KR20170137710A - Integrated sensor - Google Patents

Abstract

An integrated sensor comprising a pedestal (1) in which a sensor member is installed, characterized in that an upper cap (14) which can be independently operated in correspondence with the pedestal (1) is covered at the upper end of the pedestal And a compression spring 16 is installed between the pedestal 1 and the upper cap 14. The upper cap 14 interlocks with the sensor member in the pedestal 1 during downward pressing.
When the temperature of the inner cylinder 62 reaches the interference prevention set point, the contact piece A 33 and the contact piece B 34 cut off the connection, thereby blocking the main control panel circuit, , And the contact piece B (34) can energize the circuit again after the temperature has dropped; If the temperature exceeds the maximum extent of interference avoidance, the temperature sensing panel 43 will provide the final protection by forcing the heating circuit to shut down by way of dissolving the fuse shim 41 directly at high temperature by activating the fuse function ; The temperature sensing piece 37 and the insulation cradle 22 are stress-responsive parts, which can reduce the problem of deviation of the weld point of the leash line and increase the overall service life.

Description

Integrated sensor

The present invention relates to the field of temperature sensor control technology, and more particularly to an integrated sensor.

The Chinese patent CN201422761Y discloses a microswitch type interference prevention device, which comprises a mounting cup, a microswitch and a switch panel, the microswitch being installed in the mounting cup, the mounting cup being mounted on the switch panel A reset spring is provided between the mounting cup and the switch panel, and the switch panel is fixed on the mounting floor panel. In use, when the entire mounting cup moves downward, the microswitch turns the heating switch on the mounting floor panel, . On the heating circuit, the heat-sensitive parts are formed in series so as to cut off the heating circuit when the mounting cup is discharged.

In the structure thus designed, each working part and a mounting panel are integrally fixedly connected to each other. Under the pressure-driven operation of the inner cylinder, a vertical operation is performed to realize a pot-free inspection, There is a problem that contact failure occurs at each node.

It is an object of the present invention to propose a stable and long-life integrated sensor having a reasonable structure and a high degree of integration in order to solve the shortcomings and shortcomings of the existing technology.

The integrated sensor according to the present invention includes a pedestal, a sensor member is installed in the pedestal, and an upper cap is covered at the upper end of the pedestal so as to be independently operable in correspondence with the pedestal, A compression spring is installed between the pedestal and the upper cap; The upper cap interlocks with the sensor member in the pedestal during the downward pressing.

In addition, an annular mounting panel is provided on the outer edge of the lower end of the pedestal, an insulating cover is covered on the outer side of the pedestal, the lower end of the insulating cover and the mounting panel are fixedly connected and the compression spring is interposed between the insulating cover and the pedestal And the upper cap is movably connected to the insulating cover through the upper end entrance of the insulating cover and the upper and lower ends of the compression spring are installed in contact with and supported on the upper cap and the mounting panel respectively.

In addition, a locking ring is provided in the upper end opening of the insulating cover, a fixing ring is provided on the outer edge of the lower end of the upper cap, and the diameter of the outer edge of the fixing ring is larger than the diameter of the inner edge of the locking ring , And both upper and lower ends of the compression spring are installed so as to be held in contact with the stationary ring and the mounting panel, respectively.

In addition, a notch is formed on one side of the fixing panel, and the sensor member includes a thermosensitive part. The thermosensitive part passes through the notch of the fixing panel, Lt; / RTI > On the fixed panel, a fixing block for restricting the downward movement of the upper cap is provided.

Further, the thermosensitive component includes a thermosensitive resistor and an insulation cradle, the thermosensitive resistor is connected to the upper end of the insulation cradle, the lead wire on the thermosensitive resistor is installed through the insulation cradle,

The upper end of the insulation cradle is inserted through the notch of the fixing panel so that the thermal resistance is matched with the fixed block and the upper cap. A leaf spring is provided between the lower end of the insulation cradle and the pedestal.

In the pedestal, a diaphragm is installed laterally so that the inner space of the pedestal is divided into an upper cavity and a lower cavity, a panel is provided on the diaphragm, and an insulation cradle is provided on the pedestal Installed in the upper cavity;

On the panel, pillars corresponding to the insulation cradle are installed in the lateral direction, the leaf springs are covered on the pillars, and the upper and lower ends of the leaf spring are installed so as to be in contact with the lower end of the insulation cradle.

An upper fixing panel is provided at the upper end of the notch of the notch portion of the fixing panel, and the upper end of the insulating cradle and the upper fixing panel are connected to each other.

In addition, a mounting hole is formed in the upper end of the insulating cradle, and a structural hole is formed in a lower portion of the mounting hole. The diameter of the structural hole is smaller than the diameter of the mounting hole. The lower end of the thermosensitive resistor is inserted into the mounting hole and the lead wire of the thermosensitive resistor is inserted through the structure hole.

The sensor member further includes a micro switch fixedly installed in the pedestal and interlocked with the thermally conductive part.

Further, the microswitch includes a base, a wing plate, a second connection terminal A, a second connection terminal B, a contact piece C, and a tension spring;

The lower ends of the second connection terminal A and the second connection terminal B are fixedly connected to the base through the bottom panel of the base respectively and the upper ends of the second connection terminal A and the second connection terminal B are provided so as to correspond to each other, A hinge is provided laterally on the upper end of the second connection terminal B; The fixed end of the contact piece C is engaged with the upper end of the second connection terminal A and the contact piece C with the free end provided at the lower portion of the hinge is installed in the lateral direction;

The wing plate having one end hinged to the base is installed in a transverse direction and both ends of the tension spring are respectively connected to the other end of the wing plate and the contact piece C and the lower end of the insulation cradle contacts the other end of the wing plate As shown in Fig.

The base is fixedly installed in the lower cavity of the pedestal, and the lower end of the insulating cradle passes through the diaphragm and is connected to the wing plate in a non-contact manner.

Also, the sensor member may include an overheat cut-off device, a fuse device may be connected in parallel to the overheat cut-off device, and the overheat cut-off device and the fuse device may be installed to correspond to the upper cap through the fixed panel.

The upper heat shielding device includes a first connection terminal A, a first connection terminal B, a contact piece A, a contact piece B, and a ceramic bar, and the upper ends of the first connection terminal A and the first connection terminal B are fixed to a fixed panel And the lower ends of the first connection terminal A and the first connection terminal B are fixedly connected to the diaphragm through the diaphragm, respectively;

The fixed end of the contact piece A is connected to the upper end of the first contact terminal A and the fixed end of the contact piece B is connected to the upper end of the first contact terminal B. The free end of the contact piece A and the free end of the contact piece B Matched;

The lower end of the ceramic rod is disposed in contact with the free end of the contact piece B, and the upper end and the upper cap of the ceramic rod are matched to each other.

The fuse unit includes a fuse shim made of thermoplastic vinyl, a fuse hole is provided on the fixed panel, a fuse shim penetrates through the fuse hole, an upper end of the fuse shim and a top cap are installed to be matched with each other;

A fuse spring is provided between the lower end of the fuse core and the diaphragm, and a cutoff device matching the overheat cutoff device is provided between the lower end of the fuse core and the fuse spring.

The other end of the protrusion is provided to be in contact with the upper portion of the free end of the contact piece A so as to be supported thereon.

In addition, a coupling groove smaller than the diameter of the outer edge of the fuse core is provided on the fuse core.

In addition, a temperature sensing panel is installed at the upper end of the fuse core, the temperature sensing panel is operatively connected to the fixing panel, and the temperature sensing panel is installed to match the upper cap.

Further, a temperature sensing piece is provided between the fixing panel and the upper cap, and an elastic spring is connected to the temperature sensing piece and the fixing panel. The temperature sensing pieces are installed to be matched with the upper cap, the overheat cut-off device, and the fuse device, respectively.

The lower end of the elastic spring is fixedly connected to the fixed panel, and the upper end of the temperature sensing piece and the elastic spring are connected to each other and are inclinedly installed. The rising end of the temperature sensing piece is installed to match the upper cap, the overheat cut-off device, and the fuse device.

In addition, a locking groove is provided on the fixing panel, a curved insertion piece is provided on a lower edge of the elastic spring, and a locking groove is inserted in a lower end of the curved insertion piece to fixly connect the elastic spring on the fixing panel.

Further, the rising end of the temperature sensing piece is installed on the upper portion of the ceramic bar and the temperature sensing panel, and is installed on the lower portion of the upper cap.

Further, the liquid heater using the integrated sensor.

In the present invention, the structure is reasonable, and in use, the inner cap is pushed down to insert the upper cap. When the upper cap is pushed down, the insulated cradle continuously contacts the thermosensitive resistor and operates the microswitch to output a pot- At this time, the temperature sensing piece is brought into contact with the ceramic rod and the temperature sensing panel under the action of the upper cap to start the temperature monitoring, and the trip limiting panel controls the downward limit position of the upper cap so that the temperature of the inner cylinder is set to the anti- When the temperature reaches the upper limit of the temperature of the main control panel, the main control circuit breaks the circuit of the main control panel. The circuit may be energized again after the temperature has dropped; If the temperature exceeds the maximum extent of interference prevention, the temperature sensing panel realizes the final protection by forcing the heating circuit off by way of dissolving the fuse shim directly at high temperature by activating the fuse function; The temperature sensing element and the insulation cradle are stress response components, which reduce the problem of deviating the welding point of the lead wire and increase the overall service life.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an overall exploded view of the present invention; Fig.
Fig. 2 is an explanatory view of the exploded structure of the sensor member of the present invention. Fig.
3 is a structural explanatory view of the internal assembly of the present invention.
4 is a bird's-eye view showing the three-dimensional structure of the pedestal of the present invention.
5 is a diagram for explaining a simulation of an initial state trigger of the present invention.
6 is an enlarged structure explanatory view showing an enlarged portion A in Fig.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

1 to 6, the integrated sensor according to the present invention includes a pedestal 1, and a sensor member is installed in the pedestal 1. The pedestal 1 is provided with an upper cap 14 The pedestal 1 and the upper cap 14 can be operated independently corresponding to each other and a compression spring 16 is installed between the pedestal 1 and the upper cap 14; The upper cap 14 interlocks with and interlocks with the sensor member in the pedestal 1 during downward pressing; 5, the pedestal 1 is fixedly mounted in the electric heating vessel 61, the sensor member is electrically connected to the main control panel of the electric heating vessel 61, and the upper cap 14 is vertically And the upper cap 14 is provided so as to be in contact with the sensor member in the pedestal 1 in the initial state but not in contact with the heating panel 63. The inner cap 62 is electrically heated The upper cap 14 and the sensor member come into contact with the sensor member so as to realize the inspection with the pot and the heat generated by the heating panel 63 is transmitted to the upper cap 14, And the sensor member monitors the temperature rise condition of the inner cylinder and realizes overheat protection through the main control panel.

1, an annular mounting panel 11 is provided on the outer edge of the lower end of the pedestal 1, an insulating cover 12 is covered on the outer side of the pedestal 1, 12 and the mounting panel 11 are fixedly connected and the compression spring 16 is formed so as to be covered between the insulating cover 12 and the pedestal 1 and the upper cap 14 is fixed to the insulating cover 12, And the upper and lower ends of the compression spring 16 are installed to be in contact with and supported on the upper cap 14 and the mounting panel 11, respectively; The upper cap 14 is movable up and down along the inner edge of the insulating cover 12, thereby preventing the problem of the triggering caused by the lateral deviation from being lost; The pedestal (1) and the sensor member are fixedly mounted by connecting the mounting panel (11) and the electric heating vessel (61).

A locking ring 13 is provided in the upper end entrance of the insulating cover 12 and a fixing ring 15 is provided on the outer edge of the lower end of the lower end of the upper cap 14, The diameter of the compression spring 16 is larger than the diameter of the inner edge of the locking ring 13. The upper and lower ends of the compression spring 16 are respectively installed to be held in contact with the fixing ring 15 and the mounting panel 11, 16 serve as a buffer when the upper cap 14 is pushed down and provide a supporting force when the upper cap 14 is rebounded and the locking ring 13 and the fixing ring 15 cooperate with each other, (Up) limit range of the terminal 14.

A notch is formed in one side of the fixing panel 17, and the sensor member includes a thermosensitive part. The thermosensitive part is fixed to a fixing panel (not shown) 17), the thermally conductive parts and the pedestal (1) being operatively connected; On the fixed panel 17, a fixing block 191 for limiting the downward movement of the upper cap 14 is installed; The downward process of the upper cap 14 includes an approach process and a trigger process. The upper cap 14 is installed so as to correspond to the sensor member in the initial state but not to be in contact with the sensor member in the pedestal 1, 14 are pressed downward to be in contact with the thermal member in the proximity process and the upper cap 14 is pressed down to enter the trigger process and the thermal parts are moved down together. When the trigger process is finished, (14) is in contact with the fixing block (191). At this time, the thermosensitive part enters the temperature control protection mode.

The thermally sensitive component includes a thermally sensitive resistor 21 and an insulating cradle 22 wherein the thermally sensitive resistor 21 is connected to the upper end of the insulating cradle 22 so that the lead wire on the thermally- Is installed in the housing; A mounting hole 23 is formed in the upper end of the insulating cradle 22 and a structure hole 24 is formed in a lower portion of the mounting hole 23. The diameter of the structure hole 24 is set to a mounting hole And an opening 25 penetrating through the mounting hole 23 and the structure hole 24 is formed on the front end of the side surface of the insulating cradle 22. The heat insulating resistor 21 The lower end portion is inserted into the mounting hole 23 and the lead wire of the thermosensitive resistor 21 is inserted through the structure hole 24 so that the efficiency of replacing the thermosensitive resistor 21 or the lead wire .

The upper end of the insulation cradle 22 passes through the notch of the fixing panel 17 to allow the thermal resistance 21 to be installed to match the fixing block 191 and the upper cap 14, A leaf spring 26 is installed between the lower end of the pedestal 1 and the pedestal 1; A diaphragm 18 is provided in the pedestal 1 in the transverse direction to divide the inner space of the pedestal 1 into an upper cavity and a lower cavity. A panel 181 is provided on the diaphragm 18, (22) is installed in an upper cavity of a pedestal (1) located on one side of the panel (181) so as to be movable up and down; A column 182 corresponding to the insulating cradle 22 is installed on the panel 181 in a transverse direction. The leaf spring 26 is formed on the column 182 and covers the leaf spring 26 The upper and lower ends of the insulating cradle 22 and the diaphragm 18 are disposed so as to be in contact with the lower end of the insulating cradle 22, respectively; An upper fixing panel 184 is provided at the upper end entrance of the notch 1 of the notch portion of the fixing panel 17 and the upper end of the insulating cradle 22 is connected to the upper fixing panel 184 in a contacted manner; The plate spring 26 provides a buffering force and a rising bearing force downward to the insulating cradle 22 and is provided on the inner wall of the pedestal 1 located at the front and rear ends of the diaphragm 18, And the insulating cradle 22 moves up and down in the pedestal 1 to maintain a close contact between the thermal resistance 22 and the upper cap 14 when the upper cap 14 is pressed Thus, it is possible to prevent the risk that the sensor failure due to thermal conduction interruption and the overheat protection will be lost.

The sensor member further includes a micro switch. The micro switch is fixedly installed in the pedestal 1 and is installed to be interlocked with the thermoelectric part. The upper cap 14 is disposed below the insulating cradle 22 A push rod is provided at the lower end of the insulating cradle 22 and the lower end of the push rod is brought into contact with the micro switch so that the micro switch outputs a pot existence signal.

The micro switch includes a base 57, a wing plate 51, a second connection terminal A 52, a second connection terminal B 53, a contact piece C 55 and a tension spring 56; The lower ends of the second connection terminal A 52 and the second connection terminal B 53 are fixedly connected to the base 57 through the bottom panel of the base 57 and the second connection terminals A 52, And the upper end of the second connection terminal B 53 are provided so as to correspond to each other, and the hinge 54 is installed laterally at the upper end of the second connection terminal B 53; The fixed end of the contact piece C 55 is engaged with the upper end of the second connection terminal A 52 and the contact piece C 55 is provided in the lateral direction, ; One end of the wing plate 51 is hinged to the base 57 and the other end of the tension spring 56 is connected to the other end of the wing plate 51 And the lower end of the insulating cradle 22 is engaged on the other end of the wing plate 51; The base 57 is fixedly installed in the lower cavity of the pedestal 1 and the lower end of the insulating cradle 22 penetrates the diaphragm 18 and is connected to the wing plate 51 in a non-contact manner.

The second contact terminal A 52 and the second contact terminal B 53 constitute the terminals of the positive electrode and the free end of the contact piece C 55 and the hinge 54 are close to each other Contacts are formed on the mating surfaces of the contact pieces C (55) and the hinges (54) to improve the stability of the electrical connection; When the upper cap 14 is depressed to enter the trigger process, the insulation cradle 22 pushes the wing plate 51 downward and the contact piece C 55 is moved up and down under the action of the tension spring 56 The free end of the contact piece C 55 has a state change such that the free end of the contact piece C 55 contacts or separates from the hinge 54 and causes the terminal of the positive electrode of the microswitch to output a potsense signal; On the contrary, when the upper cap 14 is reset, under the action of the tension spring 56, the wing plate 51 rotates in the opposite direction upward so that the free end of the contact piece C 55 is rotated by the hinge 54, So that the terminal of the positive electrode of the microswitch can output the no-pot signal.

The overheat cut-off device and the fuse device are respectively connected to the upper cap (14) through the fixed panel, and the overheat cut-off device and the fuse device are connected to the over- Respectively.

The overheat cut-off device includes a first connection terminal A 31, a first connection terminal B 32, a contact piece A 33, a contact piece B 34 and a ceramic bar 35, The upper ends of the terminal A 31 and the first connection terminal B 32 are installed in the upper cavity of the pedestal 1 located between the fixed panel 17 and the diaphragm 18 and the first connection terminals A 31 and The lower end of the first connection terminal B (32) is fixedly connected to the diaphragm (18) through the diaphragm (18), respectively; The fixed end of the contact piece A 33 is connected to the upper end of the first contact terminal A 31 and the fixed end of the contact piece B 34 is connected to the upper end of the first contact terminal B 32, The free end of the piece A 33 and the free end of the contact piece B 34 are installed in a matching manner; The lower end of the ceramics rod 35 is disposed in contact with the free end of the contact piece B 34 and is supported by the ceramics rod 35, The upper end and the upper cap 14 are matched and installed.

As shown in Fig. 2, the free ends of the contact piece A 33 and the contact piece B 34 provided at different heights are vertically formed to correspond to each other to form an operation opening / closing mechanism, A trigger mechanism connected to the contact piece A 33 is provided on the fixed panel 17 and a detailed description of the trigger mechanism will be given later ; When the upper cap 14 enters the contact progress process, the trigger member is actuated to deform the contact piece A 33. When the upper cap 14 comes into contact with the fixed block 191 and ends the process, The mechanism operates the contact piece A 33 to urge the contact piece B 34 to be energized. At this time, the upper cap 14 and the ceramic 35 are in contact with each other, and the microswitch outputs a pot- The heating circuit of the main control panel connected to the first contact terminal A 31 and the first contact terminal B 32 is energized and the heating panel 63 is activated to start heating the inner cylinder 62, The temperature rise of the contact piece B 34 is conducted to the contact piece B 34 through the upper cap 14 and the ceramic bar 35 so that the temperature rise value of the contact piece B 34 reaches the deformation temperature, The contact piece A 33 and the contact piece B 34 are disconnected from each other to block the heating circuit of the main control panel, To stop the heating operation.

The fuse unit includes a fuse shim 41 made of thermoplastic vinyl. A fuse hole 183 is provided on the fixed panel 17 and a fuse shim 41 is installed through the fuse hole 183 , The upper end of the fuse shim (41) and the upper cap (14) are installed in a matching manner; A fuse spring 42 is provided between the lower end of the fuse shim 41 and the diaphragm 18 and a cutoff device matching the overheat cutoff device is installed between the lower end of the fuse shim 41 and the fuse spring 42 ; One end of the protrusion 44 is fixedly connected to the upper end of the fuse spring 42 and the other end of the protrusion 44 is connected to the free end of the contact piece A 33, As shown in Fig.

In the above description, the trigger mechanism of the overheat cut-off device is also the fuse shim 41, thereby realizing the parallel connection protection function of the overheat cut-off device and the fuse device through the heat melting property of the fuse shim 41; When the upper cap 14 enters the trigger process, the upper cap 14 operates the fuse shim 41 and pushes down along the fuse hole 183, and the fuse spring 42 contacts the fuse shim 41, The fuse spring 42 is depressed and contracted by the fuse shim 41 and the shutoff device at the upper end of the fuse spring 42 is deformed by operating the contact piece A 33, The free end of the piece A 33 is brought into contact with the contact piece B 34 in the downward direction to energize thereby activating the protective function of the overheat cut-off device; When the temperature rise of the inner cylinder 62 is excessively high, the temperature at which the upper cap 14 conducts to the fuse shim 14 exceeds its melting value. Therefore, when the fuse shim 14 melts and the fuse spring 42 And the blocking device rises at the same time to be restored to the deformation of the contact piece A 33 and connected to the contact piece B 34.

An engaging groove 411 which is smaller than the diameter of the outer edge of the fuse shim 41 is provided on the upper portion of the fuse shim 41. When the temperature rise of the fuse shim 41 exceeds the melting value, It is possible to improve the response to the overheating protection and to prevent the corresponding time of the fuse device from becoming excessively long under a sudden increase in the temperature so as to prevent the overall burning of the electric heating container 61 or the risk of fire prevent.

A temperature sensing panel 43 is installed at an upper end of the fuse shim 41 and a temperature sensing panel 43 and a fixed panel 17 are operatively connected to each other. Matched; The temperature sensing panel 43 is used to limit the upward limit range of the fuse shim 41. In order to improve the buffering force and the reset supporting force of the fuse spring 42 during assembly, And the fuse shim 41 is movably mounted in the fuse hole 183 by the temperature sensing panel 43 so as to be movable upward and downward.

A temperature sensing piece 37 is provided between the fixing panel 17 and the upper cap 14. An elastic spring 36 is connected to the temperature sensing piece 37 and the fixing panel 17; The temperature sensing piece 37 is installed to be matched with the upper cap 14, the overheat cutoff device, and the fuse device, respectively; 3, when the upper cap 14 enters the approaching process, the upper tab 14 comes into contact with the temperature sensing piece 37 and further the upper tab 14 touches the thermosensitive resistor 21 and the temperature sensing piece 37, The upper cap 14 is completely brought into contact with the temperature sensing piece 37 and the temperature sensing part 37 is brought into contact with the temperature sensing part 37. When the upper cap 14 is in contact with the fixing block 191, The piece 37 is in contact with the temperature sensing panel 43 and the ceramic bar 35 to conduct a temperature rise; The temperature sensing piece 37 and the elastic spring 36 can improve the accuracy of the triggering of the upper cap 14 and the heat conduction efficiency.

The lower edge of the elastic spring 36 and the fixing panel 17 are fixedly connected and the temperature sensing piece 37 and the elastic spring 36 are fixedly connected to each other. 36) are connected and sloped; The rising end of the temperature sensing piece 37 is installed to match the upper cap 14, the overheat cut-off device, and the fuse device. The rising end of the temperature sensing piece 37 is installed on the upper portion of the ceramic bar 35 and the temperature sensing panel 43 and is installed on the lower portion of the upper cap 14.

A locking groove 171 is provided on the fixed panel 17 and a curved insertion piece 361 is provided on the lower edge of the elastic spring 36. A locking groove 171 is formed in the lower end of the curved insertion piece 361, Is inserted to fixedly connect the elastic spring 36 to the fixed panel 17; The curved insertion portion 361 and the engagement groove 171 are matched and connected to each other to improve the mounting and height adjustment efficiency of the elastic spring 36 and the temperature sensing piece 37.

The liquid heater using the integrated sensor includes an electromagnetic cooker, a stewer, and an electric pressure cooker.

The foregoing description is only a comparatively preferred embodiment of the present invention, and all of the equivalent modifications or equations based on the above structure, feature and principle according to the claims of the present invention are included in the claims of the present invention.

1: pedestal 11: mounting panel
12: insulating cover 13:
14: upper cap 15: retaining ring
16: Compression spring 17: Fixed panel
18: diaphragm 21: thermal resistance
22: Insulation cradle 23: Mounting hole
24: Structure hole 25:
26: leaf spring 31: first connection terminal A
32: first connection terminal B 33: contact piece A
34: Contact piece B 35: Ceramic rod
36: Elastic spring 37: Temperature sensing piece
41: fuse core 42: fuse spring
43: temperature sensing panel 44: projection
51: Wing plate 52: Second connection terminal A
53: second connection terminal B 54: hinge
55: contact piece C 56: tension spring
57: base 61: electric heating container
62: inner tube 63: heating panel
171: Retaining groove 181: Panel
182: column 183: fuse hole
184: upper fixing panel 191: fixing block
361: Curved insertion piece 411: Coupling groove

Claims (22)

1. An integrated sensor comprising a pedestal (1) in which a sensor member is installed,
The upper end of the pedestal 1 is covered with an upper cap 14 which can be independently operated in correspondence with the pedestal 1 and a compression spring 16 is installed between the pedestal 1 and the upper cap 14. [ Is installed; Wherein the upper cap (14) interlocks with the sensor member in the pedestal (1) in the process of being pressed down. The method according to claim 1,
An annular mounting panel 11 is provided on the outer edge of the lower end of the pedestal 1 and an insulating cover 12 is disposed on the outer side of the pedestal 1, The panel 11 is fixedly connected and the compression spring 16 is configured to be covered between the insulating cover 12 and the pedestal 1 and the upper cap 14 penetrates through the upper end entrance of the insulating cover 12 And the upper and lower ends of the compression spring 16 are installed to be in contact with and supported on the upper cap 14 and the mounting panel 11, respectively. 3. The method of claim 2,
A locking ring 13 is provided in the upper end entrance of the insulating cover 12 and a fixing ring 15 is provided on the outer edge of the lower end of the lower end of the upper cap 14, And the diameter of the compression spring 16 is larger than the diameter of the inner edge of the locking ring 13. The upper and lower ends of the compression spring 16 are installed in contact with the fixing ring 15 and the mounting panel 11, Integrated sensor. The method according to claim 1,
A stationary panel 17 is provided at one side of the pedestal 1 and formed with a notch formed thereon. The sensor member passes through the notch of the stationary panel 17 to be movable with respect to the pedestal 1 Comprising a thermally conductive part to be connected; Wherein a fixing block (191) for limiting the downward movement of the upper cap (14) is provided on the fixed panel (17). 5. The method of claim 4,
The thermosensitive component includes a thermosensitive resistor 21 and an insulation cradle 22 and the thermosensitive resistor 21 is connected to the upper end of the insulation cradle 22. The lead wire on the thermosensitive resistor 21 is connected to the insulation cradle 22 );
The upper end of the insulation cradle 22 penetrates the notch of the fixing panel 17 and is installed so that the thermal resistance 21 is matched with the fixing block 191 and the upper cap 14. The lower end of the insulation cradle 22 And a leaf spring (26) is provided between the pedestal (1) and the pedestal (1). 6. The method of claim 5,
A partition 18 is horizontally disposed in the pedestal 1 so that the inner space of the pedestal 1 is divided into an upper cavity and a lower cavity. A panel 181 is provided on the partition 18, (22) is installed in an upper cavity of a pedestal (1) located on one side of the panel (181) so as to be movable up and down;
A column 182 corresponding to the insulation cradle 22 is installed on the panel 181 in a transverse direction and the plate spring 26 is formed on the column 182 and covered with the plate spring 26 Wherein the upper and lower ends of the insulating cradle (22) are installed in contact with the lower end of the insulating cradle (22) and the diaphragm (18), respectively. The method according to claim 6,
An upper fixing panel 184 is provided at the upper end entrance of the notch of the notch portion of the fixing panel 17 and an upper end of the insulating cradle 22 is connected to the upper fixing panel 184 in a non- Integrated sensor. 8. The method according to any one of claims 5 to 7,
A mounting hole 23 is formed in the upper end of the insulating cradle 22 and a structure hole 24 is formed in a lower portion of the mounting hole 23. The diameter of the structure hole 24 is set to a mounting hole And an opening 25 penetrating through the mounting hole 23 and the structure hole 24 is formed on the front end of the side surface of the insulating cradle 22. The opening 25 of the heat insulating resistor 21 And the lower end portion is inserted into the mounting hole (23), and the lead wire of the thermosensitive resistor (21) is inserted through the structure hole (24). 5. The method of claim 4,
Wherein the sensor member further comprises a micro switch fixedly installed in the pedestal (1) and interlocked with the thermally conductive part. 10. The method of claim 9,
The micro switch includes a base 57, a wing plate 51, a second connection terminal A 52, a second connection terminal B 53, a contact piece C 55 and a tension spring 56;
The lower ends of the second connection terminal A 52 and the second connection terminal B 53 are fixedly connected to the base 57 through the bottom panel of the base 57 and the second connection terminals A 52, And the upper end of the second connection terminal B 53 are provided so as to correspond to each other, and the hinge 54 is installed laterally at the upper end of the second connection terminal B 53; The fixed end of the contact piece C 55 is engaged with the upper end of the second connection terminal A 52 and the contact piece C 55 having the free end provided at the lower portion of the hinge 54 is installed in the lateral direction ;
The wing plate 51 hinged to the base 57 is provided laterally and both ends of the tension spring 56 are respectively connected to the other end of the wing plate 51 and the contact piece C 55 , And the lower end portion of the insulating cradle (22) is installed in contact with and supported on the other end of the wing plate (51). 11. The method of claim 10,
The base 57 is fixedly installed in the lower cavity of the pedestal 1 and the lower end of the insulating cradle 22 is connected to the wing plate 51 through the diaphragm 18 in a non- . 5. The method of claim 4,
The overheat cut-off device and the fuse device are respectively installed on the overheat cut-off device and the fuse device in parallel. The overheat cut-off device and the fuse device are respectively connected to the upper cap And the sensor is installed. 13. The method of claim 12,
The overheat cut-off device includes a first connection terminal A 31, a first connection terminal B 32, a contact piece A 33, a contact piece B 34 and a ceramic bar 35, A 31 and the first connection terminal B 32 are installed in the upper cavity of the pedestal 1 located between the fixed panel 17 and the diaphragm 18 and the first connection terminals A 31 and 1 connection terminal B 32 are fixedly connected to the diaphragm 18 through the diaphragm 18, respectively;
The fixed end of the contact piece A 33 is connected to the upper end of the first contact terminal A 31 and the fixed end of the contact piece B 34 is connected to the upper end of the first contact terminal B 32, The free end of the piece A 33 and the free end of the contact piece B 34 are installed in a matching manner;
The lower end of the ceramic bar 35 is installed to be in contact with the free end of the contact piece B 34 and supported by the ceramic bar 35, And the upper end of the upper cap and the upper cap are matched to each other. 13. The method of claim 12,
The fuse unit includes a fuse shim 41 made of thermoplastic vinyl. A fuse hole 183 is provided on the fixed panel 17. The fuse shim 41 is installed in the fuse hole 183, The upper end of the fuse shim 41 and the upper cap 14 are installed in a matching manner;
A fuse spring 42 is provided between the lower end of the fuse shim 41 and the diaphragm 18 and a cutoff device matching the overheat cutoff device is installed between the lower end of the fuse shim 41 and the fuse spring 42 Wherein the integrated sensor comprises: 15. The method of claim 14,
The other end of the protrusion 44 is connected to the free end of the contact piece A 33. The other end of the protrusion 44 is connected to the free end of the contact piece A 33, Wherein the sensor is mounted so as to be in contact with the upper part. 15. The method of claim 14,
Wherein an engagement groove (411) smaller than the diameter of the outer edge of the fuse core (41) is provided on the fuse core (41). 15. The method of claim 14,
A temperature sensing panel 43 is installed at an upper end of the fuse shim 41 and a temperature sensing panel 43 is movably connected to a fixing panel 17. A temperature sensing panel 43 is connected to the upper cap 14 Wherein the sensor is mounted in a matching manner. 13. The method of claim 12,
A temperature sensing piece 37 is provided between the fixing panel 17 and the upper cap 14 and an elastic spring 36 is connected to the temperature sensing piece 37 and the fixing panel 17; Wherein the temperature sensing piece (37) is installed to be matched with the upper cap (14), the overheat cutoff device and the fuse device, respectively. 19. The method of claim 18,
The lower edge of the elastic spring 36 and the fixing panel 17 are fixedly connected and the temperature sensing piece 37 and the elastic spring 36 are fixedly connected to each other. 36) are connected and sloped; Wherein the rising end of the temperature sensing piece (37) is installed to match the top cap (14), the overheat cutoff device and the fuse device. 20. The method of claim 19,
A locking groove 171 is provided on the fixed panel 17 and a curved insertion piece 361 is provided on the lower edge of the elastic spring 36. A locking groove 171 is formed in the lower end of the curved insertion piece 361, Is inserted to fixably connect the elastic spring (36) on the fixed panel (17). 20. The method of claim 19,
Wherein the rising end of the temperature sensing piece 37 is installed at an upper portion of the ceramic bar 35 and the temperature sensing panel 43 and is installed at a lower portion of the upper cap 14. [ A liquid heater characterized by comprising an integration sensor according to any one of claims 1 to 7 and 9 to 21.

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