CN219287743U - Support structure for multitube PTC heater - Google Patents

Abstract

The utility model provides a bracket structure for a multi-tube PTC heater, which is used for installing a heating tube and a heat dissipation component and comprises the following steps: the heat radiation device comprises a first mounting seat, a first electrode mounting hole, a first guide groove, a second guide groove, a first mounting space and a second guide groove, wherein the first mounting groove is formed in one end face of the first mounting seat and is used for mounting one end of a heat radiation component, a plurality of electrode mounting holes penetrating through the first mounting groove are formed in the other end face of the first mounting seat, a plurality of first guide grooves are formed in the lower end face of the first mounting groove, a plurality of second guide grooves are formed in the upper end face of the first mounting groove, and a first mounting space is formed between the first guide grooves and the second guide grooves and is used for mounting one end of a heating pipe; the other end of the heating pipe and the other end of the heat dissipation component are respectively arranged on the second mounting seat. The advantage of this scheme lies in that this mounting structure can install different quantity heating pipes, selects corresponding quantity heating pipe according to specific demand.

Description

Support structure for multitube PTC heater

Technical Field

The utility model relates to the field of heating equipment, in particular to a bracket structure for a multi-tube PTC heater.

Background

PTC heaters generally have three structures, an adhesive tape type, an adhesive insulating type, and a tubular insulating type. The PTC heaters in the industry still have adhesive insulating heaters, and the heater with the structure mainly has two problems, namely, the production efficiency is low, only about 300 sets of heaters can be produced every day, and the reliability is inferior to that of a tubular insulating heater. Because the heating efficiency of the adhesive insulating single-piece heating sheet is high, the heating efficiency can reach about 110w/pcs, and the single-piece efficiency of the tubular insulating heating sheet is about 85 w/pcs. How to achieve the target power of the actual demand under the condition of fixed length is generally to increase the number of the heating aluminum tubes in a certain space.

However, heaters typically have different power requirements because the number of corresponding heating aluminum tubes also varies, based on which a common support can be made to accommodate the installation of different numbers of heating aluminum tubes.

In summary, the technical problem to be solved by the present application is to design a support with higher suitability to meet the installation of different numbers of heating aluminum tubes.

Disclosure of Invention

In order to solve the technical problems, the utility model provides a bracket structure for a multi-tube type PTC heater, in the scheme, a plurality of first installation spaces are arranged to install a heating tube, one installation space can be used for installing one heating tube, two electrodes of the heating tube are respectively led out from electrode installation openings, and the bracket structure has the advantages that the installation structure can be used for installing heating tubes with different numbers, and the corresponding number of heating tubes can be selected according to specific requirements.

The utility model provides a bracket structure for a multi-tube PTC heater, which is used for installing a heating tube and a heat dissipation component and comprises the following steps:

the heat dissipation device comprises a first mounting seat, wherein a first mounting groove is formed in one end face of the first mounting seat, the first mounting groove is used for mounting one end of the heat dissipation component, a plurality of electrode mounting openings penetrating through the first mounting groove are formed in the other end face of the first mounting seat, a plurality of first guide grooves are formed in the lower end face of the first mounting groove, a plurality of second guide grooves are formed in the upper end face of the first mounting groove, a first mounting space is formed between the first guide grooves and the second guide grooves, and the first mounting space is used for mounting one end of the heating pipe;

the other end of the heating pipe and the other end of the heat dissipation component are respectively arranged on the second mounting seat.

Preferably, a second mounting groove is formed in one end face of the second mounting seat, the second mounting groove is used for mounting the other end of the heat dissipation assembly, a plurality of third guide grooves are formed in the lower end face of the second mounting groove, a plurality of fourth guide grooves are formed in the upper end face of the second mounting groove, a second mounting space is formed between the third guide grooves and the fourth guide grooves, and the second mounting space is used for mounting the other end of the heating pipe.

Preferably, each first installation space is respectively connected with two electrode installation openings.

Preferably, a first isolation part is arranged in the first installation space, and the first isolation part is positioned between two electrodes of the heating pipe.

Preferably, a second isolation part is arranged on the other end face of the first mounting seat, and the second isolation part is positioned between two electrodes of the heating pipe.

Preferably, chamfers are respectively arranged on the first isolation part and the second isolation part.

Preferably, heat dissipation components are respectively arranged on two sides of the heating pipe.

The beneficial effects are that:

the utility model provides a support structure for a multi-tube PTC heater, which is characterized in that a plurality of first installation spaces are arranged for installing a heating tube, one installation space can be used for installing one heating tube, two electrodes of the heating tube are respectively led out from electrode installation openings, and the support structure has the advantages that the support structure can be used for installing heating tubes with different numbers, and the corresponding number of heating tubes can be selected according to specific requirements.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings used in the description of the embodiments or the prior art will be briefly described below.

Fig. 1 is a schematic perspective view of a support structure for a multi-tube PTC heater according to the present embodiment;

fig. 2 is a schematic perspective view of a view angle of the first mounting seat in the present embodiment;

fig. 3 is a schematic perspective view of another view angle of the first mounting seat in the present embodiment;

fig. 4 is a schematic perspective view of a second mounting seat in the present embodiment;

FIG. 5 is a schematic view of the mounting of a heating tube to the bracket structure of the present embodiment;

FIG. 6 is a schematic view of the mounting of two heating tubes by the bracket structure of the present embodiment;

fig. 7 is a schematic view of the bracket structure of the present embodiment for mounting three heating pipes.

Wherein reference numerals are as follows:

11-a first mount; 12-a first mounting groove; 13-a heat sink assembly; 14-electrode mounting port; 15-a first guide groove; 16-a second guide groove; 17-a first installation space; 18-heating the pipe; 19-a second mount; 20-a second mounting groove; 21-a third guide groove; 22-a fourth guide groove; 23-a second installation space; 24-a first separator; 25-electrodes; 26-second separator.

Detailed Description

The utility model is described in further detail below with reference to the accompanying drawings.

As shown in fig. 1 to 7, the present embodiment proposes a bracket structure for a multi-tube PTC heater for mounting a heating tube 18 and a heat radiation assembly 13, comprising:

the heat radiation device comprises a first mounting seat 11, wherein a first mounting groove 12 is formed in one end face of the first mounting seat 11, the first mounting groove 12 is used for mounting one end of a heat radiation component 13, a plurality of electrode mounting openings 14 penetrating through the first mounting groove 12 are formed in the other end face of the first mounting seat 11, a plurality of first guide grooves 15 are formed in the lower end face of the first mounting groove 12, a plurality of second guide grooves 16 are formed in the upper end face of the first mounting groove 12, a first mounting space 17 is formed between the first guide grooves 15 and the second guide grooves 16, and the first mounting space 17 is used for mounting one end of a heating pipe 18;

the second mounting seat 19, the other end of the heating pipe 18 and the other end of the heat dissipation assembly 13 are respectively mounted on the second mounting seat 19.

In this scheme, install heating pipe 18 through setting up a plurality of first installation space 17, one of them installation space can be used for installing a heating pipe 18, and two electrodes 25 of heating pipe 18 derive from electrode mounting port 14 respectively, and this scheme's advantage lies in this mounting structure can install different quantity heating pipe 18, selects corresponding quantity heating pipe 18 according to specific demand.

In addition, according to the corresponding number, the heat dissipation assemblies 13 with corresponding sizes and numbers can be selectively installed, and several installation forms of the corresponding heating pipes 18 and the heat dissipation assemblies 13 are shown in fig. 5 to 7. Wherein the heat sink assembly 13 is of prior art and comprises corrugated aluminum strips inside.

As an implementation manner of this embodiment, a second mounting groove 20 is provided on one end surface of the second mounting seat 19, the second mounting groove 20 is used for mounting the other end of the heat dissipating component 13, a plurality of third guide grooves 21 are provided on the lower end surface of the second mounting groove 20, a plurality of fourth guide grooves 22 are provided on the upper end surface of the second mounting groove 20, a second mounting space 23 is formed between the third guide grooves 21 and the fourth guide grooves 22, and the second mounting space 23 is used for mounting the other end of the heating pipe 18.

In this scheme second mounting structure mainly used discloses the structure of second mount pad 19, and second mounting structure can carry out effectual installation to heating pipe 18 and radiator unit 13 effectively.

Further, each of the first mounting spaces 17 is respectively engaged with two electrode mounting ports 14. The engagement here means that the projection of the electrode mounting opening 14 along the length direction of the heating tube 18 falls into the projection of the first mounting space 17 along the length direction of the heating tube 18.

Further, a first isolation portion 24 is provided in the first installation space 17, and the first isolation portion 24 is located between two electrodes 25 of the heating tube 18.

Further, the other end face of the first mounting seat 11 is provided with a second isolation portion 26, and the second isolation portion 26 is located between the two electrodes 25 of the heating tube 18.

In this scheme, the isolation length is effectively increased by the first isolation portion 24 and the second isolation portion 26, so that the electric breakdown between the two electrodes 25 of the heating tube 18 can be effectively avoided, and the safety is higher.

Further, the first and second isolation portions 24 and 26 are respectively provided with chamfers.

Further, heat dissipation components 13 are respectively disposed on two sides of the heating tube 18. This solution facilitates a better heat release from the heating tube 18.

It will be apparent to those skilled in the art that various modifications and improvements can be made without departing from the spirit of the utility model.

Claims (7)

1. A bracket structure for a multitube PTC heater for mounting a heating tube (18) and a heat radiation assembly (13), characterized by comprising:

the heat dissipation device comprises a first mounting seat (11), wherein a first mounting groove (12) is formed in one end face of the first mounting seat (11), the first mounting groove (12) is used for mounting one end of a heat dissipation component (13), a plurality of electrode mounting openings (14) penetrating through the first mounting groove (12) are formed in the other end face of the first mounting seat (11), a plurality of first guide grooves (15) are formed in the lower end face of the first mounting groove (12), a plurality of second guide grooves (16) are formed in the upper end face of the first mounting groove (12), a first mounting space (17) is formed between the first guide grooves (15) and the second guide grooves (16), and the first mounting space (17) is used for mounting one end of a heating pipe (18);

the other end of the heating pipe (18) and the other end of the heat dissipation component (13) are respectively arranged on the second mounting seat (19).

2. A support structure for a multi-tube PTC heater according to claim 1, wherein one end surface of the second mounting base (19) is provided with a second mounting groove (20), the second mounting groove (20) is used for mounting the other end of the heat radiation assembly (13), a plurality of third guide grooves (21) are provided on the lower end surface of the second mounting groove (20), a plurality of fourth guide grooves (22) are provided on the upper end surface of the second mounting groove (20), a second mounting space (23) is formed between the third guide grooves (21) and the fourth guide grooves (22), and the second mounting space (23) is used for mounting the other end of the heating tube (18).

3. A support structure for a multitube PTC heater according to claim 2, characterized in that each of the first mounting spaces (17) is respectively engaged with two of the electrode mounting openings (14).

4. A support structure for a multitube PTC heater according to claim 3, characterized in that a first spacer (24) is provided in the first installation space (17), the first spacer (24) being located between two electrodes (25) of the heating tube (18).

5. A support structure for a multitube PTC heater according to claim 4, characterized in that the other end face of the first mounting seat (11) is provided with a second separator (26), the second separator (26) being located between two electrodes (25) of the heating tube (18).

6. A bracket structure for a multitube PTC heater according to claim 5, wherein the first and second partition portions (24, 26) are provided with chamfers, respectively.

7. A support structure for a multitube PTC heater according to claim 1, characterized in that the two sides of the heating tube (18) are provided with heat dissipation members (13) respectively.

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