RU2349839C2 - Connector for thermocouple to be coupled with gas flow control valve magnet assembly to control gas flow in burner and method of thermocouple terminals connection to magnet assembly contacts of gas flow control valve - Google Patents

Abstract

FIELD: power production; heating.

SUBSTANCE: connector for thermocouple to be coupled with magnet assembly of gas control valve to control gas flow in burner contains magnet assembly with the first pin contact connected with the magnet assembly conductor and inserted into the second tubular cylindrical contact. The connector is comprised of an insulating enclosure with central cylindrical element having been shaped as the inner cavity of the second tubular cylindrical contact of the magnet assembly. The central cylindrical element is provided with an opening coinciding with the first pin contact of the magnet assembly and contains the first tubular element in the above opening. The said contact is implemented so that it can be connected with the first pin contact of magnet assembly, while the central cylindrical element fits the second tubular cylindrical contact of magnet assembly. The connector is provided with the second socket contact being inside the insulating enclosure and having opening shaped as the external surface of the second tubular contact of magnet assembly. This contact of connector is coupled with the above-mentioned second tubular cylindrical contact of magnet assembly if the first pin contact of magnet assembly is connected to the first tubular contact of connector. The first tubular contact of connector is coupled with the conductor connected to the hot junction of thermocouple, while the second socket contact of connector is coupled with the conductor connected to the cold junction of thermocouple. The second socket contact shape is similar to the open cylindrical bushing. The insulating enclosure of the connector is provided with the side opening for radial installation of the second socket contact on the second tubular cylindrical contact of magnet assembly. The said opening is on the same level as the above-mentioned second tubular cylindrical contact of magnet assembly when the first tubular contact of the insulating enclosure is connected with the contacts of magnet assembly.

EFFECT: safe connection between thermocouple and magnet assembly, improved visual inspection of contact connection adequacy.

22 cl, 6 dwg

Description

A connector for connecting a thermocouple to the magnetic assembly of the gas valve for regulating the gas flow in the burner, in which the magnetic assembly includes a first pin contact connected to the conductor of the magnetic assembly and placed inside a second tubular cylindrical contact connected to the ground contact of the magnetic assembly, and the connector includes an insulating body having an insulating pin contact, the shape of which corresponds to the inner cavity of the second tubular cylindrical contact, and the insulating pin contact has a hole that coincides with the first pin contact of the magnetic unit, and contains in the aforementioned hole a first female tubular contact that is designed to connect to the first pin contact of the magnetic unit, while this insulating contact enters the second tubular contact of the magnetic unit, the connector having a second the socket contact, which is located in the insulating casing and the hole of which corresponds to the shape of the outer surface of the second tubular contact of the magnetic node, and this second socket the first contact of the connector is connected to said second tubular grounding contact of the magnetic assembly when the first pin contact of this magnetic assembly is connected to the first tubular contact of the connector, the first tubular contact of the connector being connected to a conductor connected to the hot junction of the thermocouple, and the second female contact of the connector being connected to the conductor associated with cold junction thermocouples.

Several types of connectors are known for connecting thermocouples to magnetic assemblies of safety valves for regulating gas flow. This thermocouple has the function of detecting flame and ensuring safe operation of the burner. Therefore, there has always been a need for a connector or other means for reliable electrical connection to a thermocouple. When there is no such connection between the thermocouple and the safety magnet assembly, the gas flow to the burner stops and the flame goes out or the burner can no longer remain on and its operation stops.

In this case, it is very important, especially for gas domestic appliances, such as stoves, heating boilers, water heaters or the like, to have a means for a safe connection between the thermocouple and the magnetic assembly that controls the gas flow control valve.

A number of different solutions have been proposed, but they all have certain disadvantages. Recently, a connector similar to that described above has been proposed in EP 619460, in which both the first tubular contact connected to the thermocouple junction and the second tubular contact connected to the thermocouple junction are stably fixed in the insulating casing in the respective relative positions complementary to the relative the positions of the respective contacts of the magnetic assembly, and are integrated in the insulating casing to form a bipolar connector with substantially coaxial connecting contacts. This design has a clear advantage of providing a one-step connection between two contacts of the magnetic assembly and two conductors of the thermocouple.

However, the coaxial connection of the contacts needs tolerances, especially for the tubular grounding contact, for installation and connection with the highest accuracy, otherwise this connector is difficult to fit, if at all, onto the contacts of the magnetic assembly. Therefore, the mutual clamping force between the contacts must not exceed a predetermined limit. It is likely that due to insufficiently accurate tolerances - since such products are not products of a high degree of accuracy - or because of the frequently repeated disconnection and connection of the contacts, the connection is weakened to such an extent that it becomes possible to accidentally disconnect the contacts, which leads to a loss of operability of the thermocouple and the resulting security concerns. Also, since the contacts in the connected state must be advanced deep to prevent any accidental disconnection, the contacts of this connector may be deformed or displaced, as a result of which the contact or connection with the corresponding contact of the magnetic assembly will be partial, weakened or unsatisfactory.

In addition, the disadvantage is that if the contacts of the magnetic node and the contacts of the connector have inconsistent sizes, the said contacts will not be able to connect in pairs. In the event of dimensional changes, in particular of valves and / or their magnetic assemblies, one type of connector may not be sufficient, therefore, other types of connectors having different sizes corresponding to different sizes and / or position of contacts of the magnetic assembly should be provided.

Therefore, the aim of the invention is to create a bipolar connector described above, in which, by means of simple and inexpensive design solutions, the disadvantages of the known connectors are eliminated while providing essentially the same functional suitability, as well as improved visual control of the correct connection of the contacts.

The above objectives of the invention are achieved by creating a connector for connecting a thermocouple to the magnetic assembly of the gas valve for regulating the gas flow in the burner, in which the magnetic assembly contains a first pin contact connected to the conductor of the magnetic assembly and placed inside a second tubular cylindrical contact connected to the magnetic ground terminal node, and the connector contains an insulating housing having an insulating pin contact, the shape of which corresponds to the inner cavity of the second tubular about a cylindrical contact of the magnetic assembly, wherein the insulating pin contact has an opening that corresponds to the first pin contact of the magnetic assembly, and contains in said hole a first female tubular contact that is designed to fit onto the first pin contact of the magnetic assembly, while this insulating contact enters the second a tubular contact of the magnetic assembly, the connector having a second female contact, which is placed in an insulating casing and the opening of which corresponds to the external shape of the a contact of the magnetic node, and this second female contact of the connector is inserted into said second pipe ground contact of the magnetic node when the first pin contact of this magnetic node enters the first pipe contact of the connector, the first pipe contact of the connector being connected to the conductor that is connected to the hot junction thermocouples, and the second socket contact of the connector is connected to a conductor that is connected to the cold electrode of the thermocouple.

The difference is that

the second female socket contact of the connector has a shape similar to an open cylindrical sleeve, and the insulating body of the connector has a lateral hole for radially mounting the second female contact of the connector on the second tubular ground terminal of the magnetic node, the hole being flush with said second tubular contact of the magnetic node when the first socket contact of the insulating body is connected to the contacts of the magnetic node.

The second socket contact of the connector is an open annular element covering on both sides, which is brought into contact by radial movement to the second tubular contact of the magnetic assembly, and the partially open cylindrical surface of the second socket contact (203) of the connector has an angular extension of more than 180 °.

This open annular element is formed by two opposed to each other legs having the shape of a cylinder sector, each of which has an angular length of more than 90 °

The second socket contact of the connector has an open annular element on a part of its length, the angular extent of which is more than 180 °, and a pair of opposite legs on the rest of the legs, which are oriented in the direction of connection of the second socket contact of the connector with the second socket contact of the magnetic node and act as guide means interacting with respective guide cutouts made in the connector housing between the respective side walls of the connector housing and the cent ral cylindrical element.

These guide tabs can be of a fixed size, or have thicker rib-like parts, or not flat in such a way that the tabs due to their elasticity enter with effort into the connecting cutouts of the insulating body.

Advantageously, the second socket contact of the connector and the insulating casing have interacting means for preventing disconnection, which come into effect when the second socket contact is connected in an intermediate position in the cutouts of the insulating casing.

Alternatively, or in combination with this, the second female contact of the connector and the insulating body have interacting stops to prevent the second female contact from being inserted into the cutouts of the insulating body, which come into operation at a predetermined intermediate inserted position of the second female contact in the insulating body, the resistance of these means preventing entry, can be overcome by exceeding a predetermined force in the direction of entry.

In accordance with another distinguishing feature of the present invention, this predetermined intermediate inserted position of the second female contact in the insulating housing corresponds to the position in which this second female contact is ready to be connected to the second cylindrical ground contact of the magnetic assembly, and in this ready position the open ring part of the second female contact adjacent to the second cylindrical contact of the magnetic node and is insulated on the Central cylindrical element go corps. In this position, the open annular part of the second socket contact has a small gap relative to the outer surface of the second cylindrical contact of the magnetic assembly.

Therefore, as far as construction is concerned, the connector of the present invention may include a second female contact having two pairs of opposed side legs, i.e. two legs on each side, and these pairs of legs located at some distance from each other and enter the corresponding cutout of the insulating casing, i.e. between the side walls of the hole for introducing this contact into the insulating casing and the central cylindrical element of the insulating casing, while the second pair on at the free ends, it has retaining means for preventing separation, interacting with retaining stops provided on each of the two side cut-outs of the insertion, as well as stops preventing entry, interacting with transverse protrusions-stops on the central cylindrical element, while preventing stops the separation on these legs are teeth that are made with the possibility of due to its elasticity to recess from the position in which they rest these are the stops in a position where they do not interfere with the abutment. This retractable tooth is moved to a position in which it is not an obstacle by means of a pressure that exceeds a predetermined threshold value.

The predominantly open ring contact and / or the first female contact of the connector are made of tinned phosphor bronze. This material has more stable elastic properties, taking into account the effect of constant heating and cooling on the contact in comparison with, for example, tinned or not tinned copper contact. This allows you to maintain the characteristics of the electrical contact in this connection is essentially unchanged over time.

The above-described construction of the connector in accordance with this invention demonstrates that, compared with the known coaxial connector, when the connector is mounted on the contact of the magnetic assembly, the insertion force will be lower, while an excellent electrical and mechanical connection is maintained, which is constant over time and stable to random loads.

In one embodiment, the guiding and holding tabs have stoppers that are recessed due to their elasticity to prevent entry, which interact with the restriction surfaces of the stops to prevent entry on the respective guide cutouts and restrict the movement of the second socket contact when it is inserted into the insulating body of the connector, and restricting entry the surface of the stops and stops preventing separation, as well as lining due to its elasticity stops to prevent Expectations and means of preventing separation on the guides and holding tabs are located at such a distance from each other that the second socket contact is blocked both from the disconnection and from the insertion, while the limiting entry surfaces of the stops form lateral input guide surfaces of the transverse protrusions-stops for the guides and holding legs, which can be overcome by applying to the second socket contact in the radial direction of the specified force, sufficient to translate Xia due to its elastic abutments to prevent occurrence of a situation in which the corresponding transverse projection overcome-emphasis.

In one embodiment, each guide and holding foot has a tooth at the end to prevent separation, the abutment surface of which is oriented in the direction of contact extraction from the insulating body and which interacts with an intermediate inner step facing the bottom of the corresponding guide cutout for insertion into the insulating body, and at a certain distance from the opposite end, and each guide and holding foot has a tooth recessed due to its elasticity c interacting with the inclined surface of the stop, which is the lateral surface of the transverse protrusion-stop, and the distance from the step to prevent separation to the inclined guide input surface corresponds to the distance from the surface of the retaining and preventing separation of the tooth to the tooth which is recessed due to its elasticity, and said teeth are located on the guides and holding tabs in such a position that the second socket contact is temporarily blocked in the position in which it to join on the corresponding second tubular cylindrical contact of the magnetic unit, in the radial direction, adjacent to it, and can be inserted inside the insulating housing to the position in which it is attached to the contact of the magnetic unit by applying a force sufficient to overcome the specified elastic deformation force in order to lead to a position in which it does not rest against the protrusions of the teeth that are restrained by the entry due to their elasticity, limiting the entry.

A variant is also possible in which the means of preventing separation that interact with the tooth that does not separate on the guide and the holding foot are a step made on the inner surface of the side wall, while an inclined limiting entry surface of the stop with a corresponding protrusion-stop is provided on the central cylindrical element along its part, which has a corresponding shape, which coincides with the driving with a tooth-stop of the guide and the holding foot, the tooth preventing the separation from being separated and the stop-tooth being sunk due to its elasticity protrude outward from the opposing surfaces of the guide and holding feet.

In an alternative embodiment, the step for preventing separation, made on the side wall bounding the guide cuts, has a sawtooth shape with an inclined guide lead-in surface facing the hole of the guide cutout, which is adjacent to the remaining surface of the wall by means of an expanding step, and the tooth that interacts with it and prevents separation on the guide and holding foot also has a sawtooth profile, but with the opposite orientation of the input guide and holding surfaces of an emphasis.

According to yet another alternative, the tooth-stop which is recessed due to its elasticity is formed by an elastic tongue that protrudes to the inside of the guide cutouts for introducing the guide and holding tabs, this tab being cut and folded at the corresponding angle of the wall of the guide and holding tabs, whereas the protrusion-stop is a transverse protrusion of a trapezoidal cross section.

In one embodiment, this trapezoidal protrusion has an unequal shape with a steeper side facing towards the open side of the guide cutouts for access and a less steep side facing the bottom of the guide cutouts.

In one embodiment, the force necessary to overcome the resistance of the stop tooth relative to the protrusion protruding due to its elasticity is selected so that it is the same order of magnitude as the force of the open ring part of the second socket contact to the second tubular cylindrical contact of the magnetic assembly.

A variant is also provided in which the open annular element of the second socket contact of the connector has expansion means interacting with the cylindrical surface of the second tubular cylindrical contact of the magnetic assembly during radial attachment.

Each of the two parts of the open annular element, having the shape of a sector of the cylinder, can have an end tab that is inclined outward in the radial direction so that the tabs of these two parts form opposite surfaces, expanding towards the free ends.

The invention also relates to a method for connecting the contacts of a thermocouple to the contacts of the magnetic assembly of a gas flow control valve, in which the thermocouple comprises two contacts connected to two corresponding contacts of the magnetic assembly; The method is characterized by the following operations:

joining by axial mounting of the insulating body together with the first tubular contact on the corresponding pin-like contact of the magnetic assembly,

attaching a second female contact to the cylindrical contact of the magnetic assembly by laterally and / or radially moving it to said contact of the magnetic assembly.

In this case, disconnection is achieved by disconnecting the connector from the contacts of the magnetic unit in the axial direction, while reconnecting requires the operation of returning by pulling the second female contact outward in the radial direction to the ready position.

For the above reasons, due to the cylindrical shape of the tubular cylindrical contact, said contact acts as an input surface for radially expanding the second ground contact of this connector.

Also, the cylindrical surface of the second socket contact of the connector, having an angular extent of more than 180 °, open along the axis, has significant elastic deformability, due to which, in the range of clearly defined size tolerances, the socket contact of the connector has high adaptability to various sizes of the second contact of the magnetic assembly.

In addition, this second contact of the connector must be pressed manually during radial movement on the second contact of the magnetic assembly, which allows the touch and to some extent visually control the correct connection between these two second contacts.

In particular, said disengagement preventing means operate in an intermediate inserted position of the contact in the insulating body of the connector. This position corresponds to a position in which the open annular part of the contact is ready for attachment and in which the said open annular part is directly in radius adjacent to the cylindrical contact of the magnetic assembly and mounted axially on the insulating body of the connector.

The presence of two pairs of guide tabs on each side of the female contact allows you to accurately direct this second female contact of the connector during its attachment, while protecting the ring element when it is attached to the cylindrical contact of the magnetic assembly from distortion of the second female contact of the connector, which may occur due to Resistance forces of elastic expansion deformation in the presence of only one pair of guide legs.

In addition, the second pair of tabs, which is designed to be fixed with their teeth in the guides of the insulating casing, holds the second socket contact on the insulating casing of the connector before attaching it to the corresponding second contact of the magnetic assembly, thereby simplifying the connection of the connector, since otherwise this second contact was would be free, and after fitting the connector with its first contact on the contacts of the magnetic unit, the second socket contact of this connector would first have to be placed in the stii insulating body, and then radially compressed for insertion. With this design, the second socket contact is already in the proper position, ready for connection, and after fitting the connector onto the contacts of the magnetic assembly, it is only necessary to push it radially inward to connect to the second cylindrical contact of the magnetic assembly.

The advantages of the present invention are obvious from the above description and consist in simplifying the electrical connection of the thermocouple to the magnetic assembly of the gas flow control valve while ensuring an optimal electrical connection even with a significant difference in size between the contacts of the connected connector, while maintaining the ease of installation of the connector on the contacts of the magnetic assembly.

The foregoing clearly shows that such a connector can be connected to the magnetic assembly using only a small additional operation compared to the connection operation required for coaxial connectors. Such an additional operation is very simple and fast, and also allows you to touch and visually verify the correctness of the already completed connection, at least the ground contact.

The invention relates to further improvements that are the subject of the dependent claims.

The distinguishing features of the present invention and the advantages arising from them, become more clear from the following description of the embodiment depicted in the accompanying drawings, in which

Figure 1 is an exploded perspective view of a connector of the present invention together with a contact tip of a magnetic assembly of a gas flow control valve.

Figure 2 is a perspective view of this connector mounted on the tip of the magnetic assembly of the gas flow control valve equipped with contacts.

Figure 3 is a perspective view of an assembled connector with a female contact intended to be connected to the second cylindrical ground contact of the magnetic assembly of this valve, ready for radial connection to said contact of this magnetic assembly.

FIG. 4 is a perspective view of the connector shown in FIG. 3 with a socket contact pushed into the insulator housing of the connector in a position that corresponds to a position in which it is connected to the ground terminal of the magnetic assembly.

5 and 6 are cross-sectional views of a connector with a female contact for attaching to a second cylindrical ground terminal of a magnetic assembly of a gas flow control valve, in positions respectively ready to move to a position in which it will be attached to said cylindrical ground terminal magnetic node, and in the position in which it is attached to it.

1, the latter is shown in the part in which the contacts are located for connection to the magnetic assembly of the gas flow control valve, for example, in inexpensive stoves or similar devices.

These contacts typically include a first contact (not shown) that is connected to the phase contact of the magnetic assembly and is a pin-like element. Coaxially referred to the first pin-like contact, a second cylindrical contact 2 is provided, which is, for example, a sleeve. A detailed description of the design of the magnetic unit is given, for example, in the aforementioned document EP 619460, the link to which is intended for additional information.

A flame stabilization thermocouple, which is also not shown, is usually connected to the valve magnetic assembly and usually consists of two electrodes, i.e. an internal pin-like electrode and an external cap electrode. These two electrodes are mechanically bonded together to form an electrical conduction zone at the end of this cap. A ground conductor connected to the outer cap and a signal conductor connected to the inner pin-like conductor are respectively derived from these two electrodes.

Then, the ends of the conductors for connecting these two electrodes are connected to the connector 3, which is designed to be connected to the valve magnetic assembly. This connector 3 contains two connecting contacts, i.e., a central contact 103, which connects to the inner pin-like electrode, while a conductor connected to the external thermocouple electrode connects to the second open ring female contact, which is generally indicated at 203.

The connector 3 has a housing made of an insulating material 303, which comprises a central cylindrical element made of an insulating material 403. The said central element 403 is cantilevered by the rear wall 503 of the connector housing, which comprises said rear wall, two side walls 603 and a front wall 703 having a central hole 803 from which the free end of the central cylindrical element 403 protrudes. This central cylindrical element 403 also has a central coax Flax hole 903 for connection to a first terminal 103 connected to the conductor shtyrepodobnomu thermocouple. Said contact has a tubular shape and is provided with at least one pair of radial legs or tabs 4, which radially diverge from the outer wall of the contact 103 in the direction of the rear end for connection to a conductor connected to a pin-like thermocouple electrode. An electrical connection with said conductor occurs by mechanically securing this conductor at an end 5 having a corresponding shape in a known manner. In particular, said end 5 of the tubular contact 103 has a wall whose angular extent is less than 360 °, in particular essentially 180 °, two pairs of diametrically opposite legs 6, 6 ', protruding from its two opposite sides, for fixing the conductor. In particular, the end tabs 6 'fix the insulated end portion of this conductor, while the next tabs 6 fix the uninsulated end of this conductor.

Radially diverging tabs 4 are designed to interact with radial steps-stops, or shoulders made in the Central hole 903. Behind these steps, or shoulders, the legs automatically snap as soon as the tubular contact 103 enters the hole 903 and reaches the proper axial position relative to the hole . In this position, the front end of the first contact 103 is flush with the front end of the cylindrical insulating element 403, while the opposite end for attaching the conductor remains inside the hole 903, thus leaving only the insulated part of the conductor outside.

The cylindrical insulating element 403 for fixedly securing the first tubular contact 103 connected to the inner pin-like electrode or the phase electrode of the thermocouple has an outer diameter that substantially corresponds to the inner diameter of the cylindrical ground contact 2 of the magnetic node ground. In addition, this central cylindrical element 403 has a diametrically located slot, at least in its final part, allowing a certain reduction in diameter due to elastic deformation when the connector is pressed onto the contacts of the magnetic assembly with force.

One of the sides of the insulating housing 3 of the connector is open and the cylindrical element 403 is completely accessible from the outside. The diametrically opposite side walls 603 are located at a certain distance from the central cylindrical element and form two parallel and diametrically opposite openings or cuts between the two side walls 603 and the cylindrical element. These cutouts are designed to accommodate a second open annular or covering on both sides of the socket clamp for contact. This contact 203 at its end, which must be turned to the contacts of the magnetic assembly, has a pair of tabs 7 having the shape of a ring sector, which together form an open ring element. The tabs 7, having a shape similar to sectors of the ring, have an angular extent of more than 90 °, therefore this open annular element made in this way has an angular extent of more than 180 °. Behind said legs, contact 203 has a semi-cylindrical wall and two pairs of flat guide legs 8 and 9 protruding from its diametrically opposite sides. On the contact side opposite the open ring element, means 5 are provided for attaching the connection to a conductor connected to a cold or thermocouple ground electrode that are substantially identical or similar to those described for the first contact 103.

Two pairs of legs 8, 9 are located at some distance from each other in the axial direction of this contact. They are perpendicular to the median plane of the insulating body 3 and are intended to be inserted into the cut-outs 10 from two sides of the central cylindrical element 403, which extend along said cylindrical element 403.

In particular, the first pair of guide legs 8 has bulges 108 designed to allow the legs 8 to enter due to their elasticity into these side cutouts to form a strong and reliable connection, while allowing the legs 8 to fit snugly against these side cutouts under by the action of a given force, and the open ring contact 203 to be radially deformed from the inside to repeat the joining operation.

On the other hand, the second pair of legs 9 has elastic means for retaining the fixation of the open annular socket contact 203 in a position in which the latter is ready to be connected to the cylindrical contact 2 of the magnetic assembly when the insulating body 3 is mounted with its central cylindrical part 403 in the cylindrical contact 2 magnetic node, and the first contact 103 in the Central hole 903 of the aforementioned cylindrical element 403 is pressed with force on the first pin-like contact of the magnetic node located coaxially inside the cylindrical contact 2. This ready position is shown in FIG. 3 and FIG. 5.

The sections shown in FIGS. 5 and 6 are clearer illustrations of the construction of the second legs 9, as well as of the two positions, in one of which the open ring contact 203 is ready for connection, and in the other it is actually connected to the contact 2 of the magnetic assembly.

At the free ends, two opposite guide legs 9 of the second pair have external teeth 109, which have a sawtooth profile with a less steep front surface oriented in the direction of insertion into the cutouts 10.

On the inner side, which defines the boundaries of the cutouts 10, the two side walls 603 of the insulating body 3 have, starting from the edge, which first receives the guide and holding tabs 9, the first inclined input surfaces 110, which taper towards the central cylindrical body 403 and along which the ends of the two legs 9 are moved with a slight elastic clip to each other. At some intermediate location along the height of the cut-outs 10, such an inclined lead-in surface is mated to the remaining inner surface of the corresponding side wall 603 by means of a stepped extended part 210, behind which the tooth 109 is snapped onto the corresponding guide and holding tab 9. The positions of the teeth 109 and the stepped extended parts are thus defined that they engage with each other when the open annular end attached to the cylindrical contact 2 of the magnetic node is located on spaced from said cylindrical contacts 2 mounted on the end of the cylindrical insulating element 403 and more precisely - when two ends of the lugs 7 formed like ring sectors are at a small distance from said cylindrical pin 2 of the magnet assembly.

Such a combination of the tooth 109 of the guide and holding tabs 9 and the step 210 on the inner surface of the side wall 603 of the insulating body, which defines the boundaries of the cutouts 10 from the outside, is not sufficient to ensure stable fixation of their position, since it only performs the function of holding the tabs 9 from their exit from the cutouts 10 In fact, as, in particular, shown in FIGS. 5 and 6, at a predetermined distance from the tooth 109, the two guiding and holding tabs 9 have protrusions 209 on the surface opposite to the teeth 109, which the elasticities are recessed in the direction of the opposite front surface of the legs 9 or in the direction from the opposite foot 9, and these protrusions 209 have the shape of a triangular tooth turned to the central cylindrical element 403 of the insulating body 403 and come into contact with it when the teeth 109 engage on the steps 210.

In accordance with an additional useful feature, at the same level with the guides and holding tabs 9, the central cylindrical element 403 has an annular section coinciding with the protrusions 209 recessed due to their elasticity, the shape of which is made in such a way as to facilitate the insertion or movement of the protrusions 209, as well as create conditions for easily overcoming and restoring the stable holding of the contact in a position in which it is associated with the contact 2 of the magnetic node. For this, in the region in which the central cylindrical element 403 is in contact with the protrusions 209, said central cylindrical element 403 has a flat part 12, which is inclined to the ends of the legs 9 in the direction of the said legs 9. Each of these flat parts is directed towards the corresponding tab 9, thereby forming a protrusion 13 having a predetermined length in the fitting direction, which on the front surface opposite the inclined surface 12 forms an inclined engagement surface 14. This inclined engagement surface 14 slopes towards the center of the central element 403 and to the bottom of the corresponding cutout 10, whereby the protrusion 13 has a trapezoidal cross section, in particular, it has the shape of an unequal trapezoid with a steeper side facing the access opening of the cutouts 10, and the less steep side facing the bottom of the cutouts 10. The inclination of the surface 14 is less than the inclination of the opposite surface 12 and allows you to hold the tabs 9 in the position of connection of the contacts, as well as easy to move with a given radial by pulling the contact 203 back to the temporary fixation position, that is, to the standby position, by allowing the teeth 209 to pass beyond the protrusions 13 and be in contact with the inclined surfaces 12.

The remaining part, which coincides with the teeth 209 and is provided on the central cylindrical element 403, is a flat part 15, which is oriented parallel to the corresponding tab 9 or parallel to the direction of introduction of the tabs 9 into the cutouts 10, and this flat part 15 is recessed relative to the protrusion 13 so that the tooth 209 of the corresponding foot 9 is at a certain distance and does not intersect with said flat part 15.

The elastic tooth 209 of each foot 9 is preferably made in the form of a corresponding tongue of a triangular shape, which is a part of the foot 9, separated from it on three sides by cuts, while from the side opposite to the inserted edge of the foot, the tongue remains connected to the foot 9.

According to figure 3 and figure 5, as well as figure 2, figure 4 and figure 6, the operation of the connector of the present invention is as follows.

Before connecting to the contacts of the magnetic node of the gas flow control valve, as shown in FIG. 3 and FIG. 5, the second open annular female contact contact 203 of the connector is in a position in which it is ready for radial connection, that is, it is not completely inserted into the hole and into the cutouts 10 and is firmly held in the said position by the teeth 209 of the legs 9, which abut against the steps 210 of the outer wall, are defined by the boundary of the cutouts 10 and hold the contact 203 from disconnecting it. The teeth 209 abut their sides facing in the direction of the further introduction of the contact 203 in the cutouts 10, in the flat parts 12 of the Central cylindrical body 403.

After the connector is mounted on the contacts of the valve’s magnetic assembly, that is, the central pin-like contact is inserted into the first tubular contact 103 of the connector, and the input end of the central cylindrical part 403 simultaneously enters the cylindrical ground contact 2 of the magnetic assembly, which becomes radially aligned with open the annular part of the second contact 203, said second contact is pushed radially inward in the direction of further introduction into the insulating casing. During such a radial movement, which requires a certain predetermined pressure, the tabs 7, made in the form of sectors that form an open contact ring 203, diverge and elastically snap to fit to the outer surface of the cylindrical contact 2 of the magnetic assembly, and then the teeth being sunken due to their elasticity 203 are deflected outward by an inclined lead-in surface and extend beyond the corresponding trapezoidal protrusion 12, moving further along the additional path of radial connection, tog and both legs 8 due to its elastic force are entered into the recesses 10 through 108 thickenings.

Due to this design, that is, the presence of teeth 209 recessed due to their elasticity, the resistance force upon attachment arising between the part in the form of an open ring and the cylindrical contact 2 of the magnetic assembly is balanced in the axial direction. This is achieved by making the teeth 209 with a substantially similar resistance force upon attachment. In combination with tabs 8, this prevents axial misalignment of contact 203 during attachment.

According to another distinctive feature, the free ends of the legs 7, made in the form of sectors that form an open ring and must be connected to the cylindrical grounding contact 2 of the magnetic assembly, can be extended with the formation of guide protrusions formed by those parts of the legs that are inclined outward from the axis of the open ring in a direction substantially corresponding to the tangent at the point at which they touch the cylindrical contact 2 of the magnet ground. This facilitates the expansion of the open annular element during the execution of the radial movement of the attachment to the cylindrical contact 2 of the magnetic node.

The connector can be disconnected from these contacts of the magnetic assembly by simply applying a pulling force in the direction of the axis of the connector. For reattachment, the second contact 203 is relegated to the standby position by a light pulling force for withdrawal from cutouts 10 in the radial direction.

The force is necessary to divert the teeth 109 to the position in which they abut against the steps 210, and also so that the teeth 209 recessed due to their elasticity pass through the input guide surface 14 and abut against the corresponding flat part 12, as shown in FIG. 5.

This return operation is necessary because the optimal radial force for connecting the open ring element of the contact 203 with the cylindrical contact 2 of the magnetic assembly is provided by applying radial forces to the tabs 7, made in the form of sectors, which in the unloaded state form an open ring, the inner diameter of which is slightly smaller than the outer diameter of the cylindrical contact 2 of the magnetic node. Under these conditions, contact 203 cannot be held in the attachment position, that is, completely inserted into the insulating housing 3, and a new connection to the contacts of the magnetic assembly can be made by simple movement in the axial direction.

This attachment procedure may seem relatively complicated, however, the additional operation of introducing the contact 203 in the radial direction inside the insulating body 3 and moving it back to the ready position before reconnecting is simple and quick and also always ensures an optimal electrical connection between the contacts of the magnetic assembly and connector.

Claims (22)

1. A connector for connecting a thermocouple to the magnetic assembly of the gas flow control valve for regulating the gas flow in the burner, the magnetic assembly comprising a first pin contact connected to the conductor of the magnetic assembly and placed inside a second tubular cylindrical contact (2) connected to the ground contact of the magnetic assembly wherein the connector comprises an insulating body (3) having a central cylindrical element (403), the shape of which corresponds to the inner cavity of the second tubular cylindrical contour kta (2) of the magnetic assembly, the central cylindrical element (403) having an opening (903) that coincides with the first pin contact of the magnetic assembly, and containing in said opening (903) a first tubular contact (103) configured to connect to the first pin contact of the magnetic assembly, while the central cylindrical element (403) enters the second tubular cylindrical contact (2) of the magnetic assembly, the connector having a second female contact (203), which is located in the insulating housing (3) and the opening of which corresponds to the shape of the outer surface of the second tubular contact of the magnetic assembly, and this second female contact (203) of the connector is connected to said second tubular cylindrical contact (2) of the magnetic assembly when the first pin contact of the magnetic assembly is connected to the first tubular contact (103) of the connector, the first tubular the connector pin (103) is connected to a thermocouple hot junction conductor, and the second socket contact (203) of the connector is connected to a thermocouple cold junction conductor, characterized I mean that the second female contact (203) of the connector has a shape similar to an open cylindrical sleeve, and the insulating body (3) of the connector has a side hole for radial installation of the second female contact (203) of the connector on the second tubular cylindrical contact (2) of the magnetic assembly, moreover, this hole is located on the same level with the second tubular cylindrical contact (2) of the magnetic assembly when connecting the first tubular contact (103) of the insulating body (3) with the contacts of the magnetic assembly. 2. A connector according to claim 1, characterized in that the second female contact (203) of the connector is an open annular element covering on both sides, which is introduced into the contact by radial movement to the second tubular contact of the magnetic assembly. 3. The connector according to claim 1, characterized in that the cylindrical surface of the second socket contact of the connector, which is open axially, has an angular extent of more than 180 °. 4. The connector according to claim 3, characterized in that the open annular element is formed by two opposite to each other paws having the shape of a cylinder sector, each of which has an angular length of more than 90 °. 5. The connector according to claim 1, characterized in that the second female contact (203) of the connector has an open annular element on a part of its length, the angular length of which is more than 180 °, and a pair of side legs (8) located opposite each other on the rest, which are oriented in the direction of the connection of said second female contact (203) of the connector with the second tubular cylindrical contact (2) of the magnetic assembly and act as guide means interacting with respective guide cutouts (10) made in the isol uyuschem housing (3) between the respective terminal side walls (603) of the insulating body (3) and the central cylindrical element (403). 6. A connector according to claim 5, characterized in that the side legs located opposite each other can be of a set size, or have thicker rib-like parts (108), or have a non-planar shape so that the side legs located opposite each other (8) due to the elasticity of the material, they entered with force into the guide cutouts (10) of the insulating body (3). 7. The connector according to claim 1, characterized in that the second socket contact (203) of the connector and the insulating body (3) have interacting means (210, 109) to prevent disconnection, which come into effect when the second socket contact (203) is connected in an intermediate position in the guide cutouts (10) of the insulating body (3). 8. The connector according to claim 1, characterized in that the second female contact (203) of the connector and the insulating body (3) have stops (209, 12, 13, 14) to prevent the second female contact (203) from entering the guide cutouts (10) ) insulating casing, which come into effect at a given intermediate inserted position of the second female contact (203) in the insulating casing (3), and the resistance of the stops (209, 12, 13, 14) to prevent entry can be overcome by exceeding the specified force in the direction occurrences. 9. The connector according to claim 1, characterized in that the second socket contact (203) and the insulating housing (3) have both means (210, 109) to prevent separation, and stops (209, 12, 13, 14) to prevent entry. 10. The connector according to claim 6, characterized in that the predetermined intermediate inserted position of the second female contact (203) in the insulating housing (3) corresponds to the position in which this second female contact (203) is ready to be connected to the second tubular cylindrical contact (2 ) of the magnetic assembly, and in this standby position, the open annular part of the second socket contact (203) adjoins the second tubular cylindrical contact (2) of the magnetic assembly, and fits onto the central cylindrical element (403) of the insulating body ca (3), and in this position the open-ring part of the second female terminal (203) has a small clearance relative to the outer surface of the second tubular cylindrical contact (2) of the magnet assembly. 11. The connector according to claim 1, characterized in that the second female contact (203) of the connector has two pairs of side legs (8, 9) located opposite each other, that is, two legs (8, 9) on each side, these pairs of side tabs are located at some distance from each other and enter the corresponding guide cutout (10) of the insulating body (3), that is, between the side walls (603) of the hole for introducing the second socket contact (203) into the insulating body (3) and the central a cylindrical element (403) of the insulating body (3), while the second pair on the control and holding tabs (9) have at their free ends means for preventing separation, interacting with means (210) for preventing separation provided on each of the two guide cutouts (10), as well as stops (209) for preventing entry, interacting with transverse protrusions-stops on the Central cylindrical element (403), and the stops to prevent entry on the guides and holding tabs (9) are a tooth (209), which is made possible due to its elasticity pour from the position in which it rests against the stops to prevent entry (12, 13, 14), into the position in which it does not interfere with the said stops to prevent entry (12, 13, 14), and this retractable tooth is transferred to the position, in which it is not an obstacle by means of a pressure exceeding a predetermined threshold value. 12. The connector according to claim 11, characterized in that the guiding and holding tabs (9) have stops (209) recessed due to their elasticity to prevent entry, which interact with the surfaces restricting the entry of stops (12, 13, 14) to prevent entry on the corresponding guide cutouts (10) and restrict the movement of the second socket contact (203) when it is inserted into the insulating housing (3) of the connector, moreover, the stops that limit the occurrence of the surface (12) of the stops and the separation prevention stops, as well as those recessed due to of elasticity, the stops (209) to prevent entry and means (109) to prevent separation on the guides and holding tabs (9) are located at such a distance from each other that the second socket contact (203) is blocked from separation and from the introduction, whereas the stops restricting the occurrence of the stops (12) form the lateral input guide surfaces of the transverse protrusions-stops (13) for the guide and holding tabs (9), which can be overcome by applying to the second socket contact (203) in the radial direction a predetermined effort sufficient to translate the stops (209), which are recessed due to their elasticity, in order to prevent them from entering a position in which the corresponding transverse protrusion-stop (13) is overcome. 13. A connector according to claim 12, characterized in that each guide and holding tab (9) has a tooth (109) at the end to prevent separation, the stop surface of which is oriented in the direction of contact extraction from the insulating body (3), and which interacts with intermediate inner step (210), facing the bottom of the corresponding cut-out (10) for insertion into the insulating body (3), and at a certain distance from the opposite end, and each guide and holding tab (9) has a recessed due to its elastic guests tooth (209) interacting with the inclined surface (129) of the stop, which is the lateral surface of the transverse protrusion-stop (13), and the distance from the step (210) to prevent separation to the inclined guide of the input surface (110) corresponds to the distance from the surface of the holding and preventing the tooth from separating until the tooth (209) is recessed due to its elasticity, and said teeth (109, 210; 209, 12, 13, 14) are located on the guide and holding tabs (9) in such a position that the second socket contact (203 ) is temporarily blocked in a position in which it is ready to be attached to the corresponding second tubular cylindrical contact (2) of the magnetic assembly in the radial direction adjacent to it and can be inserted inside the insulating housing to the position in which it is connected to the contact of the magnetic assembly , by applying a force sufficient to overcome a given elastic deformation force in order to divert it to a position in which it does not abut the protruding teeth protruding due to its elasticity, limiting the occurrence. 14. The connector according to item 13, characterized in that the means (210) to prevent the separation, which interact with prevent the separation of the tooth (109) on the guide and holding tab (9), represent a step (210), made on the inner surface of the side wall (603), while the inclined stop restricting the entry surface (12) of the abutment with a corresponding protrusion-abutment (13) is provided on the central cylindrical element (403) along its part having the corresponding shape, which coincides with the recessed due to its control Guests preventing occurrence of tooth-focus guide and retention tabs (9), and this prevents disengagement claw (109) and recessed due to its elasticity prevents the occurrence of tooth-stop (209) extend outwardly from spaced opposite surfaces of the guide and retention tabs (9). 15. The connector according to item 13, wherein the step (210) to prevent separation, made on the side wall (603), limiting the guide cutouts (10), has a sawtooth shape with an inclined guide input surface (110) facing to the side the holes of the guide cut-out (10), which adjoins the remaining surface of the wall by means of an expanding step, and the tooth (109) interacting with it, which prevents separation, on the guide and holding tab (9) also has a sawtooth profile, but with the opposite entatsiey introductory guide and retaining abutment faces. 16. The connector according to claim 13, characterized in that the stop-tooth (209), which is recessed due to its elasticity, prevents the entry, is formed by an elastic tongue that protrudes to the inner side of the guide cutouts (10) for introducing the guide and holding tabs (9) moreover, this tongue is made by cutting and bending at the corresponding angle of the wall of the guide and holding tabs (9), while the protrusion-stop (13) is a transverse protrusion of a trapezoidal cross section. 17. The connector according to claim 16, wherein the trapezoidal protrusion has an unequal shape with a steeper side facing towards the open side of the guide cutouts (10) for access and a less steep side facing the bottom of the guide cutouts (10) . 18. The connector according to claim 8, characterized in that the force necessary to overcome the resistance of the recessed due to its elasticity, preventing the entry of the tooth-stop (209) relative to the protrusion-stop (13) is selected so that it is the same order of magnitude, as the force of joining the open annular part of the second socket contact (203) to the second tubular cylindrical contact (2) of the magnetic assembly. 19. The connector according to claim 1, characterized in that the open annular element of the second female contact (203) of the connector has expansion means interacting with the cylindrical surface of the second tubular cylindrical contact (2) of the magnetic assembly during radial attachment. 20. The connector according to claim 19, characterized in that each of the two parts (7) of the open annular element, having the shape of a cylinder sector, can have an end tab that is inclined outward in the radial direction so that the tabs of these two parts form opposite to each other surfaces expanding towards the free ends. 21. The method of connecting the contacts of the thermocouple to the contacts of the magnetic assembly of the gas flow control valve, in which the thermocouple contains two contacts connected to two corresponding contacts of the magnetic assembly, characterized by the following operations: connecting by axially mounting the insulating body (3) together with the first tubular contact (103) to the corresponding pin-like contact of the magnetic assembly, attaching the second female contact (203) to the second tubular cylindrical contact (2) of the magnetic assembly and by moving in the transverse and / or radial direction to said second tubular cylindrical contact (2) of the magnetic assembly. 22. The method according to item 21, wherein the disconnection is achieved by disconnecting the connector from the contacts of the magnetic unit in the axial direction, while reconnecting requires the operation of returning by pulling the second female contact (203) outward in the radial direction to the ready position.

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