CN220773422U - Quartz clock movement with low energy consumption - Google Patents

Abstract

The utility model discloses a quartz clock movement with low energy consumption, which comprises a machine body, wherein three mounting seats are arranged on the outer side of the machine body in a constant-angle welding manner, and the quartz clock movement also comprises: the clock disk is installed in the inner slotting of the machine body in a penetrating mode, the clock disk is round, the diameter of the clock disk is smaller than that of the machine body, and the movement body is installed in the inner slotting of the clock disk. This quartz clock core of low energy consumption installs two sealed pads and water absorption layer, utilize the inside fluting at the fuselage to run through slidable mounting has the clock dish, then be connected to the inner wall of fuselage through second sealed pad and water absorption layer respectively in the bottom below of clock dish, not only can increase the leakproofness between fuselage and the clock dish through the second sealed pad, can also absorb the inside moisture of fuselage through the inside active carbon that sets up of water absorption layer, avoid the moisture infiltration to the inside of core body, thereby can increase the life of core body, the holistic energy consumption of better reduction quartz clock.

Description

Quartz clock movement with low energy consumption

Technical Field

The utility model relates to the technical field of quartz clock movements, in particular to a low-energy-consumption quartz clock movement.

Background

Quartz clocks are clocks that are clocked using an electronic oscillator regulated by a quartz crystal, which is very important because it has a very precise signal frequency, so that the quartz clock and the watch are a mechanical clock of a number level more precise, the core of which is the movement, which corresponds to the heart of the whole quartz clock;

in the 'quartz clock movement' disclosed in the patent CN213023968U, the quartz clock movement comprises a second gear, a minute gear and a time gear, wherein the second gear is in transmission connection with the minute gear, the minute gear is in transmission connection with the time gear, the casing is a transparent casing, the outer surfaces of the second gear, the minute gear and the time gear are coated with color coatings, the second gear, the minute gear and the time gear are main transmission gears of the movement, the outer surfaces of the second gear, the minute gear and the time gear are coated with color layers, when the movement is in failure, people can directly judge the failure part of the movement by observing the running states of the second gear, the minute gear and the time gear in the outside, and when the movement is disassembled, the outer surface of the clock movement can be more careful, and meanwhile, the color layers can also enable the outer surface of the clock movement to look more attractive;

however, the traditional movement is basically and directly arranged in the dial plate when in use, then the dial plate is arranged in the machine body, but a waterproof mechanism is not arranged to separate the machine body from the clock dial when in installation, so that moisture can be led to penetrate into the movement when in a moist environment in a later stage of quartz clock, the phenomenon of corrosion and rust of a transmission component in the movement can be caused after the movement is used for a long time, the energy consumption of the quartz clock can be increased, and the stable use of the later stage of quartz clock is inconvenient;

therefore, we propose a quartz clock movement with low energy consumption, which can well solve the problems.

Disclosure of Invention

The utility model aims to provide a quartz clock movement with low energy consumption, which aims to solve the problems that the traditional movement in the market is basically and directly arranged in a dial plate when in use, then the dial plate is arranged in a machine body, but a waterproof mechanism is not arranged to separate the machine body from a clock dial when the dial plate is arranged, so that moisture can be permeated into the movement in a moist environment in the later stage of the quartz clock, a transmission component in the movement can be corroded and rusted after long-time use, and the energy consumption of the quartz clock can be increased.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the quartz clock movement with low energy consumption comprises a machine body, wherein three mounting seats are arranged on the outer side of the machine body in an equal-angle welding manner, the three mounting seats are identical in structure, and meanwhile, the machine body can be mounted through the mounting seats by using screws;

further comprises: the clock disk is in a circular shape, the diameter of the clock disk is smaller than that of the clock body, the inner slot of the clock disk is provided with a machine core body, two ends of the clock disk are welded with mounting blocks, the two mounting blocks are symmetrically arranged about the vertical central line of the clock disk, and the two mounting blocks are connected to two ends of the inner wall of the clock body in a penetrating and sliding manner;

the output end of the movement body is penetrated and provided with two pointers, the outer sides of the two pointers are respectively provided with a scale, the scales are arranged on the surface of the clock dial at equal angles, and the outer sides of the clock dial are connected to the inner wall of the machine body through a first sealing gasket in a fitting mode.

Preferably, the inside fluting laminating of fuselage is provided with the second and seals up the pad, and the second seals up the pad and constitute through rubber material to the top laminating that the second sealed fills up is connected with the water absorption layer, can increase the leakproofness between fuselage and the clock through the second seals up to can avoid external steam infiltration to the inside of clock.

Preferably, the water absorption layer is formed by the activated carbon material, and the upper part of the water absorption layer is attached to the outer side wall of the bottom of the clock dial, so that the wet gas absorbed by the clock dial can be absorbed by the activated carbon arranged in the water absorption layer, the water vapor can be prevented from penetrating into the machine core body, and the energy consumption rate of the quartz clock can be reduced better.

Preferably, the inside both ends of fuselage all slotting sliding mounting have the movable rod, and four the structure of movable rod is equal to the equal fixed mounting of front side of four movable rods has the push rod, and the outside of two movable rods is all connected with drive gear through a row of tooth piece meshing simultaneously, the inside both ends of fuselage all slotting sliding mounting has the gag lever post, and four the structure of gag lever post is equal to the outer end of four gag lever posts all runs through and extends to the inside of two installation pieces, can utilize to press two movable rods and drive two gag lever posts through two drive gear and shrink and remove, just can drive two gag lever posts and installation piece phase separation afterwards, more makes things convenient for the later stage to carry out quick assembly disassembly to fuselage and clock.

Preferably, the inside both ends of fuselage are all slotted and are installed drive gear through torsion spring rotation, and four drive gear are about the vertical central line symmetry setting of fuselage to the outside of four drive gear is connected with the gag lever post through a row of tooth piece meshing, can carry out elastic reset to the position of rotating back drive gear through torsion spring self elasticity, the stable use of later stage quartz clock of more convenience.

Compared with the prior art, the utility model has the following beneficial effects:

(1) The quartz clock movement with low energy consumption is provided with the second sealing gasket and the water absorption layer, the clock disk is installed by penetrating through the groove in the machine body in a sliding manner, and then the lower part of the bottom of the clock disk is connected to the inner wall of the machine body through the second sealing gasket and the water absorption layer respectively;

(2) This quartz clock core of low energy consumption is provided with movable rod, gag lever post and drive gear, utilize the inside front and back both ends at the fuselage all flutedly slidable mounting have the movable rod, then all be connected with drive gear through a row of tooth piece meshing in the outside of every two movable rods, be connected with the gag lever post through a row of tooth piece meshing in the outside of two drive gears afterwards, can drive two gag lever posts and shrink the removal when pressing two movable rods, just can carry out quick assembly disassembly separation operation to fuselage and clock dial at this moment, make things convenient for the later stage to carry out quick assembly disassembly maintenance to the quartz clock more, the last elasticity that reuse four torsion springs self can carry out elastic reset to the position of rotating back drive gear, make things convenient for the steady use of quartz clock in later stage more.

Drawings

FIG. 1 is a schematic view of a top-down construction of the present utility model;

FIG. 2 is a schematic diagram of the main sectional structure of the body and the clock dial of the present utility model;

FIG. 3 is an enlarged schematic view of the structure of FIG. 2A according to the present utility model;

FIG. 4 is a schematic view of the present utility model in partial top-down configuration with respect to the fuselage and clock dial;

fig. 5 is an enlarged view of the structure of fig. 4B according to the present utility model.

In the figure: 1. a body; 2. a mounting block; 3. clock dial; 4. a mounting base; 5. a first gasket; 6. a movement body; 7. a second gasket; 8. a water-absorbing layer; 9. a moving rod; 10. a limit rod; 11. a transmission gear; 12. tooth blocks; 13. a torsion spring; 14. a scale; 15. a pointer.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-5, the present utility model provides a technical solution: a quartz clock movement with low energy consumption comprises a machine body 1, a mounting block 2, a clock disk 3, a mounting seat 4, a first sealing gasket 5, a movement body 6, a second sealing gasket 7, a water absorption layer 8, a moving rod 9, a limiting rod 10, a transmission gear 11, a tooth block 12, a torsion spring 13, a scale 14 and a pointer 15;

the machine body 1 is provided with three mounting seats 4 in an equal-angle welding way on the outer side, the structures of the three mounting seats 4 are identical, and meanwhile, the machine body 1 can be mounted through the mounting seats 4 by using screws;

further comprises: the inside fluting of fuselage 1 runs through and installs clock 3, and clock 3 is the circle shape, and the diameter of clock 3 is less than the diameter of fuselage 1, and clock 3's inside fluting installs core body 6, clock 3's both ends all welded mounting has installation piece 2, and two installation pieces 2 are about clock 3's vertical central line symmetry setting, and two installation pieces 2 run through sliding connection at fuselage 1's inner wall both ends, two pointers 15 are run through and install to core body 6's output, and the outside of two pointers 15 all corresponds there is scale table 14, and scale table 14 is the surface that sets up at clock 3 at the equiangle, clock 3's outside is through first sealed pad 5 laminating connection to fuselage 1's inner wall.

The inside fluting laminating of fuselage 1 is provided with second sealed pad 7, and the second is sealed to be filled up 7 and be constituteed through rubber materials, and the top laminating of second sealed pad 7 is connected with the water absorption layer 8, as shown in fig. 1-3, when quartz clock is in moist environment use, the sealed leakproofness of setting between fuselage 1 and clock dial 3 can be increased to the second sealed pad 7 of fuselage 1 bottom inboard, avoid external steam infiltration to the inside of core body 6, thereby avoid core body 6 to wet and influence the use in later stage.

The water absorption layer 8 is formed by the active carbon material, and the upper part of the water absorption layer 8 is attached to the outer side wall of the bottom of the clock dial 3, and then the infiltrated moisture can be absorbed by the active carbon arranged in the water absorption layer 8, so that the moisture is prevented from infiltrating into the inner part of the movement body 6 to cause the inner driving assembly to be rusted, the energy consumption rate of the quartz clock can be reduced, and the stable use of the quartz clock in the later period is more convenient.

The inside both ends of fuselage 1 all slotting slidable mounting has movable rod 9, and the structure of four movable rods 9 is equivalent, and the front side of four movable rods 9 is all fixed mounting has the push rod, the outside of two movable rods 9 all is connected with gear 11 through a row of tooth piece 12 meshing simultaneously, the inside both ends of fuselage 1 all slotting slidable mounting has gag lever post 10, and the structure of four gag lever post 10 is equivalent, and the outer end of four gag lever post 10 all runs through and extends to the inside of two installation piece 2, as shown in fig. 1-5, when the quartz clock breaks down, press two push rods and drive two movable rods 9 and drive two gear 11 through two rows of tooth piece 12 and rotate, then the outside of two gear 11 is all connected with gag lever post 10 through a row of tooth piece 12 meshing, just can drive two gag lever post 10 through pulling movable rod 9 and shrink and remove, then just can dismantle the dismouting separation to fuselage 1 and clock 3, better convenient later stage is to the maintenance.

The inside both ends of fuselage 1 are all slotted and are installed drive gear 11 through torsion spring 13 rotation, and four drive gear 11 are about the vertical central line symmetry setting of fuselage 1 to the outside of four drive gear 11 is all connected with gag lever post 10 through a row of tooth piece 12 meshing, and the last elasticity that utilizes torsion spring 13 self can carry out elasticity to the position of rotating back drive gear 11 and reset, makes things convenient for the steady use of later stage quartz clock more.

Working principle: when the quartz clock movement with low energy consumption is used, firstly, the tightness between the machine body 1 and the clock disk 3 can be increased by the second sealing gasket 7 which is arranged on the inner side of the bottom of the machine body 1, then the infiltrated moisture can be absorbed by the activated carbon which is arranged in the water absorption layer 8, the moisture is prevented from infiltrating into the inner part of the machine body 6 to cause the driving component in the machine body to be rusted, so that the energy consumption rate of the quartz clock can be reduced, the two push rods are pressed to drive the two moving rods 9 to drive the two transmission gears 11 to rotate through the two rows of tooth blocks 12, at the moment, the two limiting rods 10 can be driven to shrink through pulling the moving rods 9, then the machine body 1 and the clock disk 3 can be disassembled and separated, and finally the position of the transmission gears 11 can be elastically reset by utilizing the elasticity of the torsion spring 13, so that the quartz clock can be used stably in the later period.

Although the present utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art may modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some technical features thereof, and any modifications, equivalent substitutions, improvements and other modifications within the spirit and principles of the present utility model should be included in the scope of the present utility model.

Claims (6)

1. The quartz clock movement with low energy consumption comprises a machine body (1), wherein three mounting seats (4) are arranged on the outer side of the machine body in an equal-angle welding mode, the three mounting seats (4) are identical in structure, and meanwhile, the machine body (1) can be mounted through the mounting seats (4) by using screws;

characterized by further comprising:

the clock is characterized in that a clock disk (3) is installed in the clock body (1) in a penetrating mode, the clock disk (3) is circular, the diameter of the clock disk (3) is smaller than that of the clock body (1), a movement body (6) is installed in the clock disk (3) in the clock body, installation blocks (2) are installed at two ends of the clock disk (3) in a welding mode, the two installation blocks (2) are symmetrically arranged relative to the vertical center line of the clock disk (3), and the two installation blocks (2) are connected to two ends of the inner wall of the clock body (1) in a penetrating and sliding mode;

the output end of the movement body (6) is penetrated and provided with two pointers (15), the outer sides of the two pointers (15) are respectively provided with a dial gauge (14), the dial gauges (14) are arranged on the surface of the clock dial (3) at equal angles, and the outer sides of the clock dial (3) are connected to the inner wall of the machine body (1) in a fitting mode through the first sealing gasket (5).

2. A low energy quartz clock movement according to claim 1, characterized in that: the inside fluting laminating of fuselage (1) is provided with second sealed pad (7), and second sealed pad (7) are constituteed through rubber material to the top laminating of second sealed pad (7) is connected with water absorption layer (8).

3. A low energy quartz clock movement according to claim 2, characterized in that: the water absorption layer (8) is made of an active carbon material, and the upper part of the water absorption layer (8) is attached and connected to the outer side wall of the bottom of the clock dial (3).

4. A low energy quartz clock movement according to claim 1, characterized in that: the inside both ends of fuselage (1) all slotting slidable mounting have movable rod (9), and four the structure of movable rod (9) is equal to the front side of four movable rods (9) all fixed mounting has the push rod, and the outside of two movable rods (9) all is connected with drive gear (11) through a row of tooth piece (12) meshing simultaneously.

5. A low energy quartz clock movement according to claim 1, characterized in that: the utility model discloses a frame, including fuselage (1), inside both ends of fuselage (1) are slotted slidable mounting has gag lever post (10), and four the structure of gag lever post (10) is equal to the outer end of four gag lever posts (10) all runs through and extends to the inside of two installation pieces (2).

6. The low energy quartz clock movement of claim 5, wherein: the two ends of the inside of the machine body (1) are respectively provided with a groove, the transmission gears (11) are rotatably arranged through the torsion springs (13), the four transmission gears (11) are symmetrically arranged about the vertical central line of the machine body (1), and the outer sides of the four transmission gears (11) are respectively connected with the limiting rods (10) through a row of tooth blocks (12) in a meshed mode.