JP6073764B2 - Piezoelectric oscillator with temperature chamber - Google Patents

Description

  The present invention relates to a thermostatic chamber-equipped piezoelectric oscillator.

As an example of a piezoelectric oscillator that is a frequency device used in mobile communication equipment and transmission communication equipment, there is a thermostatic bath-equipped piezoelectric oscillator.
The thermostat-equipped piezoelectric oscillator is used as a reference signal source for a base station for a mobile terminal, for example, in situations where frequency temperature characteristics are required such that the frequency deviation is small with respect to a specified output frequency even when the ambient temperature changes. Yes.

As shown in FIG. 3, the thermostatic chamber-equipped piezoelectric oscillator 200 includes a base 232, a metal cover 235, and a piezoelectric vibrating element 234 that is connected and fixed to two holding portions 233 protruding in pairs from a predetermined surface of the base 232. Two protruding in opposite directions from the surface of the base 232 opposite to the surface from which the holding portion 233 protrudes and the piezoelectric vibrator main body portion 231 configured in a hermetically sealed state. A piezoelectric vibrator 230 including a pair of lead parts 236 is provided, and the piezoelectric vibrator 230 is mounted on a printed circuit board section 220 on which the heater section 240 is mounted.
At this time, the metal cover portion 235 of the piezoelectric vibrator main body portion 231 is in contact with the heater portion 240 mounted on the printed circuit board portion 220, and two pairs of lead portions protruding from the piezoelectric vibrator main body portion 231. 236 extends parallel to the surface on which the printed circuit board unit 220 is mounted, and is then bent and fixed to a predetermined position on the printed circuit board unit 220.
The printed circuit board unit 220 includes a plurality of electronic elements 250 that are electrically connected to the piezoelectric vibrator 230 to form at least an oscillation circuit and also constitute an electronic circuit for controlling the temperature of the heater unit 240. In addition, a wiring pattern (not shown) is provided so as to electrically connect the constituent elements.

In the thermostatic chamber-equipped piezoelectric oscillator 200 having at least the above-described structure, when the metal cover 235 is heated by the heater 240, the heat of the heater 240 moves to the metal cover 235 and moves in the metal cover 235. Heat is radiated into the atmosphere in which the piezoelectric vibration element 234 exists, and the temperature in the atmosphere in which the piezoelectric vibration element 234 exists can be increased.
That is, in such a piezoelectric oscillator 200 with a thermostatic bath, the metal cover portion 235 and the base portion 232 of the piezoelectric vibrator main body 231 serve as a thermostatic bath, and the temperature of the heater portion 240 that heats the metal cover portion 235 is controlled. By controlling, the temperature in the atmosphere where the piezoelectric vibration element 234 exists is made as constant as possible, and the frequency deviation amount is reduced with respect to the specified output frequency even if the ambient temperature changes. (For example, refer to Patent Document 1).

JP 2002-223122 A

In the thermostat-equipped piezoelectric oscillator 200 as described above, the heat of the heater part 240 moves to the metal cover part 235 in contact with the heater part 240 and the printed circuit board part 220 on which the heater part 240 is mounted.
The heat of the heater part 240 that has moved to the metal cover part 235 moves inside the metal cover part 235 and is radiated into the atmosphere where the piezoelectric vibration element 234 exists, and moves to the piezoelectric vibration element 234 and the holding part 233. Further, the heat that has moved to the holding portion 233 moves to the lead portion 236 that is electrically connected after moving inside the holding portion 233.
The heat of the heater unit 240 that has moved to the printed circuit board unit 220 moves through the printed circuit board unit 220 and moves to the lead unit 236 that is connected and fixed to the printed circuit board unit 220.
Therefore, in the thermostatic chamber-equipped piezoelectric oscillator 200, the piezoelectric vibration element 234 is maintained until the temperature inside the lead portion 236 existing between the piezoelectric vibrator main body portion 231 and the printed circuit board portion 220 becomes a constant temperature with the holding portion 233. In this configuration, the heat in the atmosphere in which the gas is present continues to move to the lead portion 236.
For this reason, in the thermostat-equipped piezoelectric oscillator 200, the heat continues to move until the temperature of the lead portion 236 between the piezoelectric vibrator main body portion 231 and the printed circuit board portion 220 becomes a constant temperature with the holding portion 233, There is a risk that it may be difficult to keep the temperature in the atmosphere where the piezoelectric vibration element 234 exists constant.
As a result, it is difficult for the thermostat-equipped piezoelectric oscillator 200 to control the frequency of the piezoelectric vibration element 234 with high accuracy and constant, and the frequency value of the output signal may be likely to fluctuate.

  Further, in the thermostatic chamber-equipped piezoelectric oscillator 200, heating is performed by the heater unit 240 until the temperature inside the lead unit 236 between the piezoelectric vibrator main body 231 and the printed circuit board unit 220 becomes constant with the temperature of the holding unit 233. There was a problem that it had to continue and consumed a lot of power.

  Therefore, in the present invention, compared with a conventional piezoelectric oscillator with a thermostatic bath, the frequency of the piezoelectric vibration element is set with high accuracy by reducing the time for heat to move from the atmosphere in which the piezoelectric vibration element exists to the lead portion. An object of the present invention is to provide a thermostatic chamber-equipped piezoelectric oscillator that can be controlled uniformly and can suppress power consumption of a heater section.

  In order to solve the above-mentioned problem, a piezoelectric oscillator with a thermostatic bath according to the present invention includes a bottom plate member and a printed circuit board provided on one main surface of the bottom plate member at a predetermined interval from the bottom plate member. A piezoelectric vibrator provided in the printed board portion, a heater provided in the printed board portion for heating the piezoelectric vibrator, and provided in the printed board portion and electrically connected to the piezoelectric vibrator. A plurality of electronic elements constituting an electronic circuit for controlling the temperature of the heater section, and electrically connecting with the electronic elements, and connecting the printed circuit board section to the bottom plate member A plurality of connection pins provided so as to pass through the bottom plate member and project to the other main surface side of the bottom plate member while holding on one main surface; the printed circuit board portion; the piezoelectric vibrator; And a lid member attached to the bottom plate member so as to cover the electronic element, wherein the piezoelectric oscillator includes a piezoelectric vibrator main body part, The piezoelectric vibrator main body includes a base, two pairs of holding portions protruding from one main surface of the base, and piezoelectric vibration connected and fixed to the holding portion. Element, and a metal cover part that hermetically seals the piezoelectric vibration element with the base, and the lead part is electrically connected to the holding part inside the base Projecting from the other main surface of the base portion, and the lead portion and the printed circuit board portion are thinner than the lead portion and thermally conductive so as to be electrically connected to the lead portion and the predetermined electronic element. Is electrically connected by a highly flexible wire section. It is characterized in.

Since the piezoelectric oscillator with a thermostatic bath according to the present invention electrically connects the lead part and the printed circuit board part with a wire part having higher thermal conductivity than the lead part, compared with the conventional piezoelectric oscillator with a thermostatic bath. The length of the lead portion can be shortened by the amount corresponding to the wire portion, and the time for heat to move through the wire portion can be shortened.
Therefore, in the piezoelectric oscillator with a thermostatic bath according to the present invention, until the temperature of the lead portion existing between the piezoelectric vibrator main body portion and the printed circuit board portion in the conventional piezoelectric oscillator with a thermostatic bath reaches a constant temperature with the holding portion. Compared to the above time, it is possible to shorten the time until the temperature of the lead portion and the wire portion existing between the piezoelectric vibrator main body portion and the printed board portion becomes a constant temperature with the holding portion.
Therefore, the thermostatic chamber-equipped piezoelectric oscillator according to the present invention can shorten the time required for the heat in the atmosphere in which the piezoelectric vibration element exists to move to the lead portion as compared with the conventional thermostatic chamber-equipped piezoelectric oscillator. The temperature in the atmosphere where the vibration element exists can be kept constant.
As a result, the thermostatic chamber-equipped piezoelectric oscillator according to the present invention can control the frequency of the piezoelectric vibration element to be constant with high accuracy, and can prevent the frequency value of the output signal from fluctuating.

In addition, in the piezoelectric oscillator with a thermostat according to the present invention, the time required for the heat in the atmosphere in which the piezoelectric vibration element exists to move to the lead portion can be shortened. The heating time of the part can be shortened.
Therefore, the piezoelectric oscillator with a thermostat according to the present invention can suppress the electric power consumed in the heater portion as compared with the conventional piezoelectric oscillator with a thermostat.

In the piezoelectric oscillator with a thermostatic bath according to the present invention, the lead portion and the printed circuit board portion are connected by the wire portion that is thinner than the lead portion and has high thermal conductivity. Compared to the surface area of the lead part existing between the main body part and the printed circuit board part, the area between the piezoelectric vibrator main body part and the printed circuit board part can be reduced and the amount of radiated heat can be suppressed, and Compared with the heat capacity between the piezoelectric vibrator main body and the printed circuit board in the conventional piezoelectric oscillator with a thermostat, the heat capacity between the piezoelectric vibrator main body and the printed circuit board can be reduced.
For this reason, in the piezoelectric oscillator with a thermostatic bath according to the present invention, it is possible to suppress the electric power consumed in the heater portion as compared with the conventional piezoelectric oscillator with a thermostatic bath.

(A) is a top view which shows an example in the state in which the cover member is not provided in the piezoelectric oscillator with a thermostat of this invention, (b) is a cover member provided in the piezoelectric oscillator with a thermostat of this invention. It is sectional drawing when cut | disconnecting by AA of Fig.1 (a) in the state by which it was carried out. It is a disassembled perspective view which shows an example of the piezoelectric vibrator used with the piezoelectric oscillator with a thermostat of this invention. (A) is a plane which shows an example in the state which does not provide a cover member in the conventional piezoelectric oscillator with a thermostat, (b) is a figure in the state where the cover member was provided in the conventional piezoelectric oscillator with a thermostat. It is sectional drawing when cut | disconnecting by BB of 3 (a).

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The following drawings are schematic. Accordingly, details may be omitted, and the dimensional ratios do not always match the actual ones.

(Basic configuration of a piezoelectric oscillator with a thermostatic chamber)
As shown in FIG. 1, the thermostatic chamber-equipped piezoelectric oscillator 100 includes at least a bottom plate member 110, a printed board part 120, a piezoelectric vibrator 130, a heater part 140, a plurality of electronic elements 150, connection pins 160, and a lid member 170. ing.

As a material of the bottom plate member 110, for example, brass is used.
The bottom plate member 110 includes, for example, a rectangular flat plate-shaped bottom plate portion and a side wall portion that is provided integrally with the bottom plate portion along the end portion of one main surface of the bottom plate portion. .

  Here, the surface of the side wall portion opposite to the surface in contact with the bottom plate portion is set as one main surface of the bottom plate member 110, and the other main surface of the bottom plate portion is set as the other main surface of the bottom plate member 110.

The printed circuit board unit 120 is provided on one main surface of the bottom plate member 110 at a predetermined interval from the bottom plate member 110. Also, the printed circuit board unit 120 is provided with components to be described later. A pad (not shown) and a wiring pattern (not shown) for electrically connecting the components are formed.
Further, the printed circuit board part 120 has a surface on which pads and wiring patterns are formed smaller than one main surface of the bottom plate member 110.

  As shown in FIG. 1 and FIG. 2, the piezoelectric vibrator 130 is mounted on the printed circuit board part 120, and includes a piezoelectric vibrator main body part 131 and two pairs of lead parts 136.

  The piezoelectric vibrator main body 131 includes a base portion 132, two pairs of holding portions 133, a piezoelectric vibration element 134, and a metal cover portion 135.

  The base 132 has, for example, a substantially rectangular parallelepiped shape.

  The two pairs of holding portions 133 are made of, for example, Kovar as a material, and protrude from the predetermined surface of the base portion 132 in the same direction while being insulated from the base portion 132.

  Here, the surface of the base portion 132 from which the holding portion 133 protrudes is defined as one main surface of the base portion 132, and the surface opposite to the one main surface of the base portion 132 is defined as the other main surface of the base portion 132.

The piezoelectric vibration element 134 includes, for example, a piezoelectric piece 134a, an excitation electrode 134b, and an extraction electrode 134c.
As the piezoelectric piece 134a, for example, quartz that is a circular flat plate-shaped piezoelectric material is used.
The excitation electrodes 134b are, for example, a pair of two, and are formed so as to face each other on both main surfaces of the piezoelectric piece 134a.
For example, two pairs of extraction electrodes 134c are formed, and one end is connected to the excitation electrode 134b, and the other end is formed at the end of the piezoelectric piece 134a.
In the piezoelectric vibration element 134 as described above, when a voltage is applied to the extraction electrode 134c, the piezoelectric piece 134a sandwiched between the excitation electrodes 134b starts to vibrate due to the piezoelectric effect and the inverse piezoelectric effect. Further, such a piezoelectric vibration element 134 has a property that the frequency when vibrating depends on the temperature in the atmosphere in which the piezoelectric vibration element 134 exists.
In the piezoelectric vibration element 134, for example, two pairs of extraction electrodes 134c are connected and fixed to the two pairs of holding portions 133 by a conductive adhesive (not shown), and are held by the holding portion 133. It has become.

For example, a substantially rectangular parallelepiped Kovar is used for the metal cover part 135, and a piezoelectric vibration element accommodation space 135a having a size capable of accommodating the piezoelectric vibration element 134 and the holding part 133 is formed.
In addition, the metal cover part 135 places the piezoelectric vibration element 134 and the holding part 133 in the piezoelectric vibration element accommodation space in a state where the opening of the piezoelectric vibration element accommodation space 135 a faces the piezoelectric vibration element 134 held by the holding part 133. While being accommodated in 135a, it is cold-welded to the base 132. At this time, the piezoelectric vibration element 134 and the holding portion 133 have a structure that does not come into contact with the surface of the metal cover portion 135 facing the inside of the piezoelectric vibration element storage space 135a.

  The piezoelectric vibrator main body 131 is configured with the above-described configuration. In the piezoelectric vibrator main body 131, the piezoelectric vibration element 134 held by the holding portion 133 is hermetically sealed in the piezoelectric vibration element storage space 135a. It is in a state.

For example, the lead portion 136 is made of Kovar having a diameter of about 0.8 mm, and protrudes in pairs from the other main surface of the base portion 132 of the piezoelectric vibrator main body portion 131 while being insulated from the base portion 132.
In addition, the lead portion 136 is in a state of being electrically connected to the holding portion 133 inside the base portion 132 although not particularly illustrated.
Further, the lead portion 136 is shorter than the lead portion 236 of the conventional thermostatic oven-equipped piezoelectric oscillator 200 by the amount of the wire portion 180 described later.

  The piezoelectric vibrator 130 is configured as described above. The piezoelectric vibrator element 134 is hermetically sealed in the piezoelectric vibrator main body 131, and the excitation electrode 134 b leads through the extraction electrode 134 c and the holding portion 133. It is in a state of being electrically connected to the part 136.

As shown in FIG. 1, the heater unit 140 is connected and fixed to a predetermined pad of the printed circuit board unit 120.
A metal cover 135 of the piezoelectric vibrator 130 is in contact with the surface of the heater section 140 facing the surface in contact with the printed circuit board section 120, so that the piezoelectric vibrator 130 can be heated by the heater section 140. ing.
Therefore, in the piezoelectric oscillator 100 with a thermostatic bath according to the embodiment of the present invention, the piezoelectric vibrating element 134 hermetically sealed with the metal cover part 135 and the base part 132 is formed by heating the metal cover part 135 with the heater part 140. The temperature in the existing atmosphere can be increased. That is, the thermostatic chamber-equipped piezoelectric oscillator 100 according to the embodiment of the present invention can be considered that the metal cover portion 135 and the base portion 132 of the piezoelectric vibrator main body portion 131 serve as a thermostatic chamber.

The plurality of electronic elements 150 are connected and fixed to predetermined pads of the printed circuit board unit 120.
Some predetermined electronic elements 150 are electrically connected to the piezoelectric vibrator 130 and constitute an oscillation circuit.
In addition, some other predetermined electronic elements 150 constitute an electronic circuit for controlling the temperature of the heater section.

The connection pin 160 is connected and fixed in a state of penetrating the printed circuit board portion 120 and is in a state of being electrically connected to the electronic element 150 by a wiring pattern.
Further, the connection pin 160 is provided so as to penetrate the bottom plate member 110 and protrude from the other main surface of the bottom plate member 110 while holding the printed circuit board portion 120 on one main surface of the bottom plate member 110. At this time, the connection pin 160 is insulated from the bottom plate member 110.
The connection pin 160 protruding to the other main surface side of the bottom plate member 110 serves as a mounting terminal of the thermostat-equipped piezoelectric oscillator 100.
In addition, as a material of the connection pin 160, for example, Kovar is used.

The lid member 170 is attached to the bottom plate member 110 so as to cover the printed circuit board unit 120, the piezoelectric vibrator 130, the heater unit 140, and the electronic element 150. At this time, the lid member 170 does not contact the printed circuit board unit 120, the piezoelectric vibrator 130, the heater unit 140, and the electronic element 150.
Further, for example, a rectangular parallelepiped brass is used for the lid member 170, and a printed circuit board portion storage space having an opening larger than one main surface of the bottom plate member 110 is formed.
Further, the lid member 170 has, for example, a screw hole (not shown) formed in the side wall portion of the bottom plate member 110, and is fixed to the bottom plate member 110 by screws (not shown).

(Configuration to shorten the time for heat to move to the lead)
In addition to the basic configuration described above, the piezoelectric oscillator 100 with a thermostatic bath according to the embodiment of the present invention is a lead for reducing the time for heat to move from the atmosphere in which the piezoelectric vibration element 134 exists to the lead portion 136. The part 136 and the printed circuit board part 120 are electrically connected by a wire part 180.

As shown in FIG. 1, the wire portion 180 has one end portion connected and fixed to the lead portion 136 while the other end portion connected and fixed to a predetermined pad of the printed circuit board portion 120. A predetermined pad of the substrate portion 1320 is electrically connected.
Therefore, the length of the lead portion 136 can be shortened by the wire portion 180 as compared with the lead portion 236 of the conventional thermostatic oven-equipped piezoelectric oscillator 200.

Further, the wire portion 180 is thinner than the lead portion 136, and for example, one having a diameter of about 0.3 mm is used.
Compared with the surface area of the lead portion 236 connecting the piezoelectric vibrator main body 231 and the printed circuit board portion 220 in the conventional thermostatic oven-equipped piezoelectric oscillator 200, the piezoelectric vibration is reduced by using the wire portion 180 thinner than the lead portion 136. The surface areas of the lead portion 136 and the wire portion 180 that connect the child main body portion 130 and the printed board portion 130 can be reduced. For this reason, the radiation (radiation) of heat from the surfaces of the lead part 136 and the wire part 180 connecting the piezoelectric vibrator main body part 131 and the printed circuit board part 120 can be reduced as compared with the prior art. Power to be reduced.
Here, that the thickness is thinner than the lead portion 136 indicates a state in which the cross-sectional area of the wire portion 186 is smaller than the cross-sectional area of the lead portion 136.

Further, the wire portion 180 has higher thermal conductivity than the lead portion 136.
Here, thermal conductivity indicates the ease with which heat is transmitted, and high thermal conductivity means that heat from one end to the other moves when compared at the same length. It shows a state where the time to do is short.
By making the thermal conductivity of the wire portion 180 higher than that of the lead portion 136, the temperature of the lead portion 236 existing between the piezoelectric vibrator main body portion 231 and the printed circuit board portion 220 in the conventional thermostatic bath-equipped piezoelectric oscillator 200 is almost equal. Compared to the constant time, it is possible to shorten the time during which the temperature inside the lead part 136 and the wire part 180 existing between the piezoelectric vibrator main body 131 and the printed circuit board part 120 is substantially constant. .

As such a wire rod part 180, for example, white is used.
Moreover, Western white has good solder wettability and excellent flexibility. For this reason, when using white, it is easy to be connected and fixed to the lead portion and the printed circuit board portion and can be easily deformed, so that the working efficiency can be improved when the connection is fixed.
In addition, Western white has excellent corrosion resistance and is not easily rusted. For this reason, even if it uses it in a humid environment, it can be used for a long time compared with the case where it is not excellent in corrosion resistance, such as iron.

  Since the thermostatic chamber-equipped piezoelectric oscillator 100 according to the embodiment of the present invention configured as described above has a property that heat moves from a high temperature to a low temperature, the heater unit When heated by 140, the heat of the heater part 140 moves to the metal cover part 135 and the printed circuit board part 120 with which the heater part 140 is in contact.

  The heat of the heater part 140 that has moved to the metal cover part 135 moves inside the metal cover part 135 and is radiated into the atmosphere in which the piezoelectric vibration element 134 exists, that is, into the piezoelectric vibration element storage space 135a. After moving into the element storage space 135a, the piezoelectric storage element 134 moves to the piezoelectric vibration element 134 and the holding unit 133 existing in the piezoelectric vibration element storage space 135a. Thereafter, the heat that has moved to the piezoelectric vibration element 134 and the holding portion 133 moves to the lead portion 136 that is electrically connected to the holding portion 133, and the inside of the lead portion 136 toward the wire rod portion 180 and the printed board portion 120 side. Moving.

  The heat of the heater unit 140 that has moved to the printed circuit board unit 120 travels inside the printed circuit board unit 120 and moves to the wire rod unit 180 that is in contact with the printed circuit board unit 120. The heat that has moved from the printed board 120 to the wire member 180 moves through the wire member 180 toward the lead 136 and the piezoelectric vibrator main body 131. Here, only the case of moving to the wire portion 180 has been described, but heat has also moved to the plurality of electronic elements 150 mounted on the printed circuit board portion 120.

In such a thermostatic oven-equipped piezoelectric oscillator 100 according to the embodiment of the present invention, the lead portion 136 and the printed circuit board portion 120 are electrically connected by the wire portion 180. Compared with the lead part 236, the length of the lead part 136 can be shortened.
In addition, the thermostatic chamber-equipped piezoelectric oscillator 100 according to the embodiment of the present invention electrically connects the lead part 136 and the printed circuit board part 120 by the wire part 180 having higher thermal conductivity than the lead part 136. Compared with the time until the temperature of the lead portion 236 existing between the piezoelectric vibrator main body portion 231 and the printed circuit board portion 220 in the thermostatic chamber-equipped piezoelectric oscillator 200 becomes a constant temperature with the holding portion 233, the piezoelectric vibration The time until the temperature of the lead part 136 and the wire part 180 existing between the child main body part 131 and the printed circuit board part 120 becomes a constant temperature with the holding part 133 can be shortened.
Therefore, the thermostatic chamber-equipped piezoelectric oscillator 100 according to the embodiment of the present invention compares the time required for the heat in the atmosphere in which the piezoelectric vibrating element 134 exists to move to the lead portion 136 with the conventional thermostatic chamber-equipped piezoelectric oscillator 200. The temperature in the atmosphere where the piezoelectric vibration element 134 exists can be kept almost constant.
As a result, the thermostatic chamber-equipped piezoelectric oscillator 100 according to the embodiment of the present invention can control the frequency of the piezoelectric vibration element 134 whose frequency fluctuates depending on the temperature in the existing atmosphere with high accuracy and constant. It is possible to prevent the frequency value from fluctuating.

In addition, in the piezoelectric oscillator 100 with a thermostat according to the embodiment of the present invention, the time for the heat in the atmosphere in which the piezoelectric vibration element 134 exists to move to the lead portion 136 can be shortened. Compared with the oscillator 200, the heating time of the heater unit 140 can be shortened.
Therefore, the thermostatic oven-equipped piezoelectric oscillator 100 according to the embodiment of the present invention can suppress the power consumed by the heater unit 140 as compared with the conventional thermostatic oven-equipped piezoelectric oscillator 200.

Moreover, in the piezoelectric oscillator 100 with a thermostat according to the embodiment of the present invention, the lead portion 136 and the printed circuit board portion 120 are electrically connected by the wire portion 180 thinner than the lead portion 136, and the conventional thermostat-equipped piezoelectric device is provided. Since the length of the lead part 136 can be shortened compared to the lead part 236 of the oscillator 200, it exists between the piezoelectric vibrator main body 231 and the printed circuit board part 220 in the conventional thermostatted piezoelectric oscillator 200. Compared to the surface area of the lead portion 236, it is possible.
For this reason, the thermostatic chamber-equipped piezoelectric oscillator 100 according to the present invention has an amount of heat radiated from the lead portion 136 and the wire portion 180 compared to the amount of heat radiated from the lead portion 236 in the conventional thermostatic chamber-equipped piezoelectric oscillator 200. Therefore, it is possible to suppress the electric power consumed by the heater unit as compared with the conventional piezoelectric oscillator 200 with a thermostatic bath.

  In addition, although the case where the wire portion is made of white and white is described, if the material is thinner and higher in thermal conductivity than the lead portion, for example, any one of silver, silver compound, gold, copper, and copper compound May be selected and used.

100, 200: Thermostatic bath-equipped piezoelectric oscillator 110: Bottom plate member 120, 220 ... Printed circuit board part 130, 230 ... Piezoelectric vibrator 131, 231 ... Piezoelectric vibrator body part 132, 232 .... Base parts 133, 233 ... Holding parts 134, 234 ... Piezoelectric vibration elements 136, 236 ... Lead parts 140, 240 ... Heater parts 150, 250 ... Electronic elements 160 ... Connection pins 170 ... Lid member 180 ... Wire part

Claims (1)

A bottom plate member;
On one main surface of the bottom plate member, a printed circuit board portion provided at a predetermined interval from the bottom plate member,
A piezoelectric vibrator provided in the printed circuit board portion;
A heater unit provided on the printed circuit board unit for heating the piezoelectric vibrator;
A plurality of electronic elements that are provided on the printed circuit board unit and are electrically connected to the piezoelectric vibrator to form at least an oscillation circuit and constitute an electronic circuit for controlling the temperature of the heater unit;
Providing electrical connection with the electronic element and projecting to the other main surface side of the bottom plate member through the bottom plate member while holding the printed board portion on one main surface of the bottom plate member A plurality of connected pins,
A lid member attached to the bottom plate member so as to cover the printed circuit board part, the piezoelectric vibrator, the heater part, and the electronic element;
A thermostatic oven-equipped piezoelectric oscillator comprising:
The piezoelectric vibrator is composed of a piezoelectric vibrator main body part and two pairs of lead parts,
The piezoelectric vibrator main body includes a base, two pairs of holding portions protruding from one main surface of the base, a piezoelectric vibration element connected and fixed to the holding portion, and the piezoelectric vibration element. A metal cover part hermetically sealed with the base part,
The lead portion protrudes from the other main surface of the base portion in a state of being electrically connected to the holding portion inside the base portion,
The lead portion and the printed circuit board portion are electrically connected by a wire material portion that is thinner than the lead portion and has high thermal conductivity so that the lead portion and the predetermined electronic element are electrically connected. A piezoelectric oscillator with a thermostatic bath characterized by the above.

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