Ignition gun electrode sparking detection device
By designing an ignition gun electrode ignition detection device, which uses a probe to observe the ignition status and combines angle adjustment and cleaning of the drive components, the problem of cumbersome and potentially dangerous judgment of the ignition status of the ignition gun is solved, and safe and accurate ignition observation and cleaning are achieved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- HUANENG (SHANGHAI) POWER MAINTENANCE LLC
- Filing Date
- 2024-06-19
- Publication Date
- 2026-06-26
AI Technical Summary
In existing technologies, judging the ignition status of the ignition gun electrode is cumbersome and there is a risk of improper insertion position and depth, which affects the success of furnace ignition.
An ignition gun electrode ignition detection device was designed, including a detection mechanism and an adjustment mechanism. The ignition status is observed by inserting a probe into the furnace, and the probe angle and cleaning are controlled by an angle adjustment component and a cleaning drive component to avoid ash and slag affecting the imaging.
It enables accurate judgment of the ignition status of the ignition gun without personnel entering the furnace, reducing operational risks, ensuring normal use of the ignition gun, and enabling accurate observation and cleaning of the ignition chamber under different conditions.
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Figure CN118654307B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of ignition gun testing, and in particular to an ignition gun electrode spark detection device. Background Technology
[0002] In the routine maintenance of the burner ignition system of current coal-fired power units, detecting the success of ignition gun electrode ignition is a crucial step. Currently, judging the ignition status relies on sound, testing the ignition gun outside, or having someone enter the furnace to observe. These methods are cumbersome, and improper insertion position or depth during reinstallation can affect furnace ignition success, posing certain safety risks. Therefore, an ignition gun electrode ignition detection device is proposed. Summary of the Invention
[0003] In view of the problems existing in the prior art, the present invention is proposed.
[0004] Therefore, the present invention aims to solve the problem in the prior art that it is inconvenient to judge the ignition status of the ignition gun.
[0005] To solve the above-mentioned technical problems, the present invention provides the following technical solution: a lighter electrode ignition detection device, comprising a detection mechanism including a handle, a connector located at the top of the handle, a cover located outside the connector, a probe located inside the cover, and a base plate located on the inner wall of the cover; and...
[0006] The adjustment mechanism includes a bracket located inside the grip bar, a control component on the outside of the bracket, an angle adjustment component on one side of the control component, a pull rope connected to the outer end of the angle adjustment component, a reverse helical toothed ring on the outside of the bracket, a retaining spring on the outer end face of the angle adjustment component, an adjustment groove on the surface of the bracket, a cleaning drive component on the other side of the control component, a tension rope on the outside of the cleaning drive component, a cleaning component connected to the other end of the tension rope, a compensation component on the lower outer wall of the cleaning component, an elastic component on the outside of the cleaning component, and a positioning component on the inner side of the elastic component.
[0007] In a preferred embodiment of the ignition gun electrode ignition detection device of the present invention, the connecting member includes a connecting seat fixed to the top of the handle, a connecting head movably connected to the inner side of the connecting seat, and a torsion spring installed between the connecting seat and the connecting head.
[0008] In a preferred embodiment of the ignition gun electrode ignition detection device of the present invention, the control component includes a free disk movably disposed in the middle section of the bracket. The free disk has a movable cavity inside, and a lever is disposed inside the movable cavity. The lever extends to the outside of the free disk, and a correction spring is sleeved on the exposed end of the lever. The correction spring is fixed to the free disk. A pin is vertically inserted through the inside of the lever, and pin seats are connected to both ends of the pin. Both pin seats are fixed to the surface of the free disk.
[0009] As a preferred embodiment of the ignition gun electrode ignition detection device of the present invention, wherein: the angle adjustment component includes a first lever plate disposed on the outside of the free disk, the first lever plate having an adjustment slot on one end face near the free disk, a locking seat being embedded on the other end face of the free disk, a limiting ring being connected to the outside of the locking seat, a helical toothed ring being fixed on the inner surface of the limiting ring, a sliding sleeve being disposed on the inner side of the first lever plate, a telescopic spring being disposed inside the sliding sleeve, and an extension post being connected to one end of the telescopic spring;
[0010] The oblique toothed ring and the reverse oblique toothed ring are meshed together.
[0011] The sliding sleeve and the adjusting groove are in a sliding fit.
[0012] In a preferred embodiment of the ignition gun electrode ignition detection device of the present invention, the adjustment groove includes a sliding groove formed on the surface of the bracket, one end of the sliding groove is connected to a switching groove, and the other end of the switching groove is connected to a reset groove.
[0013] As a preferred embodiment of the ignition gun electrode ignition detection device of the present invention, the switching groove is inclined and the reset groove is arranged in a zigzag shape;
[0014] The bottom surfaces of both the switching slot and the reset slot are lower than the sliding slot, and the bottom of the end of the reset slot that connects to the sliding slot is inclined.
[0015] As a preferred embodiment of the ignition gun electrode ignition detection device of the present invention, the cleaning drive component includes a second deflector plate movably disposed outside the bracket, and the second deflector plate has a cleaning slot on the end face near the free disk.
[0016] As a preferred embodiment of the ignition gun electrode ignition detection device of the present invention, the cleaning component includes a rotating ring located inside the cover cylinder. The surface of the rotating ring is provided with a plurality of positioning posts arranged in a ring array. The exterior of the plurality of positioning posts is rotatably connected to a scraper. A positioning head is provided inside the opening at the front end of the scraper. A limiting groove that cooperates with the positioning head is left on the outer periphery of the surface of the positioning post. A slope plate is also provided on the side wall of the rotating ring.
[0017] The compensation component includes a push plate disposed on the lower outer wall of the rotating ring, a buffer spring connected to the outer side of the push plate, and a stop plate connected to the other end of the buffer spring, the stop plate being fixed to the elastic component.
[0018] As a preferred embodiment of the ignition gun electrode ignition detection device of the present invention, the elastic element includes a rotating seat disposed outside the rotating ring, a side ring disposed on the inner side of the rotating seat, an extension opening provided on the side ring for cooperating with the scraper, a coil spring fixed to the outer wall of the rotating seat, and the other end of the coil spring fixed to the inner wall of the cover.
[0019] In a preferred embodiment of the ignition gun electrode ignition detection device of the present invention, the positioning component includes a support plate fixed to the outer wall of the side ring, an insert rod passing through the inside of the support plate, a top spring installed between the support plate and the insert rod, and an extension plate provided on the top outer wall of the insert rod.
[0020] The beneficial effects of this invention are as follows: By extending the probe into the furnace, the ignition status of the ignition gun can be observed from outside the furnace using its imaging function, without the need for personnel to enter or remove the ignition gun, ensuring the normal use of the ignition gun and reducing operational risks. Furthermore, with the control components working in conjunction with the angle adjustment components and the cleaning drive components, the probe angle and the use of the cleaning components can be controlled separately, allowing users to freely adjust the angle of the probe located inside the furnace. This ensures accurate observation of the ignition status of the ignition chamber under different conditions. At the same time, the probe surface can be cleaned in real time during use using the cleaning components, preventing the front of the probe from being affected by ash and slag in the furnace, which would cause blurred imaging. Attached Figure Description
[0021] To more clearly illustrate the technical solutions of the embodiments of the present invention, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort. Wherein:
[0022] Figure 1 This is a schematic diagram of the structure of an ignition gun electrode ignition detection device according to an embodiment of the present invention;
[0023] Figure 2 A cross-sectional structural schematic diagram of an ignition gun electrode ignition detection device according to an embodiment of the present invention;
[0024] Figure 3 A schematic diagram of the internal structure of an ignition gun electrode ignition detection device according to an embodiment of the present invention is provided.
[0025] Figure 4This is a partial exploded structural diagram of the adjustment mechanism in the ignition gun electrode ignition detection device according to an embodiment of the present invention;
[0026] Figure 5 A schematic diagram of the fitting structure between the adjusting groove and the sliding sleeve in an embodiment of the ignition gun electrode ignition detection device provided by the present invention;
[0027] Figure 6 A schematic diagram of the exploded structure inside the cover of the ignition gun electrode ignition detection device according to an embodiment of the present invention;
[0028] Figure 7 This is a schematic diagram of the positioning component in an ignition gun electrode ignition detection device according to an embodiment of the present invention.
[0029] In the diagram: 100, Detection mechanism; 101, Grip; 102, Connector; 102a, Connecting seat; 102b, Connecting head; 102c, Torsion spring; 103, Cover; 104, Probe; 105, Base plate; 200, Adjustment mechanism; 201, Bracket; 202, Control component; 202a, Free disc; 202b, Movable cavity; 202c, Lever; 202d, Correction spring; 202e, Pin; 202f, Pin seat; 203, Angle adjustment component; 203a, First lever; 203b, Adjustment bayonet; 203c, Locking seat; 203d, Restriction ring; 203e, Sloping gear ring; 203f, Sliding sleeve; 203g, Telescopic spring; 203h, Extension column; 204, Pull rope; 205, Reverse gear ring; 206 207. Tensioning spring; 207a. Adjustment groove; 207b. Sliding groove; 207c. Switching groove; 207c. Reset groove; 208. Cleaning drive component; 208a. Second dial plate; 208b. Cleaning bayonet; 209. Tensioning rope; 210. Cleaning component; 210a. Rotary ring; 210b. Positioning post; 210c. Scraper; 210d. Positioning head; 210e. Limiting groove; 210f. Slope plate; 211. Compensating component; 211a. Push plate; 211b. Buffer spring; 211c. Abutment plate; 212. Elastic component; 212a. Rotating seat; 212b. Side ring; 212c. Extension opening; 212d. Coil spring; 213. Positioning component; 213a. Support plate; 213b. Insert rod; 213c. Top spring; 213d. Extension plate. Detailed Implementation
[0030] To make the above-mentioned objects, features and advantages of the present invention more apparent and understandable, the specific embodiments of the present invention will be described in detail below with reference to the accompanying drawings.
[0031] Many specific details are set forth in the following description in order to provide a full understanding of the invention. However, the invention may also be practiced in other ways different from those described herein, and those skilled in the art can make similar extensions without departing from the spirit of the invention. Therefore, the invention is not limited to the specific embodiments disclosed below.
[0032] Secondly, the present invention will be described in detail with reference to the schematic diagrams. When detailing the embodiments of the present invention, for ease of explanation, the cross-sectional views illustrating the device structure will be partially enlarged, not according to the usual scale. Furthermore, the schematic diagrams are merely examples and should not limit the scope of protection of the present invention. In addition, actual fabrication should include three-dimensional spatial dimensions of length, width, and depth.
[0033] Furthermore, the term "an embodiment" or "embodiment" as used herein refers to a specific feature, structure, or characteristic that may be included in at least one implementation of the present invention. The phrase "in one embodiment" appearing in different places throughout this specification does not necessarily refer to the same embodiment, nor is it a single or selective embodiment that mutually excludes other embodiments.
[0034] Example 1
[0035] Reference Figure 1-2 This embodiment provides a device for detecting the arcing of an ignition gun electrode.
[0036] The ignition gun electrode ignition detection device includes a detection mechanism 100.
[0037] Specifically, the testing mechanism includes a handgrip 101 for user hand-held use. The handgrip 101 is hollow, and a connector 102 is fixedly installed on the top of the handgrip 101. The connecting end of the connector 102 is equipped with a hollow cover 103 with a front opening. A probe 104 for extending into the furnace is installed inside the cover 103. The probe 104 can observe and judge the ignition status of the lighter inside the furnace.
[0038] Example 2
[0039] Reference Figure 1-5 This is the second embodiment of the present invention, which is based on the previous embodiment and differs from the previous embodiment in that:
[0040] The ignition gun electrode ignition detection device also includes a connecting mechanism 200.
[0041] Specifically, the connector 102 includes a connector 102a fixed to the top of the grip 101, a connector 102b movably connected to the inner side of the connector 102a, and a torsion spring 102c installed between the connector 102a and the connector 102b. The torsion spring 102c can maintain the angle between the connector 102a and the connector 102b according to its own elasticity.
[0042] The adjustment mechanism 200 includes a bracket 201 fixed inside the handle 101. The bracket 201 is formed by a horizontal round rod connected to two side plates, and the lower surface of the handle 101 has an opening. A control component 202 is movably sleeved on the middle section of the bracket 201. An angle adjustment component 203 is provided on one side of the control component 202. A pull rope 204 is connected to the outer distal end of the angle adjustment component 203, and the other end of the pull rope is fixed to the bottom of the connector 102b. Thus, when the pull rope 204 moves, it can pull the connector 102b to rotate. It counteracts the force of the torsion spring 102c on the outside of the connector 102b, so that the rotation angle of the connector 102b is maintained. The bracket 201 is also fixedly fitted with a reverse helical toothed ring 205 that cooperates with the angle adjustment component 203. At the same time, a retaining spring 206 is provided on the outer end face of the angle adjustment component 203. The retaining spring 206 can support the angle adjustment component 203 through its own elasticity, so that the angle adjustment component 203 maintains a stable cooperation with the reverse helical toothed ring 205. The surface of the bracket 201 is also provided with an adjustment groove 207.
[0043] Furthermore, the control component 202 includes a free disk 202a movably disposed in the middle section of the bracket 201. The free disk 202a can rotate freely on the bracket 201. A movable cavity 202b is provided inside the free disk 202a on the side corresponding to the external opening of the grip 101. A lever 202c with a ball head is movably embedded inside the movable cavity 202b. A pin 202e is vertically inserted through the inside of the lever 202c. Both ends of the pin 202e are connected to pin seats 202f. Both pin seats 202f are fixed to the free disk. The surface of 202a allows the lever 202c to swing left and right along the setting direction of the bracket 201, thus cooperating with the angle adjustment component 203. At the same time, the lever 202c extends to the outside of the free disk 202a, and the exposed end is fitted with a correction spring 202d fixed to the outer surface of the free disk 202a. The correction spring 202d can affect the lever 202c through its own elasticity. When the lever 202c swings, the deformation recovery of the correction spring 202d can cause the lever 202c to return to the middle position.
[0044] The angle adjustment component 203 includes a first lever plate 203a disposed on the outside of the free disk 202a. The first lever plate 203a is also rotatably sleeved on the round rod of the bracket 201. The first lever plate 203a is composed of a rod-shaped plate and a ring. The pull rope 204 is fixed to one end of the rod-shaped plate of the first lever plate 203a. Thus, when the first lever plate 203a rotates, its rod-shaped plate can pull the pull rope 204. Furthermore, an adjustment slot 203b is provided on the end face of the first lever plate 203a near the free disk 202a, which can cooperate with the ball end of the lever 202c. That is, when the ball end of the lever 202c rotates into the adjustment slot 203b, the free disk 202a and the first lever plate... 203a is in a locked state, and the two can rotate synchronously. A locking seat 203c is also embedded on the other end face of the first lever 203a. The locking seat 203c can move relative to the first lever 203a, and the locking seat 203c is square to avoid relative rotation between the locking seat 203c and the first lever 203a. At the same time, a limiting ring 203d is integrally connected to the outer side of the locking seat 203c. A helical toothed ring 203e is coaxially fixed on the inner surface of the limiting ring 203d. A sliding sleeve 203f is also provided on the inner side of the first lever 203a. A telescopic spring 203g is provided inside the sliding sleeve 203f. One end of the telescopic spring 203g is connected to an extension post 203h.
[0045] Furthermore, both the forward helical ring 203e and the reverse helical ring 205 are arranged in a circular array with multiple helical teeth, and the two can be fully meshed. Thus, with the translatable arrangement of the limiting ring 203d and the locking seat 203c, the forward helical ring 203e can rotate along the inclined edge of the helical teeth of the reverse helical ring 205, thereby allowing the first lever plate 203a to rotate counterclockwise. This process is accompanied by the intermittent undulating translation of the limiting ring 203d and the locking seat 203c, and under the elastic force of the clamping spring 206, the forward helical ring 203e and the reverse helical ring 205 are always meshed in the static state. Under the combined action of the vertical edge of the reverse helical ring 205 and the vertical edge of the forward helical ring 203e, the clockwise rotation of the forward helical ring 203e is restricted, thereby ensuring that the operating angle of the probe 104 is always maintained.
[0046] The sliding sleeve 203f and the adjusting groove 207 are in sliding fit. The adjusting groove 207 includes a sliding groove 207a formed on the surface of the bracket 201. When the sliding sleeve 203f is inside the sliding groove 207a, it can ensure the stable rotation of the first lever 203a on the bracket 201 and prevent the first lever 203a from lateral displacement. One end of the sliding groove 207a is connected to the switching groove 207b, and the other end of the switching groove 207b is connected to the reset groove 207c. The switching groove 207b is inclined, and the bottom surfaces of both the switching groove 207b and the reset groove 207c are lower than the sliding groove 207a. Therefore, when the sliding sleeve 203f moves into the switching groove 207b, its bottom extension post 203h extends under the action of the telescopic spring 203g, which can restrict the sliding sleeve 203f from moving back into the sliding groove 207a. As the first lever 203a continues to rotate, the sliding sleeve... When 203f moves into the reset groove 207c, the first lever 203a is displaced under the drive of the sliding sleeve 203f, so as to disengage the engagement between the helical gear ring 203e and the reverse helical gear ring 205. At the same time, the first lever 203a can be quickly rotated and reset under the transmission of the pulling rope 204 and the elastic force of the torsion spring 102c. The sliding sleeve 203f moves synchronously to the end of the reset groove 207c. Since the reset groove 207c is set in a zigzag shape and the bottom of the end connected to the sliding groove 207a is inclined, the first lever 203a can be translated and reset in the direction of the free disk 202a under the compression of the clamping spring 206. At the same time, the extension column 203h is retracted under the action of the inclined surface, and the sliding sleeve 203f returns to the sliding groove 207a again, so as to facilitate the subsequent adjustment of the angle of the probe 104 by the angle adjustment component 203.
[0047] Example 3
[0048] Reference Figure 1-7 This is the second embodiment of the present invention, which is based on the previous embodiment and differs from the previous embodiment in that:
[0049] On the other side of the control component 202, a cleaning drive component 208 is also provided. A tension rope 209 is connected to the outer side of the cleaning drive component 208. The other end of the tension rope 209 is connected to a cleaning component 210. A compensation component 211 is provided on the lower outer wall of the cleaning component 210. An elastic component 212 is also installed on the outside of the cleaning component 210. A positioning component 213 for temporarily fixing itself is also installed on the inner side of the elastic component 212.
[0050] Furthermore, the cleaning drive component 208 includes a second lever 208a movably disposed outside the bracket 201. The second lever 208a is disposed on the opposite side of the first lever 203a relative to the free disk 202a. The second lever 208a is also composed of a disc and a rod-shaped plate, and one end of the tension rope 209 is fixed to the outer end of the rod-shaped plate of the second lever 208a. At the same time, a cleaning slot 208b is provided on the end face of the second lever 208a near the free disk 202a, which can cooperate with the ball end of the lever 202c. By moving the lever 202c, its ball end can move into the cleaning slot 208b so that the free disk 202a and the second lever 208a can rotate synchronously.
[0051] The cleaning component 210 includes a rotating ring 210a rotatably mounted on the inner wall of the cover 103. Multiple positioning posts 210b are arranged in a ring array on the surface of the rotating ring 210a. Each positioning post 210b is rotatably connected to a scraper 210c, and the bottom surface of the scraper 210c is flush with the surface of the probe 104. This allows the scraper 210c to swing and scrape the surface of the probe 104. A positioning head 210d is integrally mounted inside the opening at the front end of the scraper 210c. A limiting groove 210e is provided around the outer periphery of the positioning post 210b to cooperate with the positioning head 210d. Through the cooperation between the limiting groove 210e and the positioning head 210d, the angle of rotation of the scraper 210c around the positioning post 210b is limited to prevent excessive rotation of the scraper 210c, which would affect the normal cleaning of the probe 104. A slope plate 210f is also fixedly mounted on the lower side wall of the rotating ring 210a.
[0052] The compensation component 211 includes a push plate 211a disposed on the lower outer wall of the rotating ring 210a. A buffer spring 211b is connected to the outer side of the push plate 211a. A stop plate 211c is connected to the other end of the buffer spring 211b. The stop plate 211c is fixed on the elastic component 212. The elastic component 212 is initially in a state restricted by the positioning component 213. Thus, the rotating ring 210a can rotate relative to the elastic component 212 and squeeze the buffer spring 211b under the pull of the tension rope 209. At the same time, when the cleaning component 210 is reset, the cleaning component 210 can be reset to the initial state by the elastic force of the buffer spring 211b itself.
[0053] The elastic element 212 includes a rotating seat 212a disposed outside the rotating ring 210a. The rotating seat 212a is rotatably mounted on the surface of the base plate 105. A side ring 212b is provided on the inner side of the rotating seat 212a. The side ring 212b has an extension opening 212c that cooperates with the scraper 210c. The scraper 210c extends out of the extension opening 212c. Thus, when the rotating ring 210a rotates relative to the rotating seat 212a, the front end of the scraper 210c can rotate to the surface of the probe 104 under the restriction of the extension opening 212c, so that the rotation path of the scraper 210c completely covers the probe. The purpose of the 104 surface is to ensure the cleaning effect of the scraper 210c on the surface of the probe 104. At the same time, the outer wall of the rotating seat 212a is fixed with a coil spring 212d. The other end of the coil spring 212d is fixed with the inner wall of the cover 103. The rotation of the rotating seat 212a causes the coil spring 212d to contract. Then, the elastic force of the coil spring 212d to restore its deformation drives the rotating seat 212a to reverse and reset. Thus, the reciprocating rotation of the rotating seat 212a enables the scraper 210c to continuously clean the surface of the probe 104, so as to ensure clear imaging of the probe 104.
[0054] The positioning component 213 includes a support plate 213a fixed to the outer wall of the side ring 212b. A rod 213b is inserted through the support plate 213a, and the end of the rod 213b continues to penetrate the rotating seat 212a to the interior of the base plate 105. The rotation of the rotating seat 212a is restricted by the insertion and engagement between the rod 213b and the base plate 105. At the same time, a top spring 213c is installed between the support plate 213a and the rod 213b. The top spring 213c provides elastic support for the rod 213b through its own elasticity, ensuring a stable engagement between the rod 213b and the base plate 105. An extension plate 213d is also integrally provided on the top outer wall of the rod 213b.
[0055] Preferably, the top of the slope plate 210f is inclined, and the extension plate 213d is on the rotation path of the slope plate 210f. Thus, as the rotating ring 210a rotates, when the slope plate 210f moves to the extension plate 213d, it can lift the insertion rod 213b through its own inclined surface via the extension plate 213d, thereby releasing the rotation restriction of the rotating seat 212a. This allows the rotating ring 210a and the rotating seat 212a to rotate synchronously.
[0056] In specific operation, when it is necessary to clean the probe 104, rotate the lever 202c to the same position as the cleaning slot 208b, and then move the lever 202c to the right, so that its ball end moves into the cleaning slot 208b. At this time, the free disc 202a and the second lever 208a can rotate synchronously. Then push the lever 202c upward, so that the other end of the second lever 208a drives the tension rope 209 to move downward, thereby causing the rotating ring 210a to squeeze the buffer spring 211b to rotate. The scraper 210c gradually extends, and as the rotating ring 210a rotates, the slope plate 210f on its outer wall lifts the insertion rod 213b. The rotation restriction on the elastic element 212 is released. At this time, the rotating ring 210a and the rotating seat 212a rotate synchronously, and the scraper 210c remains in an unobstructed position to clean the probe 104. Finally, the lever 202c is released, and the rotating seat 212a, under the elastic force of the coil spring 212d, synchronously drives the rotating ring 210a to reset and rotate. This allows the scraper 210c to clean the probe 104 again during the reset process. After the rotating seat 212a resets and is restricted again by the insertion rod 213b, the buffer spring 211b continues to push the rotating ring 210a to rotate, so as to achieve the overall retraction of the scraper 210c without affecting the normal use of the probe 104. When the angle of the probe 104 needs to be adjusted, push the lever 202c up and down until it is at the same height as the adjustment slot 203b on the first lever plate 203a, then move the lever 202c to the left to engage with the adjustment slot 203b. This allows the first lever 202c to rotate synchronously with the free disc 202a. To adjust the angle of the probe 104, lift the lever 202c upwards. The relative rotation of the other end of the first lever plate 203a causes the pull rope 204 to pull the connector 102b downwards. Simultaneously with the rotation of the first lever 202c, the forward helical toothed ring 203e moves along the helical teeth of the reverse helical toothed ring 205. The tilting edge rotates, and when the first lever 203a is stationary, the meshing of the two achieves the positioning of the first lever 202c, thereby ensuring that the operating angle of the probe 104 is always maintained. When it is necessary to reset the angle of the probe 104 to the initial state, the sliding sleeve 203f on the inner side of the first lever 203a can be transferred along the sliding groove 207a through the switching groove 207b to the reset groove 207c. At this time, the forward helical gear ring 203e and the reverse helical gear ring 205 separate synchronously, so that the first lever 203a can be reset under the transmission of the pull rope 204 and the elastic force of the torsion spring 102c, so as to realize the re-adjustment of the probe 104.By extending the probe 104 into the furnace, its imaging function allows for observation of the ignition status of the ignition gun from outside the furnace without the need for personnel to enter or remove the ignition gun, ensuring normal use of the ignition gun and reducing operational risks. Furthermore, with the control unit 202 working in conjunction with the angle adjustment unit 203 and the cleaning drive unit 208, the angle of the probe 104 and the use of the cleaning unit 210 can be controlled separately. This allows users to freely adjust the angle of the probe 104 located inside the furnace, ensuring accurate observation of the ignition status of the ignition chamber under different conditions. During use, the cleaning unit 210 can be used to clean the surface of the probe 104 in real time, preventing the front of the probe 104 from being affected by ash and slag in the furnace, thus avoiding blurred imaging.
[0057] It is important to note that the constructions and arrangements of this application shown in several different exemplary embodiments are merely illustrative. Although only a few embodiments are described in detail in this disclosure, those who consult this disclosure will readily understand that many modifications are possible (e.g., changes in the size, dimensions, structure, shape, and proportions of various elements, as well as parameter values (e.g., temperature, pressure, etc.), mounting arrangements, use of materials, color, orientation, etc.) without substantially departing from the novel teachings and advantages of the subject matter described in this application). For example, an element shown as integrally formed may be composed of multiple parts or elements, the position of elements may be inverted or otherwise altered, and the nature or number or position of discrete elements may be changed or altered. Therefore, all such modifications are intended to be included within the scope of the invention. The order or sequence of any process or method steps may be changed or rearranged according to alternative embodiments. In the claims, any "device plus function" clause is intended to cover the structure described herein that performs the function, and not only structurally equivalent but also equivalent in structure. Other substitutions, modifications, alterations, and omissions may be made in the design, operation, and arrangement of the exemplary embodiments without departing from the scope of the invention. Therefore, the present invention is not limited to the specific embodiments, but extends to various modifications that still fall within the scope of the appended claims.
[0058] Furthermore, in order to provide a concise description of exemplary embodiments, not all features of actual embodiments (i.e., those features that are not relevant to the currently considered best mode for carrying out the invention, or those features that are not relevant to implementing the invention) may be omitted.
[0059] It should be understood that numerous specific implementation decisions can be made during the development of any practical implementation, such as in any engineering or design project. Such development efforts may be complex and time-consuming, but for those skilled in the art who benefit from this disclosure, the development effort will be a routine work of design, manufacturing, and production without requiring much experimentation.
[0060] It should be noted that the above embodiments are only used to illustrate the technical solutions of the present invention and are not intended to limit it. Although the present invention has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, and all such modifications or substitutions should be covered within the scope of the claims of the present invention.
Claims
1. A device for detecting electrode ignition in an ignition gun, characterized in that: include, The testing mechanism includes a handle (101), a connector (102) located at the top of the handle (101), a cover (103) located outside the connector (102), a probe (104) located inside the cover (103), and a base plate (105) located on the inner wall of the cover (103); and, The adjustment mechanism (200) includes a bracket (201) located inside the grip (101). A control element (202) is provided on the outside of the bracket (201). An angle adjustment element (203) is provided on one side of the control element (202). A pull rope (204) is connected to the outer end of the angle adjustment element (203). A reverse helical toothed ring (205) is also provided on the outside of the bracket (201). A retaining spring (206) is provided on the outer end face of the angle adjustment element (203). The surface of the control component (202) is provided with an adjustment groove (207). A cleaning drive component (208) is provided on the other side of the control component (202). A tension rope (209) is provided on the outer side of the cleaning drive component (208). The other end of the tension rope (209) is connected to the cleaning component (210). A compensation component (211) is provided on the lower outer wall of the cleaning component (210). An elastic component (212) is provided on the outside of the cleaning component (210). A positioning component (213) is also provided on the inner side of the elastic component (212). The control component (202) includes a free disk (202a) movably disposed in the middle section of the bracket (201). The free disk (202a) has an internal movable cavity (202b). A lever (202c) is disposed inside the movable cavity (202b). The lever (202c) extends to the outside of the free disk (202a). A correction spring (202d) is sleeved on the exposed end of the lever (202c). The correction spring (202d) is fixed to the free disk (202a). A pin (202e) is vertically inserted through the inside of the lever (202c). Both ends of the pin (202e) are connected to pin seats (202f). Both pin seats (202f) are fixed to the surface of the free disk (202a).
2. The ignition gun electrode ignition detection device according to claim 1, characterized in that: The connector (102) includes a connector (102a) fixed to the top of the grip (101), a connector (102b) is movably connected to the inner side of the connector (102a), and a torsion spring (102c) is installed between the connector (102a) and the connector (102b).
3. The ignition gun electrode ignition detection device according to claim 2, characterized in that: The angle adjustment component (203) includes a first lever (203a) disposed on the outside of the free disk (202a). The first lever (203a) has an adjustment slot (203b) on one end face near the free disk (202a). A locking seat (203c) is embedded on the other end face of the free disk (202a). A limiting ring (203d) is connected to the outside of the locking seat (203c). A helical toothed ring (203e) is fixed on the inner surface of the limiting ring (203d). A sliding sleeve (203f) is also disposed on the inner side of the first lever (203a). A telescopic spring (203g) is disposed inside the sliding sleeve (203f). One end of the telescopic spring (203g) is connected to an extension post (203h). The oblique toothed ring (203e) and the reverse oblique toothed ring (205) are meshed; The sliding sleeve (203f) and the adjusting groove (207) are in a sliding fit.
4. The ignition gun electrode ignition detection device according to claim 3, characterized in that: The adjustment groove (207) includes a sliding groove (207a) formed on the surface of the bracket (201), one end of the sliding groove (207a) is connected to a switching groove (207b), and the other end of the switching groove (207b) is connected to a reset groove (207c).
5. The ignition gun electrode ignition detection device according to claim 4, characterized in that: The switching slot (207b) is inclined, and the reset slot (207c) is arranged in a zigzag shape; The bottom surfaces of the switching groove (207b) and the reset groove (207c) are both lower than the sliding groove (207a), and the bottom of the end of the reset groove (207c) that connects to the sliding groove (207a) is inclined.
6. The ignition gun electrode ignition detection device according to claim 5, characterized in that: The cleaning drive (208) includes a second dial plate (208a) movably disposed outside the bracket (201), and a cleaning slot (208b) is provided on the end face of the second dial plate (208a) near the free disk (202a).
7. The ignition gun electrode ignition detection device according to claim 6, characterized in that: The cleaning component (210) includes a rotating ring (210a) located inside the cover (103). The surface of the rotating ring (210a) is provided with a plurality of positioning posts (210b) arranged in a ring array. The external surfaces of the plurality of positioning posts (210b) are rotatably connected to scrapers (210c). A positioning head (210d) is provided inside the opening at the front end of the scraper (210c). A limiting groove (210e) that cooperates with the positioning head (210d) is left on the outer periphery of the surface of the positioning post (210b). A slope plate (210f) is also provided on the side wall of the rotating ring (210a). The compensation component (211) includes a push plate (211a) disposed on the lower outer wall of the rotating ring (210a), a buffer spring (211b) is connected to the outer side of the push plate (211a), and a stop plate (211c) is connected to the other end of the buffer spring (211b), and the stop plate (211c) is fixed on the elastic component (212).
8. The ignition gun electrode ignition detection device according to claim 7, characterized in that: The elastic element (212) includes a rotating seat (212a) disposed outside the rotating ring (210a). A side ring (212b) is provided on the inner side of the rotating seat (212a). An extension (212c) is provided on the side ring (212b) to cooperate with the scraper (210c). A coil spring (212d) is fixed on the outer wall of the rotating seat (212a). The other end of the coil spring (212d) is fixed to the inner wall of the cover (103).
9. The ignition gun electrode ignition detection device according to claim 8, characterized in that: The positioning component (213) includes a support plate (213a) fixed to the outer wall of the side ring (212b), a rod (213b) passing through the inside of the support plate (213a), a top spring (213c) installed between the support plate (213a) and the rod (213b), and an extension plate (213d) provided on the top outer wall of the rod (213b).