Patent Description:
The present application relates to the field of protectors, particularly to a temperature fuse.

A temperature fuse is a kind of over-temperature protection component. When the protected electronic equipment has abnormal faults and heating, and the temperature reaches the fusing temperature of the temperature fuse, the fuse will be fused, thus cutting off the circuit. The temperature fuse is composed of a temperature-sensing body, an electrode, a ceramic housing, a push rod, a spring, etc. Usually, this type of product adopts the structure in which the fusible temperature-sensing body is placed at the bottom, and the push rod is placed above to push the spring leaf. The fusible temperature-sensing body melts when working, the push rod loses support, and the spring leaf separates from the electrode to cut off the circuit. The disadvantage of this structure is that the aging and shrinkage of the fusible temperature-sensing body will cause changes in the pressure between the spring leaf and the electrode contact point, resulting in poor contact.

The publication <CIT> describes a temperature fuse according to the preamble of claim <NUM>.

The technical problem to be solved by the present application is to provide a temperature fuse, which can effectively solve the problem of the pressure change resulting in poor contact of an electrode contact point caused by the aging of a temperature-sensing body.

To solve the above technical problems, the technical solutions adopted in the present application are as follows:
A temperature fuse includes a spring leaf and a contact point that is oppositely arranged to each other and further includes a spring mechanism, a temperature-sensing body, and a push rod. The spring mechanism includes springs and a spring column. The springs are sleeved at one end of the spring column, and when the temperature fuse is not triggered, the springs are in a state of compression. The temperature-sensing body abuts the other end of the spring column. One end of the push rod abuts the spring leaf, and the other end of the push rod abuts the end of a side wall of the spring column. The length of the temperature-sensing body in the expansion direction of the springs is greater than or equal to the length of the push rod abutting the spring column in the expansion direction of the springs.

Further, the spring column includes a seat body, two column bodies respectively arranged at both ends of the seat body on the same side, and a connecting part arranged on the seat body. The connecting part and the column bodies are arranged on the different sides of the seat body, and the springs are sleeved on the column bodies, respectively. The temperature-sensing body abuts the connecting part, and the other end of the push rod abuts a part of the seat body between the two column bodies.

Further, the temperature fuse includes a housing, two electrode sheets are interval and arranged at one end of the housing, and the two electrode sheets are accordingly electrically connected to the spring leaf and the contact point, respectively.

Further, a guide plate is arranged in the housing and is arranged at a position corresponding to the push rod.

Further, a copper cap is arranged in the housing, and the temperature-sensing body is arranged in the copper cap.

Further, the connecting part, the inner space of the copper cap, and the temperature-sensing body are cylindrical. The outer diameter of the connecting part is equal to the outer diameter of the temperature-sensing body, and the inner diameter of the copper cap is greater than the outer diameter of the connecting part.

Further, an installation plate is included. The other end of the housing is provided with an opening, the installation plate is fixed on the opening of the housing through the rivets to seal the opening, and the copper cap abuts the inner side wall of the installation plate.

Further, a cavity is arranged in the housing, and an insulating mica sheet and a resistance wire are arranged in the cavity. The resistance wire is electrically connected to a welding column arranged on the electrode sheet, and the insulating mica sheet is arranged between the resistance wire and the installation plate.

Further, the material of the housing is ceramic or plastic.

Further, the material of the push rod is ceramic or plastic.

The advantages of the present application are as follows:
The temperature fuse provided by the present application changes the traditional transmission manner of direct contact between the push rod and the temperature-sensing body. After improvements, the spring mechanism is added between the push rod and the temperature-sensing body to realize an indirect transmission between the push rod and the temperature-sensing body. Specifically, the spring mechanism includes the springs and the spring column, the springs are sleeved at one end of the spring column, and when the temperature fuse is not triggered, the springs are in a state of compression. The temperature-sensing body abuts the other end of the spring column. One end of the push rod abuts the spring leaf, and the other end of the push rod abuts the end of the side wall of the spring column. The length of the temperature-sensing body in the expansion direction of the springs is greater than or equal to the length of the push rod abutting the spring column in the expansion direction of the springs. When the temperature-sensing body is triggered, a compression force of the springs is released, such that the other end of the push rod is separated from the spring column. Then the spring leaf is separated from the contact point under the action of its elastic force to cut off the circuit. The structure is used to overcome the problem of poor electrode contact caused by the aging of the temperature-sensing body.

To explain the technical content, purpose, and effect of the present application in detail, as follows, the embodiments combined with the drawings are used to illustrate the present invention.

As shown in <FIG>, which is a schematic diagram showing the structure of a temperature fuse provided by the present application, including electrode sheets, a push rod spring, a push rod, and a spring mechanism. The spring of the push rod spring is sleeved on the push rod.

As shown in <FIG>, which show the design manners of the push rod in a temperature fuse provided by the present application, respectively. <FIG> shows that a guide post has a protrusion to fix an electric bridge to form the push rod.

Referring to <FIG> and <FIG>, Embodiment I of the present application is shown. In this embodiment, <FIG> and <FIG> show the structural schematic diagram and the exploded view in Embodiment I of the present application, respectively. The temperature fuse of the utility model has two electrode sheets that are respectively riveted on a ceramic housing. Spring leaves and contact points are respectively spot-welded on the two electrode sheets. The guide post <NUM> is welded together with the support <NUM>. In the support <NUM>, the floating spring <NUM> presses on the electric bridge <NUM>, such that a floating pressure appears when the electric bridge <NUM> contacts with the contact points <NUM>. The guide post <NUM>, the support <NUM>, the floating spring <NUM>, and the electric bridge <NUM> form a whole push rod, and the push rod spring <NUM> is placed at the front end of the push rod. When the temperature fuse is not triggered, the push rod spring <NUM> is in a state of compression. A resistance wire is welded on a welding column of the electrode sheet. When the product is used in a circuit with a large rated current, the resistance wire has an arc extinguishing function to prevent the spring leaves from producing an arc when the spring leaves separate from the contact points. The springs are placed in a cavity of the ceramic housing, a temperature-sensing body is placed in a copper cap, and the upper end of the temperature-sensing body supports the spring column. Specifically, the lower end of each of the column bodies of the spring column forms a large gap fit with the copper cap such that the large gap is conducive to the melt and discharge of the temperature-sensing body. The upper end of the spring column supports two springs. An installation plate is riveted with the ceramic housing to transfer the temperature and involved with the fixation. A cover plate is riveted together with the ceramic housing through rivets and has a dustproof and sealing function.

As shown in <FIG>, a temperature fuse provided by the present application includes a spring leaf and a contact point that is oppositely arranged to each other and further includes a spring mechanism, a temperature-sensing body, and a push rod. The spring mechanism includes springs and a spring column, the springs are sleeved at one end of the spring column, and when the temperature fuse is not triggered, the springs are in a state of compression. The temperature-sensing body abuts the other end of the spring column. One end of the push rod abuts the spring leaf, and the other end of the push rod abuts the end of a side wall of the spring column. The length of the temperature-sensing body in the expansion direction of the springs is greater than or equal to the length of the push rod abutting the spring column in the expansion direction of the springs.

According to the above description, the advantages of the present application are as follows:
The temperature fuse provided by the present application changes the traditional transmission manner of direct contact between the push rod and the temperature-sensing body. After improvements, the spring mechanism is added between the push rod and the temperature-sensing body to realize an indirect transmission between the push rod and the temperature-sensing body. Specifically, the spring mechanism includes the springs and the spring column, the springs are sleeved at one end of the spring column, and when the temperature fuse is not triggered, the springs are in a state of compression. The temperature-sensing body abuts the other end of the spring column. One end of the push rod abuts the spring leaf, and the other end of the push rod abuts the end of the side wall of the spring column. The length of the temperature-sensing body in the expansion direction of the springs is greater than or equal to the length of the push rod abutting the spring column in the expansion direction of the springs. When the temperature-sensing body is triggered, a compression force of the springs is released, such that the other end of the push rod is separated from the spring column. Then the spring leaf is separated from the contact point under the action of its elastic force to cut off the circuit. The structure is used to overcome the problem of poor electrode contact caused by the aging of the temperature-sensing body.

Further, the spring column includes a seat body, two column bodies arranged at both ends of the seat body on the same side, and a connecting part arranged on the seat body. The connecting part and the column bodies are arranged on the different sides of the seat body, and the springs are sleeved on the column bodies, respectively. The temperature-sensing body abuts the connecting part, and the other end of the push rod abuts a part of the seat body between the two column bodies.

According to the above description, through the above structure, the indirect transmission between the temperature-sensing body and the push rod is realized.

According to the above description, through the above structure, the guide plate is fixed in the housing by means of riveting and is arranged at the position corresponding to the push rod to prevent the push rod from falling off.

According to the above description, through the above structure, the temperature-sensing body is limited.

According to the above description, through the above structure, a large gap fit is formed between the connecting part of the spring column and the copper cap such that the large gap is conducive to the melt and discharge of the temperature-sensing body.

Further, the housing includes an installation plate. The other end of the housing is provided with an opening, the installation plate is fixed on the opening of the housing through the rivets to seal the opening, and the copper cap abuts the inner side wall of the installation plate.

According to the above description, through the above structure, the installation plate is riveted on the housing through the rivets to play the role of sealing and limiting the copper cap. In addition, the traditional temperature fuse is configured with resin and other materials for sealing. When the temperature is too high, the sealing material could melt. Thereby, it cannot be used in high-temperature environments. The sealing method with the above structure has the characteristics of high-temperature resistance and can realize the temperature fuse with a high melting point.

According to the above description, through the above structure, when the product is used in a circuit with a large rated current, the resistance wire has an arc extinguishing function to prevent the spring leaf from producing an arc when the spring leaf separates from the contact point.

According to the above description, through the above structure, the temperature resistance capacity reaches more than <NUM>.

Referring to <FIG>, Embodiment II of the present application is shown as follows:
The temperature fuse provided by the present application includes the spring leaf <NUM>, the contact point <NUM>, the spring mechanism, the temperature-sensing body <NUM>, the push rod <NUM>, the housing <NUM>, the guide plate <NUM>, the electrode sheets <NUM>, the mica sheet <NUM>, the copper cap <NUM>, the installation plate <NUM>, and the rivets <NUM>. In this embodiment, the material of the housing is ceramic or plastic. The material of the push rod is ceramic or plastic.

The two opposite ends of the housing <NUM> are openings, specifically the upper end opening and the lower end opening;
The spring leaf <NUM>, the contact point <NUM>, the spring mechanism, the temperature-sensing body <NUM>, the push rod <NUM>, the guide plate <NUM>, and the copper cap <NUM> are all arranged in the housing <NUM>. The two electrode sheets <NUM> are interval and arranged on both sides of the upper end opening, and the mica sheet <NUM> is arranged on the upper end opening and located between two electrode sheets. The two electrode sheets serve as the two electrical terminals of the product. In this embodiment, the mica sheet is configured to insert into the gap between the electrode sheet and the housing from the side and has a dustproof and sealing function.

The spring leaf <NUM> and the contact point <NUM> are oppositely arranged to each other, and the two electrode sheets are accordingly electrically connected to the spring leaf and the contact point, respectively.

The spring mechanism includes the springs <NUM> and the spring column <NUM>. The spring column includes the seat body <NUM>, two column bodies <NUM> respectively arranged at both ends of the seat body <NUM> on the same side, and the connecting part <NUM> arranged on the seat body. The connecting part <NUM> and the column bodies <NUM> are arranged on the different sides of the seat body, and the springs <NUM> are sleeved on the column bodies <NUM>, respectively. The springs <NUM> are sleeved at one end of the spring column <NUM>, and when the temperature fuse is not triggered, the springs are in a state of compression. The temperature-sensing body <NUM> abuts the other end of the spring column <NUM>. One end of the push rod <NUM> abuts the spring leaf <NUM>, and the other end of the push rod <NUM> abuts the end of the side wall of the spring column <NUM>. The length of the temperature-sensing body <NUM> in the expansion direction of the springs matches the length of the push rod <NUM> in the expansion direction of the springs. The temperature-sensing body <NUM> abuts the connecting part <NUM>, and the other end of the push rod <NUM> abuts the part of the seat body between the two column bodies.

The guide plate <NUM> is arranged in the housing <NUM> and is arranged at the position corresponding to the push rod. The guide plate is fixed in the housing by means of riveting and is arranged at the position corresponding to the push rod to prevent the push rod from falling off.

The copper cap <NUM> is arranged in the housing <NUM>, and the temperature-sensing body <NUM> is arranged in the copper cap <NUM>. The connecting part <NUM>, the inner space of the copper cap <NUM>, and the temperature-sensing body <NUM> are cylindrical. The outer diameter of the connecting part is equal to the outer diameter of the temperature-sensing body, and the inner diameter of the copper cap is greater than the outer diameter of the connecting part. The large gap fit is formed between the connecting part of the spring column and the copper cap, and the large gap is conducive to the melt and discharge of the temperature-sensing body.

The installation plate <NUM> is fixed on the lower end opening of the housing through the rivets <NUM> to seal the lower opening, and the copper cap <NUM> abuts the inner side wall of the installation plate <NUM>.

Preferably, the housing is ceramic, and the temperature-sensing body adopts a material with a trigger mechanism higher than <NUM>. The temperature fuse is further applied to temperatures above <NUM>.

Referring to <FIG>. Embodiment III of the present application is shown as follows:
The difference from Embodiment II lies in the addition of a resistance wire in the housing. Specifically, a cavity is arranged in the housing, and the insulating mica sheet <NUM> and the resistance wire <NUM> are arranged in the cavity. The resistance wire <NUM> is electrically connected to a welding column arranged on the electrode sheet <NUM>, and the insulating mica sheet <NUM> is arranged between the resistance wire <NUM> and the installation plate <NUM>. Through the above structure, when the product is used in a circuit with a large rated current, the resistance wire has an arc extinguishing function to prevent the spring leaf from producing an arc when the spring leaf separates from the contact point.

In conclusion, the temperature fuse provided by the present application changes the traditional transmission manner of direct contact between the push rod and the temperature-sensing body. After improvements, the spring mechanism is added between the push rod and the temperature-sensing body to realize an indirect transmission between the push rod and the temperature-sensing body. Specifically, the spring mechanism includes the springs and the spring column, the springs are sleeved at one end of the spring column, and when the temperature fuse is not triggered, the springs are in a state of compression. The temperature-sensing body abuts the other end of the spring column. One end of the push rod abuts the spring leaf, and the other end of the push rod abuts the end of the side wall of the spring column. The length of the temperature-sensing body in the expansion direction of the springs is greater than or equal to the length of the push rod abutting the spring column in the expansion direction of the springs. When the temperature-sensing body is triggered, the compression force of the springs is released, such that the other end of the push rod is separated from the spring column, and then the spring leaf is separated from the contact point under the action of its own elastic force to cut off the circuit. The structure is used to overcome the problem of poor electrode contact caused by aging of the temperature-sensing body and has the advantage of high-temperature resistance.

The above descriptions are only embodiments of the present application and do not limit the scope of the patent of the present application. All equivalent transformations made by means of the specification and the drawings of the present application, or the direct or indirect usage of the present application in the relevant technical fields shall fall within the scope of patent protection of the present application.

The terms "an embodiment," "embodiments," or "one or more embodiments" referred to herein mean that particular features, structures, or characteristics described in conjunction with the embodiments are included in at least one embodiment of the present application. In addition, please note that the examples of the term "in an embodiment" here do not necessarily refer to the same embodiment.

A large number of details are explained in the specification provided here. Whereas, it is understandable that the embodiments of the present application can be practiced without these specific details. In some embodiments, known methods, structures, and techniques are not shown in detail to avoid obscuring the understanding of this specification.

Claim 1:
A temperature fuse, comprising a push rod (<NUM>), a push rod spring (<NUM>), a spring mechanism, and a temperature-sensing body (<NUM>); the spring mechanism comprises springs (<NUM>) and a spring column (<NUM>), and when the temperature fuse is not triggered, the springs (<NUM>) are in a state of compression; the temperature-sensing body (<NUM>) abuts the other end of the spring column (<NUM>); one end of the push rod (<NUM>) abuts the push rod spring (<NUM>), and when the temperature fuse is not triggered, the push rod spring (<NUM>) is in the state of compression;
characterised in that
the springs (<NUM>) are sleeved at one end of the spring column (<NUM>), and in that
the other end of the push rod (<NUM>) abuts an end of a side wall of the spring column (<NUM>); and a length of the temperature-sensing body (<NUM>) in an expansion direction of the springs (<NUM>) is greater than or equal to a length of the push rod (<NUM>) abutting the spring column (<NUM>) in the expansion direction of the springs (<NUM>).