JPH10211812A - Blower resistor for vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To form each resistive elements into a strip separated from each other by constituting plural pieces of these resistive elements with strip resistive foil separated respectively, and bending each of them along an insulating plate so as to hold this plate between. SOLUTION: A blower resistor Ra is composed of respective resistive elements 10 to 30 and three insulating plates 90 to 110 (each consisting of mica). These resistive elements 10 to 30 are rectilinear and formed by a strip resistive foil each. These resistive elements 10 to 30 are bent so as to pinch the insulating plate 90 at an intermediate part in the each longitudinal direction. This insulating plate 90 is made up of a plane form, and it performs such a role as preventing each electrical contact between both bending parts 11 and 12 of the resistive element 10, between both bending parts 21 and 22 of the resistive element 20 as well as between both bending parts 31 and 32 of the resistive element 30, respectively. Being constituted like this, these resistive elements 10 to 30 are made into a rectilinear strip form separated with one another in consequence.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a blower resistor for a vehicle.

[0002]

2. Description of the Related Art Conventionally, as this type of blower resistor,
There is one shown in Japanese Utility Model Laid-Open No. 2-145506. In this blower resistor, a plurality of resistance elements to be connected to the blower motor are formed as a resistance assembly having a predetermined resistance pattern by etching or punching a single planar resistance foil. .

[0003]

However, in the blower resistor, as described above, the resistor assembly is formed into a predetermined resistance pattern shape from one limited planar resistance foil. The shape becomes complicated. In addition, when the resistor assembly expands and contracts due to heat generated by energization or magnetic force, if the resistor assembly has a corner, stress is concentrated on the corner, and the resistor assembly is easily broken near the corner.

[0004] Further, when it is desired to change the resistance value of a part of the resistance assembly, even if it is not necessary to change the resistance value,
It is necessary to redesign the resistance pattern shape as a new resistor assembly, and it is not possible to quickly change a part of the resistor assembly, resulting in an increase in cost. In view of the above, an object of the present invention is to provide a blower resistor for a vehicle in which each resistance element has a band shape independent of each other.

[0005]

According to the first and second aspects of the present invention, a plurality of resistive elements are formed of independent strip-shaped resistive foils and sandwich an insulating plate. So that it is bent along this insulating plate. Thus, each resistance element has a band shape independent of each other.

For this reason, not only does the shape of each resistance element become simple, but even if each resistance element expands and contracts due to its energization, stress does not concentrate on a part of each resistance element. There is no partial breakage of the element. Further, even when it is desired to change the resistance value of the blower resistor, it is only necessary to change the design of the shape of the resistor element to be changed irrespective of the resistor element which does not need to be changed. Therefore, it is possible to quickly change the resistance element of the blower resistor and to reduce the cost.

Here, if the blower resistor is arranged in the air duct as described in claim 2, air cooling of each resistance element by ventilation in the air duct is ensured.
The effects of the invention described in (1) can be achieved. Claim 3
As in the invention described in the above, a plurality of resistance elements,
Even if it is composed of independent strip-shaped resistance foils and is fixed between the insulating plates without being bent, substantially the same operation and effect as the inventions of claims 1 and 2 can be achieved.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows a circuit configuration in which a blower resistor R according to the present invention is applied to a blower driving DC motor (hereinafter, referred to as a blower motor M) provided in a vehicle air conditioner.

The blower resistor R includes three resistor elements 10, 20, 3 connected in series with the blower motor M and the battery B.
0 and a leaf spring-shaped fuse 40. A switch mechanism S is connected between each of the resistance elements 10 to 30 and the fuse 40 and the negative electrode of the battery B. The changeover switch mechanism S includes a changeover contact S1.
And five fixed contacts S2 to S6, and the switching contact S1 is connected to the negative electrode of the battery B. Each of the fixed contacts S2 to S5 is a common terminal of the fuse 40 and the blower motor M,
0, 20 are connected to the common terminal of the two resistance elements 20, 30 and the remaining terminal of the resistance element 30. The fixed contact S6 is an off terminal.

In the switching mechanism S, the switching contact S1 is changed from the fixed contact S2 to the fixed contact S.
When the connection is sequentially switched over to 5, the number of resistance elements connected in series to the blower motor M between the battery B and the blower motor M increases stepwise. For this reason, the resistance value of the resistance element connected in series to the blower motor M also increases stepwise.

This means that the voltage applied to the blower motor M by the battery B decreases stepwise. As a result, the rotation speed of the blower motor M decreases stepwise. Next, the configuration of the blower resistor R will be described in detail with reference to FIGS.

The blower resistor R is disposed in the air duct of the air conditioner at a position where the blower air flow of the blower flows. As shown in FIGS. 2 to 4, the blower resistor R includes a substrate 50 and an upper heat sink 60, and the substrate 50 is fixed to an inner wall of the air duct. The connector 51 of the board 50 (see FIGS. 3 and 4) protrudes outside via the wall of the air duct.

The upper heat sink 60 has a rectangular upper wall 6.
Each of the legs 62 extending in an L-shape from the four corners of the
The upper wall 61 is fixed on the upper wall step 52, and the upper wall 61 is opposed to and parallel to the upper wall step 52. Also,
The blower resistor R has four terminals 70a to 70d.
And each of these terminals 70a to 70d
Are fixed at their bases into the through-holes 52a to 52d of the upper wall step 52 of the substrate 50. The base of each of the terminals 70a to 70d serves as an external circuit connection terminal of the connector 51.

The blower resistor R is connected to the lower heat sink 80.
The lower heat sink 80 is provided with the upper heat sink 60.
Are attached in parallel by crimping projections 63a of the sleeve wall 63 extending from each side edge in an L-shape. Further, the blower resistor R includes a band-shaped resistor Ra, which is sandwiched between the heat radiating plates 60 and 80.

The blower resistor Ra includes the above-described resistance elements 10 to 30 and three insulating plates 90 to 110 (both of which are
Each of the resistance elements 10 to 30 is formed of a linear and band-shaped resistance foil as shown in FIG. Each of these resistance elements 1
As shown in FIG. 4, each of the reference numerals 0 to 30 is bent so as to sandwich the insulating plate 90 at an intermediate portion in the longitudinal direction.

The insulating plate 90 has a planar shape as shown in FIGS. 4 and 6, and the insulating plate 90
Between the two bent portions 11 and 12, between the two bent portions 21 and 22 of the resistance element 20, and both the bent portions 3 of the resistance element 30
It plays a role of preventing each electrical contact between the first and the second 32. Here, the connection boundary between the two bent portions of the resistance elements 10 to 30 is engaged with the notches 91 to 93 formed on one side edge of the insulating plate 90 so as not to be laterally displaced. Both bent portions of each of the resistance elements 10 to 30, except for the bent portion 12, extend to the inside of a cutout 94 formed on the other side edge of the insulating plate 90 at each end.

The insulating plates 100 and 110 sandwich the resistance elements 10 to 30 and the insulating plate 90 with the insulating plate 90 sandwiched between the bent resistance elements 10 to 30. Thereby, both insulating plates 100 and 110 are
It plays a role of electrically insulating the resistance elements 10 to 30 from the outside. Note that the insulating plate 110 has a notch 111 corresponding to the notch 94 of the insulating plate 90.

Next, the connection structure of the fuse 40 and each of the resistance elements 10 to 30 will be described.
Is welded at one end 41 to the upper end of the terminal 70c, and the other end 42 of the fuse 40 is connected to a connecting portion 82 which is formed by cutting an intermediate portion of one side edge of the lower heat sink 80 downward. Soldered (see FIGS. 2 and 4). Accordingly, when an abnormally large current flows, each of the resistance elements 10 to 30 is overheated, the heat is transmitted to the lower heat sink 80, and the solder between the other end 42 of the fuse 40 and the connection portion 82 is melted,
The fuse 40 functions as a so-called fuse by being disengaged from the connection portion 82 at the other end 42 by its spring action.

The lower bent portion 12 of the resistance element 10
Are welded to the welding points 83 of the lower heat sink 80 through the through holes 112 of the insulating plate 110. Also, the resistance element 1
The notch 94 of the insulating plate 90 and the insulating plate 11
0 notch 111 and heat sink 80 notch 82
To the upper end of the terminal 70b.

The upper bent portion 21 of the resistance element 20
The lower bent portion 32 of the resistance element 30 is
Of the terminal 70 through the notch portion 94 of the insulating plate 110, the notch portion 111 of the insulating plate 110, and the notch portion 82 of the heat sink 80.
a is welded to the upper end. The upper bent portion 31 of the resistance element 30 is welded to the upper end of the terminal 70d through the notch 94 of the insulating plate 90, the notch 111 of the insulating plate 110, and the notch 82 of the heat sink 80.

As described above, the blower motor M and the fuse 4
0 and each of the resistance elements 10 to 30 are connected in series. In the present embodiment configured as described above, since each of the resistance elements 10 to 30 has a linear band shape independent of each other, the following various operational effects are produced.

That is, the shape of each resistance element of the blower resistor R is simplified, and the resistance of the blower resistor R is easily formed, which contributes to cost reduction. In this case, the resistance value of each of the resistance elements 10 to 30 can be easily determined by changing the width, length and thickness of the resistance element.
In consideration of a good crimping state during 80, a deviation of each resistance element and a heat transfer state, it is desirable that the thickness of each resistance element is the same.

Also, when it is desired to change the resistance value of the blower resistor R, it is only necessary to change the design of the shape of the resistor element to be changed irrespective of the resistor element which does not need to be changed. For this reason, it is possible to quickly change the resistance element of the blower resistor R and to reduce the cost of the design change. In addition, even if each of the resistance elements 10 to 30 expands and contracts due to heat generated by energization or magnetic force, thermal stress does not concentrate on a part of each of the resistance elements 10 to 30, and each of the resistance elements is partially broken. Nor.

Further, the outer dimensions of the blower resistor R can be reduced, and the number of rotation speed control stages of the blower motor M can be varied widely. The blower resistor R
As described above, is disposed at a position for receiving the blown airflow of the blower in the air duct. For this reason, the resistance element of the blower resistor R can be satisfactorily air-cooled by the blown air flow.

Further, even if an overcurrent flows through the resistance element of the blower resistor and abnormal heat is generated, the fuse 40 is connected to the blower motor M
Since the connection between the resistor and the resistance element 10 is cut off, the temperature does not reach high enough to cause ignition. Next, a modified example of the above embodiment will be described with reference to FIG. In this modification, the insulating plate 90A is the insulating plate 9 described in the above embodiment.
It is adopted instead of 0. The insulating plate 90 </ b> A has a configuration in which the notch portions 91 to 93 are formed in the insulating plate 90 instead of the cutout portions 91 to 93, respectively.

As a result, both bent portions of each of the resistance elements 10 to 30 described in the above-described embodiment are connected to the respective through-hole portions 95.
Through 97 are insulated and fixed. as a result,
The lateral displacement of each of the resistance elements 10 to 30 can be ensured as in the above embodiment. Other configurations, functions and effects are the same as those of the above embodiment. In implementing the present invention, the blower resistor R may be mounted on the outer wall of the air duct without being limited to the inside of the air duct.

In the embodiment of the present invention, the band shape of each of the resistance elements 10 to 30 is not limited to a straight line, but may be a curved line. In practicing the present invention, each of the resistance elements 10 to 30 may be fixed to the insulating plate 90 in a straight line without being bent as in the above embodiment. In this case, the width and the thickness of each resistance element may be increased by the length of each resistance element.

In implementing the present invention, the upper wall 61
Need not be parallel to the upper wall step 52 of the substrate 50, and may be mounted vertically or obliquely.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating a connection circuit of a resistance element and a fuse of a blower resistor according to an embodiment of the present invention.

FIG. 2 is a plan view of a blower resistor.

FIG. 3 is a side view of the blower resistor.

FIG. 4 is an exploded perspective view of the blower resistor.

FIG. 5 is a plan view of each resistance element.

FIG. 6 is a plan view of an insulating plate sandwiched between respective resistance elements.

FIG. 7 is a main part plan view showing a modification of the above embodiment.

[Explanation of symbols]

10 to 30: resistance element, 90: insulating plate, M: blower motor.

 ──────────────────────────────────────────────────続 き Continuing from the front page (72) Inventor Shinji Iwama 1-1-1, Showa-cho, Kariya-shi, Aichi Prefecture Inside Denso Co., Ltd. (72) Inventor Koji Nishio 23-1, Myoukaku, Inuyama, Inuyama-shi, Aichi Prefecture Nakamura Denki Kogyo Co., Ltd. Nagoya Factory

Claims (3)

[Claims] 1. A vehicle blower comprising: a plurality of resistance elements (10 to 30) connected to a blower motor (M) of a blower for a vehicle, wherein the number of these resistance elements connected in series to the blower motor or the resistance element to be used is switched. In a blower resistor for adjusting a voltage applied to a blower motor in a stepwise manner, each of the plurality of resistive elements is formed of an independent strip-shaped resistive foil, and each of the resistive foils sandwiches an insulating plate (90). A blower resistor for a vehicle, wherein the blower resistor is bent along an insulating plate. 2. A plurality of resistance elements (10 to 30) connected to a blower motor (M) of a blower arranged in an air duct of a vehicle air conditioner, and the number or use of these resistance elements connected in series to the blower motor. In a blower resistor arranged in the air duct, such that the applied voltage to the blower motor is adjusted stepwise by switching the resistance element to be performed, the plurality of resistance elements are each formed from an independent strip-shaped resistance foil. A blower resistor for a vehicle, wherein each of these resistance foils is bent along the insulating plate so as to sandwich the insulating plate (90). 3. A plurality of resistive elements (10 to 30) connected to a blower motor (M) of a blower disposed in an air duct of a vehicle air conditioner, and the number or use of these resistive elements in series with the blower motor. A blower resistor that adjusts the applied voltage to the blower motor stepwise by switching the resistance elements to be applied, wherein each of the plurality of resistance elements is formed of an independent band-shaped resistance foil and is not bent and is provided with an insulating plate (100, 11).
A blower resistor for an air conditioner for a vehicle, wherein the blower resistor is sandwiched and fixed at 0).