft 243, and the third elastic member 27 is slidably arranged on the guide shaft 243, and the two ends of the first elastic member respectively abut against the upper plane of the base 21 and the lower plane of the press-down sliding block 24, the pressing contact shaft 241 and the pressing contact inclined block 253 are arranged in a matched mode, when the pressing slider 24 slides downwards under the action of downward pressure, the pressing contact shaft 241 presses and contacts the pressing contact inclined block 253, the pressing contact inclined block 253 slides inwards, and therefore the left clamping shaft 251 and the right clamping shaft 252 are driven to slide inwards, and resonator pins falling between the left clamping shaft 251 and the right clamping shaft 252 are located and clamped.

The base 21 is further provided with a sliding inclined block 28 in a sliding mode, the bottom surface of the base is also in abutting contact with a fourth elastic piece 29, the outer edge of the sliding inclined block 28 is an inclined edge, when the resonator base is pushed in, the resonator base abuts against the sliding inclined block 28 to enable the sliding inclined block to slide inwards, and when the resonator base is in place, the sliding inclined block 28 pops outwards to lock the resonator base.

The equipment platform 4 is arranged on the edge of the circulating assembly line 1, an inclined pressing plate 41 and an inclined lifting plate 42 are arranged on the equipment platform and are respectively positioned on two stations, the inclined pressing plate 41 is matched with the lower pressing slider 24, the inclined lifting plate 42 is matched with the top contact lug 231, when the automatic clamping device 2 is driven by the circulating assembly line 1 to pass through the inclined pressing plate 41, the lower inclined surface of the automatic clamping device is pressed on the inclined slope 242 of the lower pressing slider 24 to slide downwards so as to drive the left clamping shaft 251 and the right clamping shaft 252 to slide inwards, so that the resonator pins falling between the automatic clamping device and the lower pressing slider are positioned and clamped, when the automatic clamping device 2 passes through the inclined lifting plate 42, the upper inclined surface of the automatic clamping device is pressed on the arc lug 231 to slide upwards so as to unlock the sliding bottom plate 22, so as to be outwards ejected under the action of the second elastic piece 26, so that the base blanking hole 212 is communicated, the welded resonator falls downwards from the hole, a chute 43 is arranged below the belt at the position of the inclined lifting plate 42, a discharging belt 15 is arranged at the position of a lower outlet of the chute 43, the welded resonator falls onto the chute 43 after falling from the hole, and then enters the discharging belt 15 through the chute 43, and the discharging belt 15 is driven to rotate while the circulating belt 11 rotates, so that when the welded resonator falls downwards each time, the resonator which falls before leaves the outlet of the chute 43, and the resonators which fall each time cannot touch each other.

Feeding welding set 3 sets up on equipment platform 4, feeding welding set 3 includes electric putter 31, propulsion board 32, welding assembly 33 and propulsion assembly 34, electric putter 31 sets up on the last plane on equipment platform 4, propulsion board 32 slides and sets up on equipment platform 4, and its connection is on electric putter 31's telescopic shaft, welding assembly 33 and propulsion assembly 34 set up on propulsion board 32's the left and right sides, and distance between the two is the same with the interval that material loading hole 111 went up between two liang of circulating belt 11.

The pushing assembly 34 includes a feeding push plate 341 and a bottom plate thimble 342, the device platform 4 is further provided with a prevention platform 44 which is flush with the upper plane of the sliding bottom plate 22, the resonator base is placed on the prevention platform 44, at this time, the sliding bottom plate 22 is in a pushing state, the electric push rod 31 is pushed forward, the feeding push plate 341 firstly pushes the resonator base to push it to the sliding bottom plate 22, then the front end of the bottom plate thimble 342 pushes the sliding bottom plate 22 to push it inward, and presses the second elastic member 26, during the process of pushing inward, the two side edges of the resonator base push the sliding inclined blocks 28 to slide to the left and right, when the resonator base is in place, the sliding inclined blocks 28 are ejected outward, thereby locking the resonator base, so that the resonator base cannot move outward, at this time, the outer plane of the sliding bottom plate 22 is flush with the surface of the base 21, therefore, at this time, there is no pushing object below the bottom plate locking member 23, it slides downwards under its own weight, locking the sliding bottom plate 22.

The base 21 is further provided with a pre-limiting frame 213 with pins falling off, and when the resonator base is in place, the pins falling off into the pre-limiting frame 213 automatically in the process above the resonator base and located on the resonator base.

The welding assembly 34 comprises a welding gun for welding the base of the resonator and the pins together, and the station where the welding assembly 34 is located is the same as the station where the inclined pressing plate 41 is located.

When the automatic clamping device 2 enters the station, the lower inclined surface of the inclined pressing plate 41 presses the inclined surface 242 of the lower pressing slide block 24 to slide downwards, so that the left clamping shaft 251 and the right clamping shaft 252 are driven to slide inwards, the resonator pins falling from the upper station are positioned and clamped, and meanwhile, the welding assembly 34 is pushed to perform welding operation on the resonator pins.

The working principle or the using method is as follows:

blanking holes 111 are uniformly formed in the circulating belt 11, and an automatic clamping device 2 is arranged on each blanking hole 111.

In the initial state, the sliding bottom plate 22 on the automatic clamping device 2 is in an outward ejection state, the lower end surface of the bottom plate locking piece 23 is pressed against the sliding bottom plate 22, when the automatic clamping device enters the first station, the resonator base is placed on the prevention platform 44, the electric push rod 31 starts to work and advance forward, so that the feeding push plate 341 firstly presses against the resonator base and pushes the resonator base to the sliding bottom plate 22, then the front end of the bottom plate thimble 342 presses against the sliding bottom plate 22 to press the second elastic piece 26 inwards, during the inward pushing process, the two side edges of the resonator base press against the sliding inclined blocks 28 to slide towards the left and right, when the resonator base is in place, the sliding inclined blocks 28 are ejected outwards to lock the resonator base and prevent the resonator base from moving outwards, at the moment, the outer plane of the sliding bottom plate 22 is level with the surface of the base 21, and therefore, no top contact object exists below the bottom plate locking piece 23, it slides downwards under its own weight, locking the sliding bottom plate 22, at which point the equipment above this station automatically drops its stitches into the pre-limit frame 213.

Then the electric push rod 31 retracts backwards, the rotating motor 13 starts to rotate, the circulating belt 11 is driven to rotate for one station, so that the automatic clamping device 2 with pins and a resonator base enters a second station, in the process of entering the second station, the lower inclined surface on the inclined pressing plate 41 is pressed and contacted on the inclined surface 242 of the lower pressing slide block 24, the automatic clamping device is made to slide downwards, the left clamping shaft 251 and the right clamping shaft 252 are driven to slide inwards, the resonator pins falling from the upper station are positioned and clamped, at the moment, the electric push rod 31 starts to work and is pushed forwards, and the welding assembly 34 on the electric push rod is pushed to perform welding operation on the resonator pins.

After the welding operation is completed, the electric push rod 31 retracts, the rotating motor 13 starts to rotate, the circulating belt 11 is driven to rotate for one station, the resonator with the welding operation enters the next station, when the resonator is moved out of the second station, the contact between the inclined pressing plate 41 and the lower pressing slide block 24 disappears, therefore, the left clamping shaft 251 and the right clamping shaft 252 are outwards opened and return to the initial state, when the resonator enters the third station, the upper inclined surface of the inclined lifting plate 42 is pressed against the arc-shaped convex block 231, the bottom plate locking piece 23 is upwards slid, the sliding bottom plate 22 is unlocked, the sliding bottom plate 22 is outwards ejected under the action of the second elastic piece 26, the base blanking hole 212 is communicated, the welded resonator falls downwards from the hole, a sliding chute 43 is arranged below the belt at the position of the inclined lifting plate 42, a discharging belt 15 is arranged at the position of the lower outlet of the sliding chute 43, and after the welded resonator hole falls, fall on the spout 43, enter into ejection of compact belt 15 through spout 43 again on, and because circulation belt 11 rotates, drive ejection of compact belt 15 and rotate, consequently when falling the resonator that welds up downwards at every turn, the position that has left the spout 43 export that drops before to make the resonator that drops at every turn can not touch each other.

Since this process is continuously performed all the time, the resonator base can be simultaneously pushed and the welding operation can be simultaneously performed while the electric push rod 31 is pushed forward.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims

1. A continuous welding apparatus for resonators, characterized by: the automatic clamping device comprises a circulating assembly line (1) and an automatic clamping device (2), wherein the circulating assembly line (1) comprises a circulating belt (11), a plurality of blanking holes (111) are formed in the circulating belt (11), a rotating lug (12) is arranged on the circulating belt (11) and is positioned on two sides of the blanking holes (111), the automatic clamping device (2) comprises a base (21), a rotating shaft (211) is arranged on the base (21), the bottom surface of the automatic clamping device (2) is pressed and contacted on the belt surface of the circulating assembly line (1) and is rotatably arranged on the rotating lug (12) through the rotating shaft (211);

the automatic clamping device (2) further comprises a sliding bottom plate (22), a pressing sliding block (24) and a clamping device (25), a base blanking hole (212) is formed in the base (21), the sliding bottom plate (22) is arranged on the base (21) in a sliding mode and used for blocking the base blanking hole (212), the clamping device (25) comprises a left clamping shaft (251), a right clamping shaft (252) and a first elastic piece (254), the left clamping shaft (251) and the right clamping shaft (252) are oppositely arranged on the left side and the right side and are arranged above the base (21) in a sliding mode, pressing contact inclined blocks (253) are arranged at the outer ends of the left clamping shaft and the right clamping shaft, two ends of the first elastic piece (254) are abutted against the pressing contact inclined blocks (253) and the base (21), the pressing sliding block (24) is arranged on the base (21) in a vertical sliding mode and is provided with the pressing contact shaft (241), and the pressing contact inclined blocks (253) are arranged in a matched mode, when the downward pressing slide block (24) is pressed downwards, the downward pressing slide block slides downwards to drive the left clamping shaft (251) and the right clamping shaft (252) to slide inwards, so that a workpiece sliding between the left clamping shaft and the right clamping shaft is clamped.

2. A continuous welding apparatus for resonators as claimed in claim 1, characterized in that: still be provided with second elastic component (26) and bottom plate locking piece (23) in base (21), second elastic component (26) top is touched on sliding bottom plate (22) for outwards pop out sliding bottom plate (22), open base blanking hole (212), bottom plate locking piece (23) slide to be set up on the front end face of base (21), and it is used for locking sliding bottom plate (22), and when its upwards slides, its locking inefficacy to sliding bottom plate (22).

3. A continuous welding apparatus for resonators as claimed in claim 2, characterized in that: the left side and the right side of the downward pressing sliding block (24) are provided with slopes (242), a third elastic piece (27) is arranged on a guide shaft on the downward pressing sliding block in a sliding mode and used for upward returning, and the bottom plate locking piece (23) is provided with an arc-shaped convex block (231).

4. A continuous welding device for resonators as claimed in claim 3, characterized in that: still include feeding welding set (3) and equipment platform (4), equipment platform (4) set up on circulation assembly line (1) edge, and are provided with ramp plate (41) on it, ramp plate (41) set up with pushing down slider (24) cooperation, and when automatic clamping device (2) passed through ramp plate (41) under the drive of circulation assembly line (1), lower inclined plane pressure contact on slope (242) of pushing down slider (24) on it makes it lapse.

5. A continuous welding device for resonators as claimed in claim 4, characterized in that: the equipment platform (4) is further provided with an inclined lifting plate (42), the inclined lifting plate (42) is matched with the arc-shaped convex block (231), the automatic clamping device (2) is driven by the circulating water line (1) to pass through the inclined lifting plate (42), and an upper inclined plane on the automatic clamping device is pressed against the arc-shaped convex block (231), so that the bottom plate locking piece (23) slides upwards.

6. A continuous welding device for resonators as claimed in claim 5, characterized in that: the feeding welding device (3) is arranged on the equipment platform (4), the feeding welding device (3) comprises an electric push rod (31), a push plate (32), a welding assembly (33) and a push assembly (34), the pushing plate (32) is arranged on the equipment platform (4) in a sliding manner, the pushing plate (32) is connected to a telescopic rod of the electric push rod (31), the electric push rod (31) is arranged on the equipment platform (4), the welding assembly (33) is arranged on the pushing plate (32), a welding gun is arranged on the base for welding the base of the resonator and the pin together, the propulsion assembly (34) comprises a feeding push plate (341) and a bottom plate thimble (342), the feeding push plate (341) is used for pushing the resonator base into the base (21), the base plate thimble (342) is used for pushing the sliding base plate (22) to slide inwards to block the base blanking hole (212).

7. A continuous welding device for resonators as claimed in claim 6, characterized in that: the base (21) is further provided with a sliding inclined block (28) in a sliding mode, the bottom surface of the base is also in top contact with a fourth elastic piece (29), the outer edge of the sliding inclined block (28) is an inclined edge, when the resonator base is pushed in, the resonator base is in top contact with the sliding inclined block (28) to enable the sliding inclined block to slide inwards, and when the resonator base is in place, the sliding inclined block (28) pops outwards to lock the resonator base.