JPS5961027A - Semiconductor substrate heating apparatus - Google Patents

Abstract

PURPOSE:To heat or cool a heater block up to the specified temperature within a very short period of time by providing a cooling mechanism within a heating mechanism. CONSTITUTION:In a heater block 40, a heater 41 receives a signal of a temperature controller 47 and heats a heat plate 42 up to the specified temperature for the baking process. When a wafer is sent to the heater block, a coolant open/ close valve 46 is opened for the specified degree by the controller 47. Thereby, the coolant is circulated. As a result, temperature of heat plate 42 is lowered at a very fast rate. A temperature drop rate of the heat plate 42 is set at the prescribed value by adjusting an opening degree of the valve 46 by means of the controller 47 while the temperature of heat plate 42 is measured with a temperature sensor 48.

Description

[Detailed description of the invention] [Technical field of invention] The present invention relates to a semiconductor substrate heating device.

[Technical background of the invention and its problems]

In the manufacturing process of semiconductor devices, a heating device is used in a baking process. As the heating device, for example, those shown in FIG. 1(3) and FIG. 1(B) K are used.

This heating device has a hot plate 3 on a heater block 2 with a heater inside. On the hot plate 3, a transfer arm 5 for transferring a wafer, which is an object to be processed 4, is provided so as to be movable up and down and back and forth. The heat plate 3 has a temperature sensor 6 for measuring the heating temperature by the heater l.
is buried. The heating temperature by the heater 1 is controlled by the output of the temperature sensor 6, and the temperature of the object 4 on the transfer arm 5 is set to a predetermined temperature. Since the heating device configured in this manner only includes the heating heater 1 in the heating mechanism, the temperature of the hot plate 3 can be raised from a low temperature such as room temperature to a predetermined heating temperature in an extremely short time. be able to. However, once the temperature is set, the temperature of the hot plate 3 cannot be lowered to a predetermined low I, 1 degree per boat (from the condition of the product), the disadvantage is that it takes about 10 times as long as when the temperature rises. There is.

For the baking process, an oven-type heating device as shown in Figure 2 is used.

This heating device has a conveyor mechanism 23 to which a conveyor belt 22 for conveying the object to be processed 2 is attached to belt-driving Zollies 20 which are arranged opposite each other at a predetermined interval. Above the transport mechanism 23, there is a heating mechanism 2 with a heating section facing the transport surface.
4 is provided. The heating mechanism 24 includes a cover 24a with an opening facing the conveyance surface, a heat source 24b housed in the cover 24a, and a temperature sensor 24c provided above the conveyance surface. Heater 4 is
It is connected to a temperature sensor 24c via a temperature control section (not shown), and is configured to set the conveyance section within the oven to a predetermined temperature. In the figure, 24d is a lower cover forming the bottom of the oven.

This type of oven-type heating device is equipped with only a heating source 24b that only has the effect of increasing the temperature, similar to the above-mentioned one, so it is possible to raise the temperature inside the oven from a previously set high temperature state to a desired low temperature state. In order to lower the temperature, it takes much more time than in the case of increasing the temperature, which has the drawback of reducing work efficiency.

[Object of the Invention] An object of the present invention is to provide a semiconductor substrate heating device that can raise and lower the temperature of a heating mechanism on which an object to be processed is placed to a predetermined temperature in an extremely short period of time. be.

[Summary of the invention]

The present invention provides a cooling mechanism within the heating mechanism.
This is a semiconductor substrate heating device that can raise and lower the temperature of a heating part in a very short time using a predetermined temperature wave 1.

[Embodiments of the invention]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 3(5) is a side view of one embodiment of the present invention, and FIG.
) is a front view of the same embodiment. In the figure, 40 is a heater block with a built-in heater 41, and a heating plate 42 is mounted on the heater block 40 constituting the heating mechanism.
is placed. The hot plate 42VJc has the Abe collection groove 42.
Two ts are formed in parallel. Arm accommodation groove 42
a (Here, a transport arm 43 is housed so as to be able to move up and down and back and forth. The transport arm 43 moves the object to be processed 4 through the heater roller 40 and back and forth processes by moving up and down and back and forth.
It is designed to transport sea urchins (semiconductor substrates). The heater block 40 has a built-in cooling mechanism. The cooling mechanism operates through a refrigerant pipe 45 disposed at the bottom of the heater block 40, a refrigerant on-off valve 46 attached to the end of the refrigerant pipe F45 led out from the heater block 40, and a refrigerant on-off valve 46. and a refrigerant supply source (not shown) connected to the refrigerant 9-ignition 45. The refrigerant opening/closing valve 46 is connected to the temperature control section 47
to the temperature sensor 48 embedded in the hot plate 42 via the
electrically connected.

Thus, the semiconductor substrate heating device 49 configured in this manner
According to the method, first, the transport arm 43 is raised by a drive mechanism and receives the wafer, which is the object to be processed 44, from the previous process. Next, the transfer arm 43 moves forward to a predetermined position along the transfer direction while holding the wafer. Next, the transfer arm 43 descends, places the wafer on the hot plate 42, and then returns to the rear wafer supply position in the opposite direction to the transfer direction.

In the heater block 40, a heater 41 heats a hot plate 42 to a predetermined temperature in response to a signal from a temperature control section 47. The heating temperature of the hot plate 42 is detected by a temperature sensor 48. The temperature sensor 48
In response to the output, a predetermined heating signal is supplied to the heater 41r to accurately raise the temperature of the hot plate 42 to a predetermined temperature.

The wafer is subjected to a baking process by receiving heat transfer from the hot plate 42.

When the next wafer baking process is completed and the wafer with a low processing temperature is sent to the heating section, the temperature control section 47
supplies a predetermined valve opening degree signal to the refrigerant opening/closing valve 46,
The refrigerant on-off valve 46 is opened by a predetermined amount. When the refrigerant on-off valve 46 is opened, refrigerant is released from the refrigerant supply source.
A refrigerant, such as water, is circulated through the tube. As a result, the temperature of hot plate 42 decreases at an extremely rapid rate.

The temperature drop rate of the hot plate 42 is set to a predetermined value by adjusting the opening degree of the refrigerant opening/closing valve 46 using the temperature control unit 47 while measuring the temperature of the hot plate 42 using the temperature sensor 48 .

In this way, the temperature control unit 47 controls the temperature increase rate of the heater 41 of the heating mechanism and the temperature decrease rate of the cooling mechanism to bring the temperature of the hot plate 42 from a low temperature state to a desired high temperature state in an extremely short time. or easily set from a high temperature state to a desired low temperature state. As a result, workability can be improved.

Next, another embodiment of the present invention will be described with reference to FIG.

In the figure, reference numeral 50 denotes a conveyor belt 53 for conveying the object to be processed 52 to belt drive gooleys 51 that are disposed opposite to each other at a predetermined interval.
This is a transport mechanism with a .

A heating mechanism 54 is provided above the transport mechanism 50 with a heating section facing the transport surface. The heating mechanism 54 includes a cover 54th having openings facing each other on the conveyance surface, and a force/Z-
It is composed of a heating source 54b contained in a heating section 54a, and a temperature sensor 54c installed near the heating section.

In the upper part of the cover 54a, a refrigerant/mother 55 is arranged facing the heat source 54b. A large number of nozzles 55a are bored in the lower surface of the refrigerant tube 55. A refrigerant supply source (not shown) is connected to the refrigerant 55 led out from the cover 54th via a refrigerant opening/closing valve 56. The refrigerant opening/closing valve 56 is electrically connected to the temperature sensor 54c via a temperature control section (not shown). In the figure, 54d is a lower part of the cover 54a that constitutes the oven of the heating mechanism 54.

According to the semiconductor substrate heating device port configured in this way,
A wafer, which is the object to be processed 52, is placed on the conveying surface of the conveying belt 53, and the cover 54a is heated by the temperature sensor 54C.
While measuring the temperature inside the oven surrounded by
The temperature inside the oven can be raised from a low temperature state to baking temperature 1 in a short time. After the baking process of the wafer is completed, the wafer is then baked with a low processing humidity.
When the refrigerant gas is sent, a predetermined valve opening signal is supplied from the temperature control section to the refrigerant opening/closing valve 56, and the valve is opened to supply refrigerant gas from the refrigerant supply source into the refrigerant pipe fss. The supplied refrigerant gas flows into the oven from the nozzle 55a of the refrigerant pipe 55, and lowers the temperature inside the oven from the once set high temperature state to a predetermined low temperature state at an extremely rapid temperature drop rate. At this time, the temperature decreasing rate V is easily set to a predetermined value by measuring the temperature inside the oven with the temperature sensor 54c, and adjusting the valve opening degree of the refrigerant opening/closing valve 56 by the temperature control unit according to the output. All you can do is do it.

As a result, the temperature required for baking in the oven can be easily set from a low temperature state to a high temperature state, or from a high temperature state to a low temperature state, in an extremely short temperature processing time, improving work efficiency. be able to.

Note that in the oven-type semiconductor substrate heating device 60, the heating source 54b is provided above the transport surface.

It may be provided below. Moreover, although the conveyance mechanism 50 employs the conveyance belt 53, it is of course possible to use a multiple conveyance mechanism such as an air bearing system.

〔Effect of the invention〕

As explained above, according to the semiconductor substrate heating apparatus according to the present invention, the temperature of the heating mechanism can be raised or lowered to a predetermined temperature in an extremely short time.

[Brief explanation of the drawing]

Figure 1 is a front view of a conventional heating device, Figure (B) is a front view of the heating device, Figure 2 is a side sectional view of a conventional oven-type heating device, and Figure 3 is a side sectional view of a conventional oven-type heating device. Figure (A) is a side view of one embodiment of the present invention, Figure (B) is a front view of the same embodiment,
FIG. 4 is a side sectional view of another embodiment of the invention. 40... Heater block, 4... Heater, 4
2... Hot plate, 43... Transfer arm, 44... Processed object, 45... Refrigerant pipe, 46... Refrigerant opening/closing valve, 47... 1 degree control section, 48 River temperature safety @J
--14g...Semiconductor substrate heating device, 5o...Transportation mechanism, 51...Belt drive boob IJ-1s 2 river wave processing body, 53...Transportation belt, 54...Heating mechanism, 5
4a...Cover, 54h...Heating source, s 4 c.
...Temperature sensor, 54d...Lower cover, 55...
・Refrigerant/mother Eve, 56... Refrigerant opening/closing valve, 60,
,,Semiconductor substrate heating device.

Claims (1)

[Claims] A transport mechanism for the object to be processed, and the transport a! a heating mechanism provided close to the conveying surface of the image; a cooling mechanism built into the heating mechanism; a temperature sensor for measuring heating temperature provided in the heating mechanism; the temperature sensor and the heating mechanism; A semiconductor substrate heating apparatus comprising: a temperature control section electrically connected to the cooling mechanism.